Leukemia, Myelodysplasia, Transplantation

Researcher in the lab

Photo by Darren Baker

Researchers say they have created a model that can show how nearly any drug behaves in P-glycoprotein (P-gp), a protein associated with chemotherapy failure.

The team developed this computer-generated model to overcome the problem of relying on static images for the structure of P-gp.

When the researchers introduced drugs into the model, the drugs responded the way they do in real life and behaved according to predictions.

John G. Wise, PhD, of Southern Methodist University in Dallas, Texas, and his colleagues described the model in Biochemistry.

“The value of this fundamental research is that it generates dynamic mechanisms that let us understand something in biochemistry, in biology,” Dr Wise said. “And by understanding P-gp in such detail, we can now think of ways to better and more specifically inhibit it.”

Dr Wise and his colleagues noted that P-gp protects cells by pumping out toxins, but that can include chemotherapy drugs. So inhibiting P-gp’s pumping action might circumvent chemotherapy failure.

With than in mind, the team tested tariquidar, a P-gp inhibitor in clinical trials, in their model.

It hasn’t been clear exactly where tariquidar binds in P-gp. But the model showed the drug prefers to bind high in the protein. Tariquidar also behaved as expected. It wasn’t effectively pumped from the cell.

“Now we have more details on how tariquidar inhibits P-gp, where it inhibits, and what it’s actually binding to,” Dr Wise said.

He and his colleagues also used their model to uncover additional details about the behavior of other drugs in P-gp.

“For a long time, it’s been thought that there are at least a couple of distinct binding sites for drugs,” Dr Wise said.

“Sure enough, with our models, we found that [the chemotherapeutic agent] daunorubicin, at least, prefers to bind on one side of the P-gp model, while verapamil—a commonly prescribed blood pressure medicine—prefers the other side.”

Not only did the researchers show computationally that there are 2 different starting points for drugs, they also showed that there are 2 different pathways to get the drugs through.

“The 2 different drugs start at different sites, and they’re funneled to the outside by being pushed by the protein,” Dr Wise said. “But the actual parts of the protein that are pushing the drugs out are different.”

Drug discovery

Being able to watch molecular machinery up close, while it is doing its job the way it does in real life, may spark new drug discoveries to fight cancer, Dr Wise said.

“Having an accurate model that actually moves—that shows the dynamics of the thing—is incredibly helpful in developing therapies against a molecular target to inhibit it,” Dr Wise said. “The only other ways to do it are blind, and the chances of success using blind methods are very low.”

“Scientists have tried for 30 years to find inhibitors of this pump and have done it without knowing the structure and with only little knowledge about the mechanism, screening more or less blindly for compounds that inhibit the thing.”

“They found drugs that worked in the test tube and that worked in cultured cells but that didn’t work in the patient. With our model, because we can see the pump moving, we can probably predict better what’s going to make an inhibitor actually work well.”

Dr Wise and his colleagues used the P-gp model to virtually screen millions of publicly available compounds. They discovered 3 new drug leads that could ultimately inhibit P-gp and offer better odds of survival to prostate cancer patients.

The researchers reported these findings in Pharmacology Research & Perspectives.

Creating the model

To build the P-gp model, Dr Wise and his colleagues used static structures from the US Protein Data Bank repository. They used structures showing various stages of transport to simulate 4 points of reference.

From there, the team fed a supercomputer parameters and characteristics of the protein, as well as how it should behave physically, including when kinetic energy was added to bring the protein and its surrounding membrane and water up to body temperature.

The animated model resulted from calculating differences between 2 structures and using targeted molecular dynamics programs to slightly nudge the model to the next step.

“You do that several million times and make several trillion calculations, and you arrive at the next structure,” Dr Wise said. “In this way, we can nudge P-gp through a full catalytic transport cycle.”

Finally, using a docking program, the researchers individually introduced daunorubicin and other drugs into the protein and watched the drugs move through P-gp’s catalytic cycle.

“What happened was: the drugs moved,” Dr Wise said. “And they moved the way they should move, clinically, biochemically, physiologically, to pump the compounds out of the cell.”

Challenging the model

The researchers ran a critical control to further test if the model worked.

“We thought maybe anything you put in the protein, relevant or not, would get pumped through,” Dr Wise said. “So we put in something that is not a transport substrate of P-gp, something that, biochemically, would never be transported by P-gp.”

“We put it in, starting where daunorubicin is effectively pumped out, and, very quickly, the compound left the protein. But it left the opposite way, back into the cell. This experiment gave us more confidence that what we are seeing in these models is reflecting what happens in the cell.”

Dr Wise admitted that, until he saw it for himself, he had doubts the virtual P-gp model would behave like real-life P-gp.

“It’s a crude approximation of a complex, sophisticated human protein, but it’s so much better than the static images available now,” Dr Wise said.

“I’ve got to emphasize for all the disbelievers, for the ‘culture of doubters’ out there, that this model works. It moves the drugs through the membrane. That speaks for itself. What P-gp does in the cell, cancerous or normal, it does in our simulations.”

Researcher in the lab

Photo by Darren Baker

Researchers say they have created a model that can show how nearly any drug behaves in P-glycoprotein (P-gp), a protein associated with chemotherapy failure.

The team developed this computer-generated model to overcome the problem of relying on static images for the structure of P-gp.

When the researchers introduced drugs into the model, the drugs responded the way they do in real life and behaved according to predictions.

John G. Wise, PhD, of Southern Methodist University in Dallas, Texas, and his colleagues described the model in Biochemistry.

“The value of this fundamental research is that it generates dynamic mechanisms that let us understand something in biochemistry, in biology,” Dr Wise said. “And by understanding P-gp in such detail, we can now think of ways to better and more specifically inhibit it.”

Dr Wise and his colleagues noted that P-gp protects cells by pumping out toxins, but that can include chemotherapy drugs. So inhibiting P-gp’s pumping action might circumvent chemotherapy failure.

With than in mind, the team tested tariquidar, a P-gp inhibitor in clinical trials, in their model.

It hasn’t been clear exactly where tariquidar binds in P-gp. But the model showed the drug prefers to bind high in the protein. Tariquidar also behaved as expected. It wasn’t effectively pumped from the cell.

“Now we have more details on how tariquidar inhibits P-gp, where it inhibits, and what it’s actually binding to,” Dr Wise said.

He and his colleagues also used their model to uncover additional details about the behavior of other drugs in P-gp.

“For a long time, it’s been thought that there are at least a couple of distinct binding sites for drugs,” Dr Wise said.

“Sure enough, with our models, we found that [the chemotherapeutic agent] daunorubicin, at least, prefers to bind on one side of the P-gp model, while verapamil—a commonly prescribed blood pressure medicine—prefers the other side.”

Not only did the researchers show computationally that there are 2 different starting points for drugs, they also showed that there are 2 different pathways to get the drugs through.

“The 2 different drugs start at different sites, and they’re funneled to the outside by being pushed by the protein,” Dr Wise said. “But the actual parts of the protein that are pushing the drugs out are different.”

Drug discovery

Being able to watch molecular machinery up close, while it is doing its job the way it does in real life, may spark new drug discoveries to fight cancer, Dr Wise said.

“Having an accurate model that actually moves—that shows the dynamics of the thing—is incredibly helpful in developing therapies against a molecular target to inhibit it,” Dr Wise said. “The only other ways to do it are blind, and the chances of success using blind methods are very low.”

“Scientists have tried for 30 years to find inhibitors of this pump and have done it without knowing the structure and with only little knowledge about the mechanism, screening more or less blindly for compounds that inhibit the thing.”

“They found drugs that worked in the test tube and that worked in cultured cells but that didn’t work in the patient. With our model, because we can see the pump moving, we can probably predict better what’s going to make an inhibitor actually work well.”

Dr Wise and his colleagues used the P-gp model to virtually screen millions of publicly available compounds. They discovered 3 new drug leads that could ultimately inhibit P-gp and offer better odds of survival to prostate cancer patients.

The researchers reported these findings in Pharmacology Research & Perspectives.

Creating the model

To build the P-gp model, Dr Wise and his colleagues used static structures from the US Protein Data Bank repository. They used structures showing various stages of transport to simulate 4 points of reference.

From there, the team fed a supercomputer parameters and characteristics of the protein, as well as how it should behave physically, including when kinetic energy was added to bring the protein and its surrounding membrane and water up to body temperature.

The animated model resulted from calculating differences between 2 structures and using targeted molecular dynamics programs to slightly nudge the model to the next step.

“You do that several million times and make several trillion calculations, and you arrive at the next structure,” Dr Wise said. “In this way, we can nudge P-gp through a full catalytic transport cycle.”

Finally, using a docking program, the researchers individually introduced daunorubicin and other drugs into the protein and watched the drugs move through P-gp’s catalytic cycle.

“What happened was: the drugs moved,” Dr Wise said. “And they moved the way they should move, clinically, biochemically, physiologically, to pump the compounds out of the cell.”

Challenging the model

The researchers ran a critical control to further test if the model worked.

“We thought maybe anything you put in the protein, relevant or not, would get pumped through,” Dr Wise said. “So we put in something that is not a transport substrate of P-gp, something that, biochemically, would never be transported by P-gp.”

“We put it in, starting where daunorubicin is effectively pumped out, and, very quickly, the compound left the protein. But it left the opposite way, back into the cell. This experiment gave us more confidence that what we are seeing in these models is reflecting what happens in the cell.”

Dr Wise admitted that, until he saw it for himself, he had doubts the virtual P-gp model would behave like real-life P-gp.

“It’s a crude approximation of a complex, sophisticated human protein, but it’s so much better than the static images available now,” Dr Wise said.

“I’ve got to emphasize for all the disbelievers, for the ‘culture of doubters’ out there, that this model works. It moves the drugs through the membrane. That speaks for itself. What P-gp does in the cell, cancerous or normal, it does in our simulations.”

Researcher in the lab

Photo by Darren Baker

Researchers say they have created a model that can show how nearly any drug behaves in P-glycoprotein (P-gp), a protein associated with chemotherapy failure.

The team developed this computer-generated model to overcome the problem of relying on static images for the structure of P-gp.

When the researchers introduced drugs into the model, the drugs responded the way they do in real life and behaved according to predictions.

John G. Wise, PhD, of Southern Methodist University in Dallas, Texas, and his colleagues described the model in Biochemistry.

“The value of this fundamental research is that it generates dynamic mechanisms that let us understand something in biochemistry, in biology,” Dr Wise said. “And by understanding P-gp in such detail, we can now think of ways to better and more specifically inhibit it.”

Dr Wise and his colleagues noted that P-gp protects cells by pumping out toxins, but that can include chemotherapy drugs. So inhibiting P-gp’s pumping action might circumvent chemotherapy failure.

With than in mind, the team tested tariquidar, a P-gp inhibitor in clinical trials, in their model.

It hasn’t been clear exactly where tariquidar binds in P-gp. But the model showed the drug prefers to bind high in the protein. Tariquidar also behaved as expected. It wasn’t effectively pumped from the cell.

“Now we have more details on how tariquidar inhibits P-gp, where it inhibits, and what it’s actually binding to,” Dr Wise said.

He and his colleagues also used their model to uncover additional details about the behavior of other drugs in P-gp.

“For a long time, it’s been thought that there are at least a couple of distinct binding sites for drugs,” Dr Wise said.

“Sure enough, with our models, we found that [the chemotherapeutic agent] daunorubicin, at least, prefers to bind on one side of the P-gp model, while verapamil—a commonly prescribed blood pressure medicine—prefers the other side.”

Not only did the researchers show computationally that there are 2 different starting points for drugs, they also showed that there are 2 different pathways to get the drugs through.

“The 2 different drugs start at different sites, and they’re funneled to the outside by being pushed by the protein,” Dr Wise said. “But the actual parts of the protein that are pushing the drugs out are different.”

Drug discovery

Being able to watch molecular machinery up close, while it is doing its job the way it does in real life, may spark new drug discoveries to fight cancer, Dr Wise said.

“Having an accurate model that actually moves—that shows the dynamics of the thing—is incredibly helpful in developing therapies against a molecular target to inhibit it,” Dr Wise said. “The only other ways to do it are blind, and the chances of success using blind methods are very low.”

“Scientists have tried for 30 years to find inhibitors of this pump and have done it without knowing the structure and with only little knowledge about the mechanism, screening more or less blindly for compounds that inhibit the thing.”

“They found drugs that worked in the test tube and that worked in cultured cells but that didn’t work in the patient. With our model, because we can see the pump moving, we can probably predict better what’s going to make an inhibitor actually work well.”

Dr Wise and his colleagues used the P-gp model to virtually screen millions of publicly available compounds. They discovered 3 new drug leads that could ultimately inhibit P-gp and offer better odds of survival to prostate cancer patients.

The researchers reported these findings in Pharmacology Research & Perspectives.

Creating the model

To build the P-gp model, Dr Wise and his colleagues used static structures from the US Protein Data Bank repository. They used structures showing various stages of transport to simulate 4 points of reference.

From there, the team fed a supercomputer parameters and characteristics of the protein, as well as how it should behave physically, including when kinetic energy was added to bring the protein and its surrounding membrane and water up to body temperature.

The animated model resulted from calculating differences between 2 structures and using targeted molecular dynamics programs to slightly nudge the model to the next step.

“You do that several million times and make several trillion calculations, and you arrive at the next structure,” Dr Wise said. “In this way, we can nudge P-gp through a full catalytic transport cycle.”

Finally, using a docking program, the researchers individually introduced daunorubicin and other drugs into the protein and watched the drugs move through P-gp’s catalytic cycle.

“What happened was: the drugs moved,” Dr Wise said. “And they moved the way they should move, clinically, biochemically, physiologically, to pump the compounds out of the cell.”

Challenging the model

The researchers ran a critical control to further test if the model worked.

“We thought maybe anything you put in the protein, relevant or not, would get pumped through,” Dr Wise said. “So we put in something that is not a transport substrate of P-gp, something that, biochemically, would never be transported by P-gp.”

“We put it in, starting where daunorubicin is effectively pumped out, and, very quickly, the compound left the protein. But it left the opposite way, back into the cell. This experiment gave us more confidence that what we are seeing in these models is reflecting what happens in the cell.”

Dr Wise admitted that, until he saw it for himself, he had doubts the virtual P-gp model would behave like real-life P-gp.

“It’s a crude approximation of a complex, sophisticated human protein, but it’s so much better than the static images available now,” Dr Wise said.

“I’ve got to emphasize for all the disbelievers, for the ‘culture of doubters’ out there, that this model works. It moves the drugs through the membrane. That speaks for itself. What P-gp does in the cell, cancerous or normal, it does in our simulations.”

Prescription drugs

Photo courtesy of CDC

England’s National Health Service (NHS) plans to remove several drugs used to treat hematologic malignancies from the Cancer Drugs Fund (CDF).

The plan is that, as of November 4, 2015, pomalidomide, lenalidomide, ibrutinib, dasatinib, brentuximab, bosutinib, and bendamustine will no longer be funded via the CDF for certain indications.

Ofatumumab was removed from the CDF list yesterday but is now available through the NHS.

Drugs used to treat solid tumor malignancies are set to be de-funded through CDF in November as well.

However, the NHS said the proposal to remove a drug from the CDF is not necessarily a final decision.

In cases where a drug offers enough clinical benefit, the pharmaceutical company developing that drug has the opportunity to reduce the price they are asking the NHS to pay to ensure that it achieves a satisfactory level of value for money. The NHS said a number of such negotiations are underway.

In addition, patients who are currently receiving the drugs set to be removed from the CDF will continue to have access to those drugs.

About the CDF and the NHS

The CDF—set up in 2010 and currently due to run until March 2016—is money the government has set aside to pay for cancer drugs that haven’t been approved by the National Institute for Health and Care Excellence (NICE) and aren’t available within the NHS in England. Most cancer drugs are routinely funded outside of the CDF.

NHS England and NICE are planning to consult on a proposed new system for commissioning cancer drugs. The NHS said the new system will be designed to provide the agency with a more systematic approach to getting the best price for cancer drugs.

Reason for drug removals

The NHS previously increased the budget for the CDF from £200 million in 2013/14, to £280 million in 2014/15, and £340 million from April 2015. This represents a total increase of 70% since August 2014.

However, current projections suggest that spending would rise to around £410 million for this year, an over-spend of £70 million, in the absence of further prioritization. The NHS said this money could be used for other aspects of cancer treatment or NHS services for other patient groups.

Therefore, some drugs are set to be removed from the CDF. The NHS said all decisions on drugs to be maintained in the CDF were based on the advice of clinicians, the best available evidence, and the cost of the treatment.

“There is no escaping the fact that we face a difficult set of choices, but it is our duty to ensure we get maximum value from every penny available on behalf of patients,” said Peter Clark, chair of the CDF.

“We must ensure we invest in those treatments that offer the most benefit, based on rigorous evidence-based clinical analysis and an assessment of the cost of those treatments.”

While de-funding certain drugs will reduce costs, the CDF is not expected to be back on budget this financial year. The NHS does expect the CDF will be operating within its budget during 2016/17.

Blood cancer drugs to be removed

The following drugs are currently on the CDF list for the following indications, but they are set to be de-listed on November 4, 2015.

Bendamustine

For the treatment of chronic lymphocytic leukemia (CLL) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• CLL (not licensed in this indication)
• Second-line indication, third-line indication, or fourth-line indication
• To be used within the treating Trust’s governance framework, as bendamustine is not licensed in this indication

For the treatment of relapsed mantle cell lymphoma (MCL) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• MCL
• Option for second- or subsequent-line chemotherapy
• No previous treatment with bendamustine
• To be used within the treating Trust’s governance framework, as bendamustine is not licensed in this indication

*Bendamustine will remain on the CDF for other indications.

Bosutinib

For the treatment of refractory, chronic phase chronic myeloid leukemia (CML) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Chronic phase CML
• Refractory to nilotinib or dasatinib (if dasatinib accessed via a clinical trial or via its current approved CDF indication)

For the treatment of refractory, accelerated phase CML where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Accelerated phase CML
• Refractory to nilotinib or dasatinib (if dasatinib accessed via a clinical trial or via its current approved CDF indication)
• Significant intolerance to nilotinib (grade 3 or 4 events)

For the treatment of accelerated phase CML where there is intolerance of treatments and where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Accelerated phase CML
• Significant intolerance to dasatinib (grade 3 or 4 adverse events; if dasatinib accessed via its current approved CDF indication)
• Significant intolerance to nilotinib (grade 3 or 4 events)

*Bosutinib will still be available through the CDF for patients with chronic phase CML that is intolerant of other treatments.

Brentuximab

For the treatment of refractory, systemic anaplastic lymphoma where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Relapsed or refractory systemic anaplastic large-cell lymphoma

For the treatment of relapsed or refractory CD30+ Hodgkin lymphoma where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Relapsed or refractory CD30+ Hodgkin lymphoma
• Following autologous stem cell transplant or following at least 2 prior therapies when autologous stem cell transplant or multi-agent chemotherapy is not an option

Dasatinib

For the treatment of Philadelphia-chromosome-positive (Ph+) acute lymphoblastic leukemia where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Refractory or significant intolerance or resistance to prior therapy including imatinib (grade 3 or 4 adverse events)
• Second-line indication or third-line indication

*Dasatinib will still be available for chronic phase and accelerated phase CML.

Ibrutinib

For the treatment of relapsed/refractory CLL where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Confirmed CLL
• Must have received at least 1 prior therapy for CLL
• Considered not appropriate for treatment or retreatment with purine-analogue-based therapy due to:

  • Failure to respond to chemo-immunotherapy or
  • A progression-free interval of less than 3 years or
  • Age of 70 years or more or
  • Age of 65 years or more plus the presence of comorbidities or
  • A 17p or TP53 deletion

• ECOG performance status of 0-2
• A neutrophil count of ≥0.75 x 10⁹/L
• A platelet count of ≥30 x 10⁹/L
• Patient not on warfarin or CYP3A4/5 inhibitors
• No prior treatment with idelalisib

For the treatment of relapsed/refractory MCL where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Confirmed MCL with cyclin D1 overexpression or translocation breakpoints at t(11;14)
• Failure to achieve at least partial response with, or documented disease progression disease after, the most recent treatment regimen
• ECOG performance status of 0-2
• At least 1 but no more than 5 previous lines of treatment

Lenalidomide

For the second-line treatment of multiple myeloma (MM) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• MM
• Second-line indication
• Contraindication to bortezomib or previously received bortezomib in the first-line setting

*Lenalidomide will still be available for patients with myelodysplastic syndromes with 5q deletion.

Pomalidomide

For the treatment of relapsed and refractory MM where the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically
• MM
• Performance status of 0-2
• Previously received treatment with adequate trials of at least all of the following options of therapy: bortezomib, lenalidomide, and alkylating agents
• Failed treatment with bortezomib or lenalidomide, as defined by: progression on or before 60 days of treatment, progressive disease 6 months or less after achieving a partial response, or intolerance to bortezomib
• Refractory disease to previous treatment
• No resistance to high-dose dexamethasone used in the last line of therapy
• No peripheral neuropathy of grade 2 or more

A complete list of proposed changes to the CDF, as well as the drugs that were de-listed on March 12, 2015, is available on the NHS website.

Prescription drugs

Photo courtesy of CDC

England’s National Health Service (NHS) plans to remove several drugs used to treat hematologic malignancies from the Cancer Drugs Fund (CDF).

The plan is that, as of November 4, 2015, pomalidomide, lenalidomide, ibrutinib, dasatinib, brentuximab, bosutinib, and bendamustine will no longer be funded via the CDF for certain indications.

Ofatumumab was removed from the CDF list yesterday but is now available through the NHS.

Drugs used to treat solid tumor malignancies are set to be de-funded through CDF in November as well.

However, the NHS said the proposal to remove a drug from the CDF is not necessarily a final decision.

In cases where a drug offers enough clinical benefit, the pharmaceutical company developing that drug has the opportunity to reduce the price they are asking the NHS to pay to ensure that it achieves a satisfactory level of value for money. The NHS said a number of such negotiations are underway.

In addition, patients who are currently receiving the drugs set to be removed from the CDF will continue to have access to those drugs.

About the CDF and the NHS

The CDF—set up in 2010 and currently due to run until March 2016—is money the government has set aside to pay for cancer drugs that haven’t been approved by the National Institute for Health and Care Excellence (NICE) and aren’t available within the NHS in England. Most cancer drugs are routinely funded outside of the CDF.

NHS England and NICE are planning to consult on a proposed new system for commissioning cancer drugs. The NHS said the new system will be designed to provide the agency with a more systematic approach to getting the best price for cancer drugs.

Reason for drug removals

The NHS previously increased the budget for the CDF from £200 million in 2013/14, to £280 million in 2014/15, and £340 million from April 2015. This represents a total increase of 70% since August 2014.

However, current projections suggest that spending would rise to around £410 million for this year, an over-spend of £70 million, in the absence of further prioritization. The NHS said this money could be used for other aspects of cancer treatment or NHS services for other patient groups.

Therefore, some drugs are set to be removed from the CDF. The NHS said all decisions on drugs to be maintained in the CDF were based on the advice of clinicians, the best available evidence, and the cost of the treatment.

“There is no escaping the fact that we face a difficult set of choices, but it is our duty to ensure we get maximum value from every penny available on behalf of patients,” said Peter Clark, chair of the CDF.

“We must ensure we invest in those treatments that offer the most benefit, based on rigorous evidence-based clinical analysis and an assessment of the cost of those treatments.”

While de-funding certain drugs will reduce costs, the CDF is not expected to be back on budget this financial year. The NHS does expect the CDF will be operating within its budget during 2016/17.

Blood cancer drugs to be removed

The following drugs are currently on the CDF list for the following indications, but they are set to be de-listed on November 4, 2015.

Bendamustine

For the treatment of chronic lymphocytic leukemia (CLL) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• CLL (not licensed in this indication)
• Second-line indication, third-line indication, or fourth-line indication
• To be used within the treating Trust’s governance framework, as bendamustine is not licensed in this indication

For the treatment of relapsed mantle cell lymphoma (MCL) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• MCL
• Option for second- or subsequent-line chemotherapy
• No previous treatment with bendamustine
• To be used within the treating Trust’s governance framework, as bendamustine is not licensed in this indication

*Bendamustine will remain on the CDF for other indications.

Bosutinib

For the treatment of refractory, chronic phase chronic myeloid leukemia (CML) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Chronic phase CML
• Refractory to nilotinib or dasatinib (if dasatinib accessed via a clinical trial or via its current approved CDF indication)

For the treatment of refractory, accelerated phase CML where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Accelerated phase CML
• Refractory to nilotinib or dasatinib (if dasatinib accessed via a clinical trial or via its current approved CDF indication)
• Significant intolerance to nilotinib (grade 3 or 4 events)

For the treatment of accelerated phase CML where there is intolerance of treatments and where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Accelerated phase CML
• Significant intolerance to dasatinib (grade 3 or 4 adverse events; if dasatinib accessed via its current approved CDF indication)
• Significant intolerance to nilotinib (grade 3 or 4 events)

*Bosutinib will still be available through the CDF for patients with chronic phase CML that is intolerant of other treatments.

Brentuximab

For the treatment of refractory, systemic anaplastic lymphoma where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Relapsed or refractory systemic anaplastic large-cell lymphoma

For the treatment of relapsed or refractory CD30+ Hodgkin lymphoma where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Relapsed or refractory CD30+ Hodgkin lymphoma
• Following autologous stem cell transplant or following at least 2 prior therapies when autologous stem cell transplant or multi-agent chemotherapy is not an option

Dasatinib

For the treatment of Philadelphia-chromosome-positive (Ph+) acute lymphoblastic leukemia where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Refractory or significant intolerance or resistance to prior therapy including imatinib (grade 3 or 4 adverse events)
• Second-line indication or third-line indication

*Dasatinib will still be available for chronic phase and accelerated phase CML.

Ibrutinib

For the treatment of relapsed/refractory CLL where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Confirmed CLL
• Must have received at least 1 prior therapy for CLL
• Considered not appropriate for treatment or retreatment with purine-analogue-based therapy due to:

  • Failure to respond to chemo-immunotherapy or
  • A progression-free interval of less than 3 years or
  • Age of 70 years or more or
  • Age of 65 years or more plus the presence of comorbidities or
  • A 17p or TP53 deletion

• ECOG performance status of 0-2
• A neutrophil count of ≥0.75 x 10⁹/L
• A platelet count of ≥30 x 10⁹/L
• Patient not on warfarin or CYP3A4/5 inhibitors
• No prior treatment with idelalisib

For the treatment of relapsed/refractory MCL where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Confirmed MCL with cyclin D1 overexpression or translocation breakpoints at t(11;14)
• Failure to achieve at least partial response with, or documented disease progression disease after, the most recent treatment regimen
• ECOG performance status of 0-2
• At least 1 but no more than 5 previous lines of treatment

Lenalidomide

For the second-line treatment of multiple myeloma (MM) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• MM
• Second-line indication
• Contraindication to bortezomib or previously received bortezomib in the first-line setting

*Lenalidomide will still be available for patients with myelodysplastic syndromes with 5q deletion.

Pomalidomide

For the treatment of relapsed and refractory MM where the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically
• MM
• Performance status of 0-2
• Previously received treatment with adequate trials of at least all of the following options of therapy: bortezomib, lenalidomide, and alkylating agents
• Failed treatment with bortezomib or lenalidomide, as defined by: progression on or before 60 days of treatment, progressive disease 6 months or less after achieving a partial response, or intolerance to bortezomib
• Refractory disease to previous treatment
• No resistance to high-dose dexamethasone used in the last line of therapy
• No peripheral neuropathy of grade 2 or more

A complete list of proposed changes to the CDF, as well as the drugs that were de-listed on March 12, 2015, is available on the NHS website.

Prescription drugs

Photo courtesy of CDC

England’s National Health Service (NHS) plans to remove several drugs used to treat hematologic malignancies from the Cancer Drugs Fund (CDF).

The plan is that, as of November 4, 2015, pomalidomide, lenalidomide, ibrutinib, dasatinib, brentuximab, bosutinib, and bendamustine will no longer be funded via the CDF for certain indications.

Ofatumumab was removed from the CDF list yesterday but is now available through the NHS.

Drugs used to treat solid tumor malignancies are set to be de-funded through CDF in November as well.

However, the NHS said the proposal to remove a drug from the CDF is not necessarily a final decision.

In cases where a drug offers enough clinical benefit, the pharmaceutical company developing that drug has the opportunity to reduce the price they are asking the NHS to pay to ensure that it achieves a satisfactory level of value for money. The NHS said a number of such negotiations are underway.

In addition, patients who are currently receiving the drugs set to be removed from the CDF will continue to have access to those drugs.

About the CDF and the NHS

The CDF—set up in 2010 and currently due to run until March 2016—is money the government has set aside to pay for cancer drugs that haven’t been approved by the National Institute for Health and Care Excellence (NICE) and aren’t available within the NHS in England. Most cancer drugs are routinely funded outside of the CDF.

NHS England and NICE are planning to consult on a proposed new system for commissioning cancer drugs. The NHS said the new system will be designed to provide the agency with a more systematic approach to getting the best price for cancer drugs.

Reason for drug removals

The NHS previously increased the budget for the CDF from £200 million in 2013/14, to £280 million in 2014/15, and £340 million from April 2015. This represents a total increase of 70% since August 2014.

However, current projections suggest that spending would rise to around £410 million for this year, an over-spend of £70 million, in the absence of further prioritization. The NHS said this money could be used for other aspects of cancer treatment or NHS services for other patient groups.

Therefore, some drugs are set to be removed from the CDF. The NHS said all decisions on drugs to be maintained in the CDF were based on the advice of clinicians, the best available evidence, and the cost of the treatment.

“There is no escaping the fact that we face a difficult set of choices, but it is our duty to ensure we get maximum value from every penny available on behalf of patients,” said Peter Clark, chair of the CDF.

“We must ensure we invest in those treatments that offer the most benefit, based on rigorous evidence-based clinical analysis and an assessment of the cost of those treatments.”

While de-funding certain drugs will reduce costs, the CDF is not expected to be back on budget this financial year. The NHS does expect the CDF will be operating within its budget during 2016/17.

Blood cancer drugs to be removed

The following drugs are currently on the CDF list for the following indications, but they are set to be de-listed on November 4, 2015.

Bendamustine

For the treatment of chronic lymphocytic leukemia (CLL) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• CLL (not licensed in this indication)
• Second-line indication, third-line indication, or fourth-line indication
• To be used within the treating Trust’s governance framework, as bendamustine is not licensed in this indication

For the treatment of relapsed mantle cell lymphoma (MCL) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• MCL
• Option for second- or subsequent-line chemotherapy
• No previous treatment with bendamustine
• To be used within the treating Trust’s governance framework, as bendamustine is not licensed in this indication

*Bendamustine will remain on the CDF for other indications.

Bosutinib

For the treatment of refractory, chronic phase chronic myeloid leukemia (CML) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Chronic phase CML
• Refractory to nilotinib or dasatinib (if dasatinib accessed via a clinical trial or via its current approved CDF indication)

For the treatment of refractory, accelerated phase CML where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Accelerated phase CML
• Refractory to nilotinib or dasatinib (if dasatinib accessed via a clinical trial or via its current approved CDF indication)
• Significant intolerance to nilotinib (grade 3 or 4 events)

For the treatment of accelerated phase CML where there is intolerance of treatments and where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Accelerated phase CML
• Significant intolerance to dasatinib (grade 3 or 4 adverse events; if dasatinib accessed via its current approved CDF indication)
• Significant intolerance to nilotinib (grade 3 or 4 events)

*Bosutinib will still be available through the CDF for patients with chronic phase CML that is intolerant of other treatments.

Brentuximab

For the treatment of refractory, systemic anaplastic lymphoma where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Relapsed or refractory systemic anaplastic large-cell lymphoma

For the treatment of relapsed or refractory CD30+ Hodgkin lymphoma where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Relapsed or refractory CD30+ Hodgkin lymphoma
• Following autologous stem cell transplant or following at least 2 prior therapies when autologous stem cell transplant or multi-agent chemotherapy is not an option

Dasatinib

For the treatment of Philadelphia-chromosome-positive (Ph+) acute lymphoblastic leukemia where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Refractory or significant intolerance or resistance to prior therapy including imatinib (grade 3 or 4 adverse events)
• Second-line indication or third-line indication

*Dasatinib will still be available for chronic phase and accelerated phase CML.

Ibrutinib

For the treatment of relapsed/refractory CLL where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Confirmed CLL
• Must have received at least 1 prior therapy for CLL
• Considered not appropriate for treatment or retreatment with purine-analogue-based therapy due to:

  • Failure to respond to chemo-immunotherapy or
  • A progression-free interval of less than 3 years or
  • Age of 70 years or more or
  • Age of 65 years or more plus the presence of comorbidities or
  • A 17p or TP53 deletion

• ECOG performance status of 0-2
• A neutrophil count of ≥0.75 x 10⁹/L
• A platelet count of ≥30 x 10⁹/L
• Patient not on warfarin or CYP3A4/5 inhibitors
• No prior treatment with idelalisib

For the treatment of relapsed/refractory MCL where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• Confirmed MCL with cyclin D1 overexpression or translocation breakpoints at t(11;14)
• Failure to achieve at least partial response with, or documented disease progression disease after, the most recent treatment regimen
• ECOG performance status of 0-2
• At least 1 but no more than 5 previous lines of treatment

Lenalidomide

For the second-line treatment of multiple myeloma (MM) where all the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically trained and accredited in the use of systemic anticancer therapy
• MM
• Second-line indication
• Contraindication to bortezomib or previously received bortezomib in the first-line setting

*Lenalidomide will still be available for patients with myelodysplastic syndromes with 5q deletion.

Pomalidomide

For the treatment of relapsed and refractory MM where the following criteria are met:

• Application made by and first cycle of systemic anticancer therapy to be prescribed by a consultant specialist specifically
• MM
• Performance status of 0-2
• Previously received treatment with adequate trials of at least all of the following options of therapy: bortezomib, lenalidomide, and alkylating agents
• Failed treatment with bortezomib or lenalidomide, as defined by: progression on or before 60 days of treatment, progressive disease 6 months or less after achieving a partial response, or intolerance to bortezomib
• Refractory disease to previous treatment
• No resistance to high-dose dexamethasone used in the last line of therapy
• No peripheral neuropathy of grade 2 or more

A complete list of proposed changes to the CDF, as well as the drugs that were de-listed on March 12, 2015, is available on the NHS website.

Patient receiving chemotherapy

Photo by Rhoda Baer

Last March, the US Food and Drug Administration (FDA) issued a statement warning healthcare professionals not to use the chemotherapy drug Treanda Injection (bendamustine hydrochloride) with closed system transfer devices (CSTDs), adapters, and syringes containing polycarbonate or acrylonitrile-butadiene-styrene (ABS).

Now, the FDA is providing a list of devices that were tested and deemed compatible with the drug (see the tables below).

The devices were tested by Treanda’s manufacturer, Teva Pharmaceuticals.

Treanda is used to treat patients with chronic lymphocytic leukemia and indolent B-cell non-Hodgkin lymphoma that has progressed during or within 6 months of treatment with rituximab or a rituximab-containing regimen.

Treanda is available in 2 formulations: a solution, Treanda Injection (45 mg/0.5 mL or 180 mg/2 mL solution), and a lyophilized powder, Treanda for Injection (25 mg/vial or 100 mg/vial lyophilized powder).  The information discussed here is referring to compatibility with the solution, Treanda Injection.

Treanda Injection contains N, N-dimethylacetamide (DMA), which is incompatible with devices that contain polycarbonate or ABS. Devices including CSTDs, adapters, and syringes that contain polycarbonate or ABS have been shown to dissolve when they come in contact with DMA in the drug.

This incompatibility leads to device failure, such as leaking, breaking, or operational failure of CSTD components; possible product contamination; and potential serious adverse health consequences to practitioners, such as skin reactions, or to patients, including the risk of small blood vessel blockage if the product is contaminated with dissolved ABS or polycarbonate.

Users should contact device manufacturers prior to using the specific devices listed below to ensure there have been no changes made to the material composition of the devices and that the devices are compatible with Treanda use.

Table 1. The compatibility of Treanda Injection with specific CSTDs, syringes, vial adapters, and gloves (based on testing conducted by Teva from February 2015 through June 2015).

*Part numbers reflect a specific size glove used in the compatibility tests.

Table 2. The IV administration set found to be compatible with Treanda Injection after dilution in a 500 mL 0.9% sodium chloride IV infusion bags (based on testing conducted by Teva from February 2015 through June 2015*).

*Compatibility studies did not include testing with 2.5% dextrose/0.45% sodium chloride injection. However, the results of these studies are not expected to change. So either diluent, 0.9% sodium chloride or 2.5% dextrose/0.45% sodium chloride injection, can be used with Treanda injection.

The FDA required label changes for both the solution and the powder formulations of Treanda to include information for safe preparation and handling for IV administration. See the full prescribing information for details.

For more details on the compatibility of Treanda Injection with specific CSTDs, syringes, vial adapters, gloves, and IV administration sets, see Teva’s Dear Health Care Provider letter.

Adverse events or quality problems associated with the use of Treanda products can be reported to the FDA’s MedWatch Adverse Event Reporting Program.

Patient receiving chemotherapy

Photo by Rhoda Baer

Last March, the US Food and Drug Administration (FDA) issued a statement warning healthcare professionals not to use the chemotherapy drug Treanda Injection (bendamustine hydrochloride) with closed system transfer devices (CSTDs), adapters, and syringes containing polycarbonate or acrylonitrile-butadiene-styrene (ABS).

Now, the FDA is providing a list of devices that were tested and deemed compatible with the drug (see the tables below).

The devices were tested by Treanda’s manufacturer, Teva Pharmaceuticals.

Treanda is used to treat patients with chronic lymphocytic leukemia and indolent B-cell non-Hodgkin lymphoma that has progressed during or within 6 months of treatment with rituximab or a rituximab-containing regimen.

Treanda is available in 2 formulations: a solution, Treanda Injection (45 mg/0.5 mL or 180 mg/2 mL solution), and a lyophilized powder, Treanda for Injection (25 mg/vial or 100 mg/vial lyophilized powder).  The information discussed here is referring to compatibility with the solution, Treanda Injection.

Treanda Injection contains N, N-dimethylacetamide (DMA), which is incompatible with devices that contain polycarbonate or ABS. Devices including CSTDs, adapters, and syringes that contain polycarbonate or ABS have been shown to dissolve when they come in contact with DMA in the drug.

This incompatibility leads to device failure, such as leaking, breaking, or operational failure of CSTD components; possible product contamination; and potential serious adverse health consequences to practitioners, such as skin reactions, or to patients, including the risk of small blood vessel blockage if the product is contaminated with dissolved ABS or polycarbonate.

Users should contact device manufacturers prior to using the specific devices listed below to ensure there have been no changes made to the material composition of the devices and that the devices are compatible with Treanda use.

Table 1. The compatibility of Treanda Injection with specific CSTDs, syringes, vial adapters, and gloves (based on testing conducted by Teva from February 2015 through June 2015).

*Part numbers reflect a specific size glove used in the compatibility tests.

Table 2. The IV administration set found to be compatible with Treanda Injection after dilution in a 500 mL 0.9% sodium chloride IV infusion bags (based on testing conducted by Teva from February 2015 through June 2015*).

*Compatibility studies did not include testing with 2.5% dextrose/0.45% sodium chloride injection. However, the results of these studies are not expected to change. So either diluent, 0.9% sodium chloride or 2.5% dextrose/0.45% sodium chloride injection, can be used with Treanda injection.

The FDA required label changes for both the solution and the powder formulations of Treanda to include information for safe preparation and handling for IV administration. See the full prescribing information for details.

For more details on the compatibility of Treanda Injection with specific CSTDs, syringes, vial adapters, gloves, and IV administration sets, see Teva’s Dear Health Care Provider letter.

Adverse events or quality problems associated with the use of Treanda products can be reported to the FDA’s MedWatch Adverse Event Reporting Program.

Patient receiving chemotherapy

Photo by Rhoda Baer

Last March, the US Food and Drug Administration (FDA) issued a statement warning healthcare professionals not to use the chemotherapy drug Treanda Injection (bendamustine hydrochloride) with closed system transfer devices (CSTDs), adapters, and syringes containing polycarbonate or acrylonitrile-butadiene-styrene (ABS).

Now, the FDA is providing a list of devices that were tested and deemed compatible with the drug (see the tables below).

The devices were tested by Treanda’s manufacturer, Teva Pharmaceuticals.

Treanda is used to treat patients with chronic lymphocytic leukemia and indolent B-cell non-Hodgkin lymphoma that has progressed during or within 6 months of treatment with rituximab or a rituximab-containing regimen.

Treanda is available in 2 formulations: a solution, Treanda Injection (45 mg/0.5 mL or 180 mg/2 mL solution), and a lyophilized powder, Treanda for Injection (25 mg/vial or 100 mg/vial lyophilized powder).  The information discussed here is referring to compatibility with the solution, Treanda Injection.

Treanda Injection contains N, N-dimethylacetamide (DMA), which is incompatible with devices that contain polycarbonate or ABS. Devices including CSTDs, adapters, and syringes that contain polycarbonate or ABS have been shown to dissolve when they come in contact with DMA in the drug.

This incompatibility leads to device failure, such as leaking, breaking, or operational failure of CSTD components; possible product contamination; and potential serious adverse health consequences to practitioners, such as skin reactions, or to patients, including the risk of small blood vessel blockage if the product is contaminated with dissolved ABS or polycarbonate.

Users should contact device manufacturers prior to using the specific devices listed below to ensure there have been no changes made to the material composition of the devices and that the devices are compatible with Treanda use.

Table 1. The compatibility of Treanda Injection with specific CSTDs, syringes, vial adapters, and gloves (based on testing conducted by Teva from February 2015 through June 2015).

*Part numbers reflect a specific size glove used in the compatibility tests.

Table 2. The IV administration set found to be compatible with Treanda Injection after dilution in a 500 mL 0.9% sodium chloride IV infusion bags (based on testing conducted by Teva from February 2015 through June 2015*).

*Compatibility studies did not include testing with 2.5% dextrose/0.45% sodium chloride injection. However, the results of these studies are not expected to change. So either diluent, 0.9% sodium chloride or 2.5% dextrose/0.45% sodium chloride injection, can be used with Treanda injection.

The FDA required label changes for both the solution and the powder formulations of Treanda to include information for safe preparation and handling for IV administration. See the full prescribing information for details.

For more details on the compatibility of Treanda Injection with specific CSTDs, syringes, vial adapters, gloves, and IV administration sets, see Teva’s Dear Health Care Provider letter.

Adverse events or quality problems associated with the use of Treanda products can be reported to the FDA’s MedWatch Adverse Event Reporting Program.

Prefilled syringes of Zarxio

© Sandoz Inc. 2015

The leukocyte growth factor Zarxio (filgrastim-sndz), the first biosimilar product to gain approval from the US Food and Drug Administration (FDA), is now available in the US.

Zarxio was approved by the FDA on March 6. The product, made by Sandoz, Inc., is biosimilar to Amgen Inc.’s Neupogen, which was originally licensed in 1991.

Zarxio is marketed as Zarzio outside the US. The biosimilar is available in more than 60 countries worldwide.

In the US, Zarxio is approved for the same indications as Neupogen. So Zarxio can be prescribed for the following 5 indications.

Patients with cancer receiving myelosuppressive chemotherapy: to decrease the incidence of infection, as manifested by febrile neutropenia, in patients with nonmyeloid malignancies receiving myelosuppressive anticancer drugs associated with a significant incidence of severe neutropenia with fever.

Patients with acute myeloid leukemia receiving induction or consolidation chemotherapy: to reduce the time to neutrophil recovery and the duration of fever, following induction or consolidation chemotherapy.

Patients with cancer undergoing bone marrow transplant: to reduce the duration of neutropenia and neutropenia-related clinical sequelae—eg, febrile neutropenia—in patients with nonmyeloid malignancies undergoing myeloablative chemotherapy followed by bone marrow transplant.

Patients undergoing autologous peripheral blood progenitor cell collection and therapy: for the mobilization of autologous hematopoietic progenitor cells into the peripheral blood for collection by leukapheresis.

Patients with severe chronic neutropenia: for chronic administration to reduce the incidence and duration of sequelae of neutropenia—eg, fever, infections, oropharyngeal ulcers—in symptomatic patients with congenital neutropenia, cyclic neutropenia, or idiopathic neutropenia.

PIONEER trial

The FDA’s approval of Zarxio was based on data showing that Zarxio is highly similar to Neupogen, with no clinically meaningful differences between the products.

The head-to-head PIONEER study was the final piece of evidence the FDA used to approve Zarxio as biosimilar to Neupogen. Results of the trial were presented at ASH 2014.

Zarxio and Neupogen both produced the expected reduction in the duration of severe neutropenia in breast cancer patients undergoing myelosuppressive chemotherapy—1.17 ± 1.11 and 1.20 ±1.02 days, respectively.

The mean time to absolute neutrophil count recovery in cycle 1 was also similar—1.8 ± 0.97 days in the Zarxio arm and 1.7 ± 0.81 days in the Neupogen arm. No immunogenicity or antibodies against rhG-CSF were detected throughout the study.

The researchers said there were no obvious differences between Zarxio and Neupogen with regard to treatment-emergent adverse events.

The most common side effects observed with Zarxio are aching bones/muscles and redness, swelling, or itching at the injection site. Serious side effects may include spleen rupture; serious allergic reactions that may cause rash, shortness of breath, wheezing and/or swelling around the mouth and eyes; fast pulse and sweating; and acute respiratory distress syndrome.

For more details on Zarxio, see the full prescribing information or visit www.zarxio.com.

Prefilled syringes of Zarxio

© Sandoz Inc. 2015

The leukocyte growth factor Zarxio (filgrastim-sndz), the first biosimilar product to gain approval from the US Food and Drug Administration (FDA), is now available in the US.

Zarxio was approved by the FDA on March 6. The product, made by Sandoz, Inc., is biosimilar to Amgen Inc.’s Neupogen, which was originally licensed in 1991.

Zarxio is marketed as Zarzio outside the US. The biosimilar is available in more than 60 countries worldwide.

In the US, Zarxio is approved for the same indications as Neupogen. So Zarxio can be prescribed for the following 5 indications.

Patients with cancer receiving myelosuppressive chemotherapy: to decrease the incidence of infection, as manifested by febrile neutropenia, in patients with nonmyeloid malignancies receiving myelosuppressive anticancer drugs associated with a significant incidence of severe neutropenia with fever.

Patients with acute myeloid leukemia receiving induction or consolidation chemotherapy: to reduce the time to neutrophil recovery and the duration of fever, following induction or consolidation chemotherapy.

Patients with cancer undergoing bone marrow transplant: to reduce the duration of neutropenia and neutropenia-related clinical sequelae—eg, febrile neutropenia—in patients with nonmyeloid malignancies undergoing myeloablative chemotherapy followed by bone marrow transplant.

Patients undergoing autologous peripheral blood progenitor cell collection and therapy: for the mobilization of autologous hematopoietic progenitor cells into the peripheral blood for collection by leukapheresis.

Patients with severe chronic neutropenia: for chronic administration to reduce the incidence and duration of sequelae of neutropenia—eg, fever, infections, oropharyngeal ulcers—in symptomatic patients with congenital neutropenia, cyclic neutropenia, or idiopathic neutropenia.

PIONEER trial

The FDA’s approval of Zarxio was based on data showing that Zarxio is highly similar to Neupogen, with no clinically meaningful differences between the products.

The head-to-head PIONEER study was the final piece of evidence the FDA used to approve Zarxio as biosimilar to Neupogen. Results of the trial were presented at ASH 2014.

Zarxio and Neupogen both produced the expected reduction in the duration of severe neutropenia in breast cancer patients undergoing myelosuppressive chemotherapy—1.17 ± 1.11 and 1.20 ±1.02 days, respectively.

The mean time to absolute neutrophil count recovery in cycle 1 was also similar—1.8 ± 0.97 days in the Zarxio arm and 1.7 ± 0.81 days in the Neupogen arm. No immunogenicity or antibodies against rhG-CSF were detected throughout the study.

The researchers said there were no obvious differences between Zarxio and Neupogen with regard to treatment-emergent adverse events.

The most common side effects observed with Zarxio are aching bones/muscles and redness, swelling, or itching at the injection site. Serious side effects may include spleen rupture; serious allergic reactions that may cause rash, shortness of breath, wheezing and/or swelling around the mouth and eyes; fast pulse and sweating; and acute respiratory distress syndrome.

For more details on Zarxio, see the full prescribing information or visit www.zarxio.com.

Prefilled syringes of Zarxio

© Sandoz Inc. 2015

The leukocyte growth factor Zarxio (filgrastim-sndz), the first biosimilar product to gain approval from the US Food and Drug Administration (FDA), is now available in the US.

Zarxio was approved by the FDA on March 6. The product, made by Sandoz, Inc., is biosimilar to Amgen Inc.’s Neupogen, which was originally licensed in 1991.

Zarxio is marketed as Zarzio outside the US. The biosimilar is available in more than 60 countries worldwide.

In the US, Zarxio is approved for the same indications as Neupogen. So Zarxio can be prescribed for the following 5 indications.

Patients with cancer receiving myelosuppressive chemotherapy: to decrease the incidence of infection, as manifested by febrile neutropenia, in patients with nonmyeloid malignancies receiving myelosuppressive anticancer drugs associated with a significant incidence of severe neutropenia with fever.

Patients with acute myeloid leukemia receiving induction or consolidation chemotherapy: to reduce the time to neutrophil recovery and the duration of fever, following induction or consolidation chemotherapy.

Patients with cancer undergoing bone marrow transplant: to reduce the duration of neutropenia and neutropenia-related clinical sequelae—eg, febrile neutropenia—in patients with nonmyeloid malignancies undergoing myeloablative chemotherapy followed by bone marrow transplant.

Patients undergoing autologous peripheral blood progenitor cell collection and therapy: for the mobilization of autologous hematopoietic progenitor cells into the peripheral blood for collection by leukapheresis.

Patients with severe chronic neutropenia: for chronic administration to reduce the incidence and duration of sequelae of neutropenia—eg, fever, infections, oropharyngeal ulcers—in symptomatic patients with congenital neutropenia, cyclic neutropenia, or idiopathic neutropenia.

PIONEER trial

The FDA’s approval of Zarxio was based on data showing that Zarxio is highly similar to Neupogen, with no clinically meaningful differences between the products.

The head-to-head PIONEER study was the final piece of evidence the FDA used to approve Zarxio as biosimilar to Neupogen. Results of the trial were presented at ASH 2014.

Zarxio and Neupogen both produced the expected reduction in the duration of severe neutropenia in breast cancer patients undergoing myelosuppressive chemotherapy—1.17 ± 1.11 and 1.20 ±1.02 days, respectively.

The mean time to absolute neutrophil count recovery in cycle 1 was also similar—1.8 ± 0.97 days in the Zarxio arm and 1.7 ± 0.81 days in the Neupogen arm. No immunogenicity or antibodies against rhG-CSF were detected throughout the study.

The researchers said there were no obvious differences between Zarxio and Neupogen with regard to treatment-emergent adverse events.

The most common side effects observed with Zarxio are aching bones/muscles and redness, swelling, or itching at the injection site. Serious side effects may include spleen rupture; serious allergic reactions that may cause rash, shortness of breath, wheezing and/or swelling around the mouth and eyes; fast pulse and sweating; and acute respiratory distress syndrome.

For more details on Zarxio, see the full prescribing information or visit www.zarxio.com.

ALEXANDRIA, VA. – How are mutation analysis gene panels affecting risk stratification and decision making regarding stem cell transplants in myelofibrosis patients? How are the results of the Dynamic International Prognostic Scoring System (DIPSS) and performance status improvements seen with JAK2 inhibitors influencing who is a candidate for transplant and the timing of transplants?

Watch the conversation between Dr. Vikas Gupta of the leukemia and bone marrow transplant programs at the Princess Margaret Cancer Centre, Toronto, and associate professor of medicine at the University of Toronto, and Dr. Rami S. Komrokji of the Moffitt Cancer Center, Tampa, Fla., as they discuss their individual approaches that consider patient wishes and goals, type of donor, and disease risk in their decisions to perform stem cell transplants upfront or to delay them until after JAK2 inhibitor therapy.

Have an insight to share? Post a comment.

mdales@frontlinemedcom.com

ALEXANDRIA, VA. – How are mutation analysis gene panels affecting risk stratification and decision making regarding stem cell transplants in myelofibrosis patients? How are the results of the Dynamic International Prognostic Scoring System (DIPSS) and performance status improvements seen with JAK2 inhibitors influencing who is a candidate for transplant and the timing of transplants?

Watch the conversation between Dr. Vikas Gupta of the leukemia and bone marrow transplant programs at the Princess Margaret Cancer Centre, Toronto, and associate professor of medicine at the University of Toronto, and Dr. Rami S. Komrokji of the Moffitt Cancer Center, Tampa, Fla., as they discuss their individual approaches that consider patient wishes and goals, type of donor, and disease risk in their decisions to perform stem cell transplants upfront or to delay them until after JAK2 inhibitor therapy.

Have an insight to share? Post a comment.

mdales@frontlinemedcom.com

ALEXANDRIA, VA. – How are mutation analysis gene panels affecting risk stratification and decision making regarding stem cell transplants in myelofibrosis patients? How are the results of the Dynamic International Prognostic Scoring System (DIPSS) and performance status improvements seen with JAK2 inhibitors influencing who is a candidate for transplant and the timing of transplants?

Watch the conversation between Dr. Vikas Gupta of the leukemia and bone marrow transplant programs at the Princess Margaret Cancer Centre, Toronto, and associate professor of medicine at the University of Toronto, and Dr. Rami S. Komrokji of the Moffitt Cancer Center, Tampa, Fla., as they discuss their individual approaches that consider patient wishes and goals, type of donor, and disease risk in their decisions to perform stem cell transplants upfront or to delay them until after JAK2 inhibitor therapy.

Have an insight to share? Post a comment.

mdales@frontlinemedcom.com

ALEXANDRIA, VA. – What are the emerging combination therapies for slowing disease progression and improving therapeutic tolerability in myeloproliferative neoplasms and myelodysplastic syndromes?

Join Dr. Jaroslaw Maciejewski, chairman of the department of translational hematology and oncology research at the Taussig Cancer Institute, Cleveland Clinic, and professor of medicine at the Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, and Dr. Ruben A. Mesa, chair of the Division of Hematology/Oncology, department of internal medicine, Mayo Clinic, Scottsdale, Arizona, for their one-on-one discussion of emerging treatment approaches. Then join the conversation by posting your comments and recommendations for other Heme Themes.

mdales@frontlinemedcom.com

ALEXANDRIA, VA. – What are the emerging combination therapies for slowing disease progression and improving therapeutic tolerability in myeloproliferative neoplasms and myelodysplastic syndromes?

Join Dr. Jaroslaw Maciejewski, chairman of the department of translational hematology and oncology research at the Taussig Cancer Institute, Cleveland Clinic, and professor of medicine at the Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, and Dr. Ruben A. Mesa, chair of the Division of Hematology/Oncology, department of internal medicine, Mayo Clinic, Scottsdale, Arizona, for their one-on-one discussion of emerging treatment approaches. Then join the conversation by posting your comments and recommendations for other Heme Themes.

mdales@frontlinemedcom.com

ALEXANDRIA, VA. – What are the emerging combination therapies for slowing disease progression and improving therapeutic tolerability in myeloproliferative neoplasms and myelodysplastic syndromes?

Join Dr. Jaroslaw Maciejewski, chairman of the department of translational hematology and oncology research at the Taussig Cancer Institute, Cleveland Clinic, and professor of medicine at the Cleveland Clinic Lerner College of Medicine of Case Western Reserve University, and Dr. Ruben A. Mesa, chair of the Division of Hematology/Oncology, department of internal medicine, Mayo Clinic, Scottsdale, Arizona, for their one-on-one discussion of emerging treatment approaches. Then join the conversation by posting your comments and recommendations for other Heme Themes.

mdales@frontlinemedcom.com

CTL019 cells

Photo from Penn Medicine

The chimeric antigen receptor (CAR) T-cell therapy CTL019 can produce durable responses in patients with relapsed/refractory chronic lymphocytic leukemia (CLL), according to research published in Science Translational Medicine.

Eight of 14 patients responded to CTL019—4 complete responses (CRs) and 4 partial responses (PRs).

Three of the patients with CRs were still alive and in remission at last follow-up. The longest remission has lasted 53 months.

Only 1 patient with a PR was still alive at last follow-up, and that patient progressed.

Nine patients developed cytokine release syndrome (CRS), some requiring intensive care. And there were 2 cases of tumor lysis syndrome.

These results are the most mature data from this trial. Results from this study were previously presented at ASH 2013 and ASH 2012, and they were published in NEJM and Science Translational Medicine in August 2011.

This study was supported by grants from Novartis, the Leukemia and Lymphoma Society, and the National Institutes of Health. CTL019 was originally developed at the University of Pennsylvania, but the university licensed the technology to Novartis.

Treatment and outcomes

The trial enrolled 23 CLL patients, but only 14 received CTL019. The 14 patients had a median age of 66 (range, 51 to 78), and most (n=14) were male.

They had received a median of 5 prior therapies (range, 1 to 11), and 8 patients had 17p deletion. All patients had active disease at the time of CTL019 infusion.

Patients received CTL019 at doses of 0.14 × 10⁸ to 11 × 10⁸ cells (median, 1.6 × 10⁸ cells). Eight patients responded to the treatment, for an overall response rate of 57%.

Four patients (29%) achieved a CR. One of these patients died while in remission at 21 months due to infectious complications that occurred after removal of a basal cell carcinoma on his leg.

The other 3 CR patients remained alive at the time of analysis, with no evidence of leukemia at 28 months, 52 months, and 53 months after receiving their infusions. They did not receive additional therapy after CTL019.

“The durability of the remissions we have observed in this study are remarkable and have given us great hope that personalized cell therapies are going to be important options for patients whose cancers are no longer treatable with standard approaches,” said study author David L. Porter, MD, of the University of Pennsylvania Perelman School of Medicine in Philadelphia.

Four patients (29%) achieved a PR after receiving CTL019, with responses lasting a median of 7 months. Two of these patients died of disease progression 10 months and 27 months after receiving CTL019.

One PR patient died after suffering a pulmonary embolism 6 months after CTL019 infusion. The last PR patient experienced disease progression at 13 months, but the patient remained alive on other therapies 36 months after receiving CTL019.

Six patients (43%) did not respond to CTL019 and progressed within 1 month to 9 months. Tests revealed that the modified T cells did not expand as robustly in these patients as in those who experienced remissions.

Two of these patients later died from their disease or complications of other therapies, and 4 are receiving other types of treatment.

CRS and other toxicity

The investigators said infusional toxicities were infrequent and mild (less than grade 2). They were primarily low-grade fevers and chills.

The most frequent related adverse events were associated with complications of neutropenia (including fevers) and delayed CRS, which was correlated with in vivo CTL019 expansion. Nine patients (including all 8 responders) developed CRS.

Five patients with CRS required anti-cytokine-directed therapy—tocilizumab (n=4) and/or steroids (n=3). Four patients required intensive care for complications related to CRS, such as hypotension and hypoxia. They remained in the intensive care unit for a median of 6 days (range, 1-9).

Concurrent with CRS were 6 neurologic events in 5 patients—grade 1/2 hallucinations, confusion, or delirium typically associated with high fevers, intensive care, or medication use. There was 1 case of grade 4 confusion that lasted 2 days and was attributed, at least partly, to CTL019.

There were 2 cases of tumor lysis syndrome. And 1 patient died in remission 21 months after CTL019 infusion, having developed overwhelming ecthyma gangrenosum from a pseudomonas wound infection from a skin biopsy site.

CTL019 durability

“Importantly, our tests of patients who experienced complete remissions showed that the modified cells remain in patients’ bodies for years after their infusions, with no sign of cancerous or normal B cells,” said study author Carl H. June, MD, of the University of Pennsylvania Perelman School of Medicine.

“This suggests that at least some of the CTL019 cells retain their ability to hunt for cancerous cells for long periods of time.”

A lab experiment using CAR T cells isolated from one of the first patients to receive CTL019 confirmed the potential for long-term function of these cells. At nearly 3 years after infusion, the patient’s CTL019 cells demonstrated immediate and specific reactivity against cells expressing CD19.

CTL019 development

The investigators did not identify demographic or disease-related factors, such as age or types of prior therapies, that could be used to predict response to CTL019. And there was no association between T-cell dose and patient response.

An ongoing dose-optimization study is exploring this relationship in greater detail. Further future areas of study may include strategies to combine CTL019 with immune checkpoint inhibitors or other therapies to stimulate T-cell recognition of tumor cells.

In addition to CLL, CTL019 is under investigation in patients with acute lymphoblastic leukemia, non-Hodgkin lymphoma, and myeloma. The product has breakthrough designation from the US Food and Drug Administration for acute lymphoblastic leukemia.

CTL019 cells

Photo from Penn Medicine

The chimeric antigen receptor (CAR) T-cell therapy CTL019 can produce durable responses in patients with relapsed/refractory chronic lymphocytic leukemia (CLL), according to research published in Science Translational Medicine.

Eight of 14 patients responded to CTL019—4 complete responses (CRs) and 4 partial responses (PRs).

Three of the patients with CRs were still alive and in remission at last follow-up. The longest remission has lasted 53 months.

Only 1 patient with a PR was still alive at last follow-up, and that patient progressed.

Nine patients developed cytokine release syndrome (CRS), some requiring intensive care. And there were 2 cases of tumor lysis syndrome.

These results are the most mature data from this trial. Results from this study were previously presented at ASH 2013 and ASH 2012, and they were published in NEJM and Science Translational Medicine in August 2011.

This study was supported by grants from Novartis, the Leukemia and Lymphoma Society, and the National Institutes of Health. CTL019 was originally developed at the University of Pennsylvania, but the university licensed the technology to Novartis.

Treatment and outcomes

The trial enrolled 23 CLL patients, but only 14 received CTL019. The 14 patients had a median age of 66 (range, 51 to 78), and most (n=14) were male.

They had received a median of 5 prior therapies (range, 1 to 11), and 8 patients had 17p deletion. All patients had active disease at the time of CTL019 infusion.

Patients received CTL019 at doses of 0.14 × 10⁸ to 11 × 10⁸ cells (median, 1.6 × 10⁸ cells). Eight patients responded to the treatment, for an overall response rate of 57%.

Four patients (29%) achieved a CR. One of these patients died while in remission at 21 months due to infectious complications that occurred after removal of a basal cell carcinoma on his leg.

The other 3 CR patients remained alive at the time of analysis, with no evidence of leukemia at 28 months, 52 months, and 53 months after receiving their infusions. They did not receive additional therapy after CTL019.

“The durability of the remissions we have observed in this study are remarkable and have given us great hope that personalized cell therapies are going to be important options for patients whose cancers are no longer treatable with standard approaches,” said study author David L. Porter, MD, of the University of Pennsylvania Perelman School of Medicine in Philadelphia.

Four patients (29%) achieved a PR after receiving CTL019, with responses lasting a median of 7 months. Two of these patients died of disease progression 10 months and 27 months after receiving CTL019.

One PR patient died after suffering a pulmonary embolism 6 months after CTL019 infusion. The last PR patient experienced disease progression at 13 months, but the patient remained alive on other therapies 36 months after receiving CTL019.

Six patients (43%) did not respond to CTL019 and progressed within 1 month to 9 months. Tests revealed that the modified T cells did not expand as robustly in these patients as in those who experienced remissions.

Two of these patients later died from their disease or complications of other therapies, and 4 are receiving other types of treatment.

CRS and other toxicity

The investigators said infusional toxicities were infrequent and mild (less than grade 2). They were primarily low-grade fevers and chills.

The most frequent related adverse events were associated with complications of neutropenia (including fevers) and delayed CRS, which was correlated with in vivo CTL019 expansion. Nine patients (including all 8 responders) developed CRS.

Five patients with CRS required anti-cytokine-directed therapy—tocilizumab (n=4) and/or steroids (n=3). Four patients required intensive care for complications related to CRS, such as hypotension and hypoxia. They remained in the intensive care unit for a median of 6 days (range, 1-9).

Concurrent with CRS were 6 neurologic events in 5 patients—grade 1/2 hallucinations, confusion, or delirium typically associated with high fevers, intensive care, or medication use. There was 1 case of grade 4 confusion that lasted 2 days and was attributed, at least partly, to CTL019.

There were 2 cases of tumor lysis syndrome. And 1 patient died in remission 21 months after CTL019 infusion, having developed overwhelming ecthyma gangrenosum from a pseudomonas wound infection from a skin biopsy site.

CTL019 durability

“Importantly, our tests of patients who experienced complete remissions showed that the modified cells remain in patients’ bodies for years after their infusions, with no sign of cancerous or normal B cells,” said study author Carl H. June, MD, of the University of Pennsylvania Perelman School of Medicine.

“This suggests that at least some of the CTL019 cells retain their ability to hunt for cancerous cells for long periods of time.”

A lab experiment using CAR T cells isolated from one of the first patients to receive CTL019 confirmed the potential for long-term function of these cells. At nearly 3 years after infusion, the patient’s CTL019 cells demonstrated immediate and specific reactivity against cells expressing CD19.

CTL019 development

The investigators did not identify demographic or disease-related factors, such as age or types of prior therapies, that could be used to predict response to CTL019. And there was no association between T-cell dose and patient response.

An ongoing dose-optimization study is exploring this relationship in greater detail. Further future areas of study may include strategies to combine CTL019 with immune checkpoint inhibitors or other therapies to stimulate T-cell recognition of tumor cells.

In addition to CLL, CTL019 is under investigation in patients with acute lymphoblastic leukemia, non-Hodgkin lymphoma, and myeloma. The product has breakthrough designation from the US Food and Drug Administration for acute lymphoblastic leukemia.

CTL019 cells

Photo from Penn Medicine

The chimeric antigen receptor (CAR) T-cell therapy CTL019 can produce durable responses in patients with relapsed/refractory chronic lymphocytic leukemia (CLL), according to research published in Science Translational Medicine.

Eight of 14 patients responded to CTL019—4 complete responses (CRs) and 4 partial responses (PRs).

Three of the patients with CRs were still alive and in remission at last follow-up. The longest remission has lasted 53 months.

Only 1 patient with a PR was still alive at last follow-up, and that patient progressed.

Nine patients developed cytokine release syndrome (CRS), some requiring intensive care. And there were 2 cases of tumor lysis syndrome.

These results are the most mature data from this trial. Results from this study were previously presented at ASH 2013 and ASH 2012, and they were published in NEJM and Science Translational Medicine in August 2011.

This study was supported by grants from Novartis, the Leukemia and Lymphoma Society, and the National Institutes of Health. CTL019 was originally developed at the University of Pennsylvania, but the university licensed the technology to Novartis.

Treatment and outcomes

The trial enrolled 23 CLL patients, but only 14 received CTL019. The 14 patients had a median age of 66 (range, 51 to 78), and most (n=14) were male.

They had received a median of 5 prior therapies (range, 1 to 11), and 8 patients had 17p deletion. All patients had active disease at the time of CTL019 infusion.

Patients received CTL019 at doses of 0.14 × 10⁸ to 11 × 10⁸ cells (median, 1.6 × 10⁸ cells). Eight patients responded to the treatment, for an overall response rate of 57%.

Four patients (29%) achieved a CR. One of these patients died while in remission at 21 months due to infectious complications that occurred after removal of a basal cell carcinoma on his leg.

The other 3 CR patients remained alive at the time of analysis, with no evidence of leukemia at 28 months, 52 months, and 53 months after receiving their infusions. They did not receive additional therapy after CTL019.

“The durability of the remissions we have observed in this study are remarkable and have given us great hope that personalized cell therapies are going to be important options for patients whose cancers are no longer treatable with standard approaches,” said study author David L. Porter, MD, of the University of Pennsylvania Perelman School of Medicine in Philadelphia.

Four patients (29%) achieved a PR after receiving CTL019, with responses lasting a median of 7 months. Two of these patients died of disease progression 10 months and 27 months after receiving CTL019.

One PR patient died after suffering a pulmonary embolism 6 months after CTL019 infusion. The last PR patient experienced disease progression at 13 months, but the patient remained alive on other therapies 36 months after receiving CTL019.

Six patients (43%) did not respond to CTL019 and progressed within 1 month to 9 months. Tests revealed that the modified T cells did not expand as robustly in these patients as in those who experienced remissions.

Two of these patients later died from their disease or complications of other therapies, and 4 are receiving other types of treatment.

CRS and other toxicity

The investigators said infusional toxicities were infrequent and mild (less than grade 2). They were primarily low-grade fevers and chills.

The most frequent related adverse events were associated with complications of neutropenia (including fevers) and delayed CRS, which was correlated with in vivo CTL019 expansion. Nine patients (including all 8 responders) developed CRS.

Five patients with CRS required anti-cytokine-directed therapy—tocilizumab (n=4) and/or steroids (n=3). Four patients required intensive care for complications related to CRS, such as hypotension and hypoxia. They remained in the intensive care unit for a median of 6 days (range, 1-9).

Concurrent with CRS were 6 neurologic events in 5 patients—grade 1/2 hallucinations, confusion, or delirium typically associated with high fevers, intensive care, or medication use. There was 1 case of grade 4 confusion that lasted 2 days and was attributed, at least partly, to CTL019.

There were 2 cases of tumor lysis syndrome. And 1 patient died in remission 21 months after CTL019 infusion, having developed overwhelming ecthyma gangrenosum from a pseudomonas wound infection from a skin biopsy site.

CTL019 durability

“Importantly, our tests of patients who experienced complete remissions showed that the modified cells remain in patients’ bodies for years after their infusions, with no sign of cancerous or normal B cells,” said study author Carl H. June, MD, of the University of Pennsylvania Perelman School of Medicine.

“This suggests that at least some of the CTL019 cells retain their ability to hunt for cancerous cells for long periods of time.”

A lab experiment using CAR T cells isolated from one of the first patients to receive CTL019 confirmed the potential for long-term function of these cells. At nearly 3 years after infusion, the patient’s CTL019 cells demonstrated immediate and specific reactivity against cells expressing CD19.

CTL019 development

The investigators did not identify demographic or disease-related factors, such as age or types of prior therapies, that could be used to predict response to CTL019. And there was no association between T-cell dose and patient response.

An ongoing dose-optimization study is exploring this relationship in greater detail. Further future areas of study may include strategies to combine CTL019 with immune checkpoint inhibitors or other therapies to stimulate T-cell recognition of tumor cells.

In addition to CLL, CTL019 is under investigation in patients with acute lymphoblastic leukemia, non-Hodgkin lymphoma, and myeloma. The product has breakthrough designation from the US Food and Drug Administration for acute lymphoblastic leukemia.

Patient receiving chemotherapy

Photo by Rhoda Baer

The US Food and Drug Administration (FDA) has approved rolapitant (Varubi) for use in adult cancer patients receiving initial and repeat courses of emetogenic chemotherapy.

Rolapitant is to be used in combination with other antiemetic agents to prevent delayed chemotherapy-induced nausea and vomiting (CINV).

Tesaro, Inc., the company developing rolapitant, plans to launch the drug in the fourth quarter of this year.

Rolapitant is a selective and competitive antagonist of human substance P/neurokinin 1 (NK-1) receptors, with a plasma half-life of approximately 7 days. Activation of NK-1 receptors plays a central role in CINV, particularly in the delayed phase (the 25- to 120-hour period after chemotherapy administration).

Rolapitant comes in tablet form. The recommended dose is 180 mg, given approximately 1 to 2 hours prior to chemotherapy administration in combination with a 5-HT3 receptor antagonist and dexamethasone. No dosage adjustment is required for dexamethasone when administering rolapitant.

Rolapitant inhibits the CYP2D6 enzyme, so it is contraindicated with the use of thioridazine, a drug metabolized by the CYP2D6 enzyme. Use of these drugs together may increase the amount of thioridazine in the blood and cause an abnormal heart rhythm that can be serious.

Rolapitant clinical trials

Results from three phase 3 trials suggested that rolapitant (at 180 mg) in combination with a 5-HT3 receptor antagonist and dexamethasone was more effective than the 5-HT3 receptor antagonist and dexamethasone on their own (active control).

The 3-drug combination demonstrated a significant reduction in episodes of vomiting or use of rescue medication during the 25- to 120-hour period following administration of highly emetogenic and moderately emetogenic chemotherapy regimens.

In addition, patients who received rolapitant reported experiencing less nausea that interfered with normal daily life and fewer episodes of vomiting or retching over multiple cycles of chemotherapy.

Highly emetogenic chemotherapy

The clinical profile of rolapitant in cisplatin-based, highly emetogenic chemotherapy (HEC) was confirmed in two phase 3 studies: HEC1 and HEC2. Results from these trials were recently published in The Lancet Oncology.

Both trials met their primary endpoint of complete response (CR) and demonstrated statistical superiority of the rolapitant combination compared to active control.

In HEC1, 264 patients received the rolapitant combination, and 262 received active control. The proportion of patients achieving a CR was 72.7% and 58.4%, respectively (P<0.001).

In HEC2, 271 patients received the rolapitant combination, and 273 received active control. The proportion of patients achieving a CR was 70.1% and 61.9%, respectively (P=0.043).

The most common adverse events (≥3%) were neutropenia (9% rolapitant and 8% control), hiccups (5% and 4%), and abdominal pain (3% and 2%).

Moderately emetogenic chemotherapy

Researchers conducted another phase 3 trial to compare the rolapitant combination with active control in 1332 patients receiving moderately emetogenic chemotherapy regimens. Results from this trial were recently published in The Lancet Oncology.

This trial met its primary endpoint of CR and demonstrated statistical superiority of the rolapitant combination compared to active control. The proportion of patients achieving a CR was 71.3% and 61.6%, respectively (P<0.001).

The most common adverse events (≥3%) were decreased appetite (9% rolapitant and 7% control), neutropenia (7% and 6%), dizziness (6% and 4%), dyspepsia (4% and 2%), urinary tract infection (4% and 3%), stomatitis (4% and 2%), and anemia (3% and 2%).

The full prescribing information for rolapitant is available at www.varubirx.com.

Patient receiving chemotherapy

Photo by Rhoda Baer

The US Food and Drug Administration (FDA) has approved rolapitant (Varubi) for use in adult cancer patients receiving initial and repeat courses of emetogenic chemotherapy.

Rolapitant is to be used in combination with other antiemetic agents to prevent delayed chemotherapy-induced nausea and vomiting (CINV).

Tesaro, Inc., the company developing rolapitant, plans to launch the drug in the fourth quarter of this year.

Rolapitant is a selective and competitive antagonist of human substance P/neurokinin 1 (NK-1) receptors, with a plasma half-life of approximately 7 days. Activation of NK-1 receptors plays a central role in CINV, particularly in the delayed phase (the 25- to 120-hour period after chemotherapy administration).

Rolapitant comes in tablet form. The recommended dose is 180 mg, given approximately 1 to 2 hours prior to chemotherapy administration in combination with a 5-HT3 receptor antagonist and dexamethasone. No dosage adjustment is required for dexamethasone when administering rolapitant.

Rolapitant inhibits the CYP2D6 enzyme, so it is contraindicated with the use of thioridazine, a drug metabolized by the CYP2D6 enzyme. Use of these drugs together may increase the amount of thioridazine in the blood and cause an abnormal heart rhythm that can be serious.

Rolapitant clinical trials

Results from three phase 3 trials suggested that rolapitant (at 180 mg) in combination with a 5-HT3 receptor antagonist and dexamethasone was more effective than the 5-HT3 receptor antagonist and dexamethasone on their own (active control).

The 3-drug combination demonstrated a significant reduction in episodes of vomiting or use of rescue medication during the 25- to 120-hour period following administration of highly emetogenic and moderately emetogenic chemotherapy regimens.

In addition, patients who received rolapitant reported experiencing less nausea that interfered with normal daily life and fewer episodes of vomiting or retching over multiple cycles of chemotherapy.

Highly emetogenic chemotherapy

The clinical profile of rolapitant in cisplatin-based, highly emetogenic chemotherapy (HEC) was confirmed in two phase 3 studies: HEC1 and HEC2. Results from these trials were recently published in The Lancet Oncology.

Both trials met their primary endpoint of complete response (CR) and demonstrated statistical superiority of the rolapitant combination compared to active control.

In HEC1, 264 patients received the rolapitant combination, and 262 received active control. The proportion of patients achieving a CR was 72.7% and 58.4%, respectively (P<0.001).

In HEC2, 271 patients received the rolapitant combination, and 273 received active control. The proportion of patients achieving a CR was 70.1% and 61.9%, respectively (P=0.043).

The most common adverse events (≥3%) were neutropenia (9% rolapitant and 8% control), hiccups (5% and 4%), and abdominal pain (3% and 2%).

Moderately emetogenic chemotherapy

Researchers conducted another phase 3 trial to compare the rolapitant combination with active control in 1332 patients receiving moderately emetogenic chemotherapy regimens. Results from this trial were recently published in The Lancet Oncology.

This trial met its primary endpoint of CR and demonstrated statistical superiority of the rolapitant combination compared to active control. The proportion of patients achieving a CR was 71.3% and 61.6%, respectively (P<0.001).

The most common adverse events (≥3%) were decreased appetite (9% rolapitant and 7% control), neutropenia (7% and 6%), dizziness (6% and 4%), dyspepsia (4% and 2%), urinary tract infection (4% and 3%), stomatitis (4% and 2%), and anemia (3% and 2%).

The full prescribing information for rolapitant is available at www.varubirx.com.

Patient receiving chemotherapy

Photo by Rhoda Baer

The US Food and Drug Administration (FDA) has approved rolapitant (Varubi) for use in adult cancer patients receiving initial and repeat courses of emetogenic chemotherapy.

Rolapitant is to be used in combination with other antiemetic agents to prevent delayed chemotherapy-induced nausea and vomiting (CINV).

Tesaro, Inc., the company developing rolapitant, plans to launch the drug in the fourth quarter of this year.

Rolapitant is a selective and competitive antagonist of human substance P/neurokinin 1 (NK-1) receptors, with a plasma half-life of approximately 7 days. Activation of NK-1 receptors plays a central role in CINV, particularly in the delayed phase (the 25- to 120-hour period after chemotherapy administration).

Rolapitant comes in tablet form. The recommended dose is 180 mg, given approximately 1 to 2 hours prior to chemotherapy administration in combination with a 5-HT3 receptor antagonist and dexamethasone. No dosage adjustment is required for dexamethasone when administering rolapitant.

Rolapitant inhibits the CYP2D6 enzyme, so it is contraindicated with the use of thioridazine, a drug metabolized by the CYP2D6 enzyme. Use of these drugs together may increase the amount of thioridazine in the blood and cause an abnormal heart rhythm that can be serious.

Rolapitant clinical trials

Results from three phase 3 trials suggested that rolapitant (at 180 mg) in combination with a 5-HT3 receptor antagonist and dexamethasone was more effective than the 5-HT3 receptor antagonist and dexamethasone on their own (active control).

The 3-drug combination demonstrated a significant reduction in episodes of vomiting or use of rescue medication during the 25- to 120-hour period following administration of highly emetogenic and moderately emetogenic chemotherapy regimens.

In addition, patients who received rolapitant reported experiencing less nausea that interfered with normal daily life and fewer episodes of vomiting or retching over multiple cycles of chemotherapy.

Highly emetogenic chemotherapy

The clinical profile of rolapitant in cisplatin-based, highly emetogenic chemotherapy (HEC) was confirmed in two phase 3 studies: HEC1 and HEC2. Results from these trials were recently published in The Lancet Oncology.

Both trials met their primary endpoint of complete response (CR) and demonstrated statistical superiority of the rolapitant combination compared to active control.

In HEC1, 264 patients received the rolapitant combination, and 262 received active control. The proportion of patients achieving a CR was 72.7% and 58.4%, respectively (P<0.001).

In HEC2, 271 patients received the rolapitant combination, and 273 received active control. The proportion of patients achieving a CR was 70.1% and 61.9%, respectively (P=0.043).

The most common adverse events (≥3%) were neutropenia (9% rolapitant and 8% control), hiccups (5% and 4%), and abdominal pain (3% and 2%).

Moderately emetogenic chemotherapy

Researchers conducted another phase 3 trial to compare the rolapitant combination with active control in 1332 patients receiving moderately emetogenic chemotherapy regimens. Results from this trial were recently published in The Lancet Oncology.

This trial met its primary endpoint of CR and demonstrated statistical superiority of the rolapitant combination compared to active control. The proportion of patients achieving a CR was 71.3% and 61.6%, respectively (P<0.001).

The most common adverse events (≥3%) were decreased appetite (9% rolapitant and 7% control), neutropenia (7% and 6%), dizziness (6% and 4%), dyspepsia (4% and 2%), urinary tract infection (4% and 3%), stomatitis (4% and 2%), and anemia (3% and 2%).

The full prescribing information for rolapitant is available at www.varubirx.com.

Treatment with chimeric antigen receptor (CAR)-modified T cells targeting CD19 achieved a response in 8 of 14 patients (57%) with advanced chronic lymphocytic leukemia (CLL), of whom 4 experienced a complete remission without relapse, based on the mature results of a small pilot study.

Of these four patients, two have remained free of their disease for up to 4 years after they received treatment. An analysis of blood samples also showed that these modified T cells can multiply and persist in the body for a period of years, the researchers report in a study published Sept. 2 in Science Translational Medicine

“Both patients remain alive and cancer free and just passed the 5-year anniversary of their treatment this summer,” said Dr. David L. Porter, the Jodi Fisher Horowitz Professor in Leukemia Care Excellence and director of blood and marrow transplantation at the University of Pennsylvania’s Abramson Cancer Center in Philadelphia. “A third patient in remission just passed the 3-year anniversary with no signs of leukemia” (Sci Transl Med. 2015;7:303ra139).

The current study indicates the mature results from this trial, which began in the summer of 2010. In 2011, preliminary findings from the first three patients to enroll in the study were published and showed that two of them had experienced a complete response. Their disease currently remains in remission more than 4 years after beginning treatment. The first patient to receive the therapy has been cancer free for 5 years.

© Ed Uthman/Flickr

In the current trial, 14 patients with relapsed or refractory CLL received at least one infusion of autologous T cells transduced with a CD19-directed CAR (CTL019) lentiviral vector. All of the patients had active disease at the time they received the experimental treatment, and had received a median of 5 previous therapies (range, 1-11). One participant had undergone two previous autologous stem cell transplants and one had progressed on ibrutinib therapy.

In addition to those who achieved a complete remission, four other patients (29%) had partial responses to the therapy with responses that persisted for a median of 7 months. Two died of disease progression at 10 and 27 months after receiving CTL019, and one died from a pulmonary embolism; the remaining patient remains alive after CLL progressed at 13 months, and is receiving other therapies.

Overall, the CTL019 infusions were well tolerated, with grade less than 2 toxicities that included primarily low-grade fevers and chills. The most frequent related events were associated with complications of neutropenia and delayed cytokine release syndrome, which correlated with in vivo CTL019 expansion. There were two cases of tumor lysis syndrome, and one patient died in remission 21 months after T cell infusion, after developing ecthyma gangrenosum after pseudomonas infection at a skin biopsy site.

Six subjects (43%) had no response and all six progressed within 1-9 months (median, 4 months) of CTL019 therapy. “We are working hard to determine why this therapy may be appropriate for some patients and not others, and trying to optimize either treatment conditions or patient-specific factors so that this might be more effective for more patients,” Dr. Porter wrote.

Minimal residual disease was not detectable in patients who achieved a complete response, suggesting that disease eradication may be possible in some patients with advanced CLL. The activity of CTLO19 seemed to be on par with results achieved with allogeneic stem cell transplantation, suggesting that this therapy could possibly cure CLL. But Dr. Porter pointed out that this study was conducted with a small number of patients and for CLL, a relatively short follow-up.

“However, these patients all had heavily pretreated resistant disease,” he said. “Though we do not know if patients are indeed cured, it is certainly our goal to find a cure for CLL and without the toxicities and limitations of allogeneic stem cell transplantation. Indeed, longer follow-up will be needed but we are quite excited about the results to date.”

Dr. Porter said he and his team have ongoing trials in CLL in progress, where they are working on trying to identify the optimal dose of T cells for this approach. Also, “this research has led to expansion of this approach to other B cell malignancies such as acute lymphocytic leukemia.”

Novartis, the Leukemia and Lymphoma Society (Specialized Center of Research Award), and the National Institutes of Health funded the study. The University of Pennsylvania has licensed technologies involved in this trial to Novartis. Some scientists involved in these trials, including Dr. Porter, are inventors of these technologies. As a result of the licensing relationship with Novartis, the University of Pennsylvania receives significant financial benefit, and these inventors have benefited financially and/or may benefit financially in the future.

Treatment with chimeric antigen receptor (CAR)-modified T cells targeting CD19 achieved a response in 8 of 14 patients (57%) with advanced chronic lymphocytic leukemia (CLL), of whom 4 experienced a complete remission without relapse, based on the mature results of a small pilot study.

Of these four patients, two have remained free of their disease for up to 4 years after they received treatment. An analysis of blood samples also showed that these modified T cells can multiply and persist in the body for a period of years, the researchers report in a study published Sept. 2 in Science Translational Medicine

“Both patients remain alive and cancer free and just passed the 5-year anniversary of their treatment this summer,” said Dr. David L. Porter, the Jodi Fisher Horowitz Professor in Leukemia Care Excellence and director of blood and marrow transplantation at the University of Pennsylvania’s Abramson Cancer Center in Philadelphia. “A third patient in remission just passed the 3-year anniversary with no signs of leukemia” (Sci Transl Med. 2015;7:303ra139).

The current study indicates the mature results from this trial, which began in the summer of 2010. In 2011, preliminary findings from the first three patients to enroll in the study were published and showed that two of them had experienced a complete response. Their disease currently remains in remission more than 4 years after beginning treatment. The first patient to receive the therapy has been cancer free for 5 years.

© Ed Uthman/Flickr

In the current trial, 14 patients with relapsed or refractory CLL received at least one infusion of autologous T cells transduced with a CD19-directed CAR (CTL019) lentiviral vector. All of the patients had active disease at the time they received the experimental treatment, and had received a median of 5 previous therapies (range, 1-11). One participant had undergone two previous autologous stem cell transplants and one had progressed on ibrutinib therapy.

In addition to those who achieved a complete remission, four other patients (29%) had partial responses to the therapy with responses that persisted for a median of 7 months. Two died of disease progression at 10 and 27 months after receiving CTL019, and one died from a pulmonary embolism; the remaining patient remains alive after CLL progressed at 13 months, and is receiving other therapies.

Overall, the CTL019 infusions were well tolerated, with grade less than 2 toxicities that included primarily low-grade fevers and chills. The most frequent related events were associated with complications of neutropenia and delayed cytokine release syndrome, which correlated with in vivo CTL019 expansion. There were two cases of tumor lysis syndrome, and one patient died in remission 21 months after T cell infusion, after developing ecthyma gangrenosum after pseudomonas infection at a skin biopsy site.

Six subjects (43%) had no response and all six progressed within 1-9 months (median, 4 months) of CTL019 therapy. “We are working hard to determine why this therapy may be appropriate for some patients and not others, and trying to optimize either treatment conditions or patient-specific factors so that this might be more effective for more patients,” Dr. Porter wrote.

Minimal residual disease was not detectable in patients who achieved a complete response, suggesting that disease eradication may be possible in some patients with advanced CLL. The activity of CTLO19 seemed to be on par with results achieved with allogeneic stem cell transplantation, suggesting that this therapy could possibly cure CLL. But Dr. Porter pointed out that this study was conducted with a small number of patients and for CLL, a relatively short follow-up.

“However, these patients all had heavily pretreated resistant disease,” he said. “Though we do not know if patients are indeed cured, it is certainly our goal to find a cure for CLL and without the toxicities and limitations of allogeneic stem cell transplantation. Indeed, longer follow-up will be needed but we are quite excited about the results to date.”

Dr. Porter said he and his team have ongoing trials in CLL in progress, where they are working on trying to identify the optimal dose of T cells for this approach. Also, “this research has led to expansion of this approach to other B cell malignancies such as acute lymphocytic leukemia.”

Novartis, the Leukemia and Lymphoma Society (Specialized Center of Research Award), and the National Institutes of Health funded the study. The University of Pennsylvania has licensed technologies involved in this trial to Novartis. Some scientists involved in these trials, including Dr. Porter, are inventors of these technologies. As a result of the licensing relationship with Novartis, the University of Pennsylvania receives significant financial benefit, and these inventors have benefited financially and/or may benefit financially in the future.

Treatment with chimeric antigen receptor (CAR)-modified T cells targeting CD19 achieved a response in 8 of 14 patients (57%) with advanced chronic lymphocytic leukemia (CLL), of whom 4 experienced a complete remission without relapse, based on the mature results of a small pilot study.

Of these four patients, two have remained free of their disease for up to 4 years after they received treatment. An analysis of blood samples also showed that these modified T cells can multiply and persist in the body for a period of years, the researchers report in a study published Sept. 2 in Science Translational Medicine

“Both patients remain alive and cancer free and just passed the 5-year anniversary of their treatment this summer,” said Dr. David L. Porter, the Jodi Fisher Horowitz Professor in Leukemia Care Excellence and director of blood and marrow transplantation at the University of Pennsylvania’s Abramson Cancer Center in Philadelphia. “A third patient in remission just passed the 3-year anniversary with no signs of leukemia” (Sci Transl Med. 2015;7:303ra139).

The current study indicates the mature results from this trial, which began in the summer of 2010. In 2011, preliminary findings from the first three patients to enroll in the study were published and showed that two of them had experienced a complete response. Their disease currently remains in remission more than 4 years after beginning treatment. The first patient to receive the therapy has been cancer free for 5 years.

© Ed Uthman/Flickr

In the current trial, 14 patients with relapsed or refractory CLL received at least one infusion of autologous T cells transduced with a CD19-directed CAR (CTL019) lentiviral vector. All of the patients had active disease at the time they received the experimental treatment, and had received a median of 5 previous therapies (range, 1-11). One participant had undergone two previous autologous stem cell transplants and one had progressed on ibrutinib therapy.

In addition to those who achieved a complete remission, four other patients (29%) had partial responses to the therapy with responses that persisted for a median of 7 months. Two died of disease progression at 10 and 27 months after receiving CTL019, and one died from a pulmonary embolism; the remaining patient remains alive after CLL progressed at 13 months, and is receiving other therapies.

Overall, the CTL019 infusions were well tolerated, with grade less than 2 toxicities that included primarily low-grade fevers and chills. The most frequent related events were associated with complications of neutropenia and delayed cytokine release syndrome, which correlated with in vivo CTL019 expansion. There were two cases of tumor lysis syndrome, and one patient died in remission 21 months after T cell infusion, after developing ecthyma gangrenosum after pseudomonas infection at a skin biopsy site.

Six subjects (43%) had no response and all six progressed within 1-9 months (median, 4 months) of CTL019 therapy. “We are working hard to determine why this therapy may be appropriate for some patients and not others, and trying to optimize either treatment conditions or patient-specific factors so that this might be more effective for more patients,” Dr. Porter wrote.

Minimal residual disease was not detectable in patients who achieved a complete response, suggesting that disease eradication may be possible in some patients with advanced CLL. The activity of CTLO19 seemed to be on par with results achieved with allogeneic stem cell transplantation, suggesting that this therapy could possibly cure CLL. But Dr. Porter pointed out that this study was conducted with a small number of patients and for CLL, a relatively short follow-up.

“However, these patients all had heavily pretreated resistant disease,” he said. “Though we do not know if patients are indeed cured, it is certainly our goal to find a cure for CLL and without the toxicities and limitations of allogeneic stem cell transplantation. Indeed, longer follow-up will be needed but we are quite excited about the results to date.”

Dr. Porter said he and his team have ongoing trials in CLL in progress, where they are working on trying to identify the optimal dose of T cells for this approach. Also, “this research has led to expansion of this approach to other B cell malignancies such as acute lymphocytic leukemia.”

Novartis, the Leukemia and Lymphoma Society (Specialized Center of Research Award), and the National Institutes of Health funded the study. The University of Pennsylvania has licensed technologies involved in this trial to Novartis. Some scientists involved in these trials, including Dr. Porter, are inventors of these technologies. As a result of the licensing relationship with Novartis, the University of Pennsylvania receives significant financial benefit, and these inventors have benefited financially and/or may benefit financially in the future.

Doctor consults with cancer

patient and her father

Photo by Rhoda Baer

Exome and transcriptome sequencing results can inform the management of young patients with relapsed, refractory, and rare malignancies, a new study suggests.

In a consecutive case series, sequencing data revealed potentially actionable findings for 46% of patients.

As a result, 15% of patients changed treatment, and 10% underwent genetic counseling.

Investigators described this research in JAMA.

“We found that, for some children with rare, difficult-to-treat, and aggressive cancers, this technology can dramatically change the course of their treatment,” said study author Rajen Mody, MBBS, of the University of Michigan in Ann Arbor.

Dr Mody and his colleagues evaluated 102 patients with relapsed, refractory, or rare cancers. Their median age was 11.5 (range, 0-22).

The patients underwent integrative clinical exome (tumor and germline DNA) and transcriptome (tumor RNA) sequencing. Ninety-one patients (89%) had adequate tumor tissue to complete sequencing, including 28 patients (31%) with hematologic malignancies and 63 (69%) with solid tumors.

All sequencing results were discussed at a precision medicine tumor board, which included pediatric and adult oncologists, pathologists, genetics specialists, and other professionals. This group discussed the results and assessed the feasibility of pursuing treatment options based on the findings.

Actionable findings

Forty-two patients (46%) had potentially actionable findings, 15 (54%) with hematologic malignancies and 27 (43%) with solid tumors.

Actionable findings included a change in diagnosis (n=2), the presence of a genetic anomaly that could be targeted by an approved or experimental drug (n=31), and the need for genetic counseling for inherited cancer risk that could affect the patient or the whole family (n=9).

“We were excited to see an actionable finding in such a substantial percentage of patients, and we think it could potentially be higher over time,” said study author Arul Chinnaiyan, MD, PhD, also of the University of Michigan.

“These are patients who had exhausted all proven therapeutic options or who had an extremely rare diagnosis. If we can find a clinically actionable event and have a chance to act upon it, we show in this study that it can have a big impact on that patient.”

Actions were taken in 23 of the 42 patients. Fourteen patients (15%) had their treatment changed, and 9 of these patients (10%) had durable partial or complete remissions (CRs) as a result.

Nine patients (10%) underwent genetic counseling because of sequencing results. The researchers noted that 4 of these patients had no notable family history to suggest an inherited risk, and they would not otherwise have been referred for genetic counseling.

Hematologic malignancies

Fifteen patients with hematologic malignancies had potentially actionable findings, and 4 underwent treatment changes as a result. (None of the patients required genetic counseling.)

For a patient with pre-B acute lymphoblastic leukemia (ALL), sequencing revealed a homozygous CDKN2A deletion and an ETV6-ABL1 fusion. So the patient was placed on imatinib and had a sustained CR for 21 months.

A patient with early T-cell precursor ALL had a FLT3-ITD mutation, Chr16p gain, Chr16q loss, and FLT3 overexpression. The patient achieved a CR after transplant, was placed on the FLT3 inhibitor sorafenib, and remained in CR for 15 months.

Another patient with pre-B ALL had a FLT3 nonframeshift deletion and BLK and FLT3 overexpression. The patient was in CR for 9 months after a transplant and received sorafenib for 6 months.

A patient with biphenotypic leukemia had mutations in NRAS and PHF6; SPI1, ASXL1, and CBLC frameshift insertions; a JAK3-activating mutation; and JAK3 overexpression. The patient received the JAK3 inhibitor tofacitinib but could not tolerate the full dose and died of progressive disease.

Cost and turn-around time

The cost for sequencing was approximately $6000 per patient and was covered under the research protocol.

It took the researchers about 7 to 8 weeks to report the sequencing results back to treating physicians and families.

“These are early days, and the full promise of precision medicine is yet to be fully realized,” Dr Mody said. “We need better targeted therapies designed for children, and turnaround time for sequencing needs to be less than 2 weeks for it to be a regular part of a patient’s treatment plan.”

Doctor consults with cancer

patient and her father

Photo by Rhoda Baer

Exome and transcriptome sequencing results can inform the management of young patients with relapsed, refractory, and rare malignancies, a new study suggests.

In a consecutive case series, sequencing data revealed potentially actionable findings for 46% of patients.

As a result, 15% of patients changed treatment, and 10% underwent genetic counseling.

Investigators described this research in JAMA.

“We found that, for some children with rare, difficult-to-treat, and aggressive cancers, this technology can dramatically change the course of their treatment,” said study author Rajen Mody, MBBS, of the University of Michigan in Ann Arbor.

Dr Mody and his colleagues evaluated 102 patients with relapsed, refractory, or rare cancers. Their median age was 11.5 (range, 0-22).

The patients underwent integrative clinical exome (tumor and germline DNA) and transcriptome (tumor RNA) sequencing. Ninety-one patients (89%) had adequate tumor tissue to complete sequencing, including 28 patients (31%) with hematologic malignancies and 63 (69%) with solid tumors.

All sequencing results were discussed at a precision medicine tumor board, which included pediatric and adult oncologists, pathologists, genetics specialists, and other professionals. This group discussed the results and assessed the feasibility of pursuing treatment options based on the findings.

Actionable findings

Forty-two patients (46%) had potentially actionable findings, 15 (54%) with hematologic malignancies and 27 (43%) with solid tumors.

Actionable findings included a change in diagnosis (n=2), the presence of a genetic anomaly that could be targeted by an approved or experimental drug (n=31), and the need for genetic counseling for inherited cancer risk that could affect the patient or the whole family (n=9).

“We were excited to see an actionable finding in such a substantial percentage of patients, and we think it could potentially be higher over time,” said study author Arul Chinnaiyan, MD, PhD, also of the University of Michigan.

“These are patients who had exhausted all proven therapeutic options or who had an extremely rare diagnosis. If we can find a clinically actionable event and have a chance to act upon it, we show in this study that it can have a big impact on that patient.”

Actions were taken in 23 of the 42 patients. Fourteen patients (15%) had their treatment changed, and 9 of these patients (10%) had durable partial or complete remissions (CRs) as a result.

Nine patients (10%) underwent genetic counseling because of sequencing results. The researchers noted that 4 of these patients had no notable family history to suggest an inherited risk, and they would not otherwise have been referred for genetic counseling.

Hematologic malignancies

Fifteen patients with hematologic malignancies had potentially actionable findings, and 4 underwent treatment changes as a result. (None of the patients required genetic counseling.)

For a patient with pre-B acute lymphoblastic leukemia (ALL), sequencing revealed a homozygous CDKN2A deletion and an ETV6-ABL1 fusion. So the patient was placed on imatinib and had a sustained CR for 21 months.

A patient with early T-cell precursor ALL had a FLT3-ITD mutation, Chr16p gain, Chr16q loss, and FLT3 overexpression. The patient achieved a CR after transplant, was placed on the FLT3 inhibitor sorafenib, and remained in CR for 15 months.

Another patient with pre-B ALL had a FLT3 nonframeshift deletion and BLK and FLT3 overexpression. The patient was in CR for 9 months after a transplant and received sorafenib for 6 months.

A patient with biphenotypic leukemia had mutations in NRAS and PHF6; SPI1, ASXL1, and CBLC frameshift insertions; a JAK3-activating mutation; and JAK3 overexpression. The patient received the JAK3 inhibitor tofacitinib but could not tolerate the full dose and died of progressive disease.

Cost and turn-around time

The cost for sequencing was approximately $6000 per patient and was covered under the research protocol.

It took the researchers about 7 to 8 weeks to report the sequencing results back to treating physicians and families.

“These are early days, and the full promise of precision medicine is yet to be fully realized,” Dr Mody said. “We need better targeted therapies designed for children, and turnaround time for sequencing needs to be less than 2 weeks for it to be a regular part of a patient’s treatment plan.”

Doctor consults with cancer

patient and her father

Photo by Rhoda Baer

Exome and transcriptome sequencing results can inform the management of young patients with relapsed, refractory, and rare malignancies, a new study suggests.

In a consecutive case series, sequencing data revealed potentially actionable findings for 46% of patients.

As a result, 15% of patients changed treatment, and 10% underwent genetic counseling.

Investigators described this research in JAMA.

“We found that, for some children with rare, difficult-to-treat, and aggressive cancers, this technology can dramatically change the course of their treatment,” said study author Rajen Mody, MBBS, of the University of Michigan in Ann Arbor.

Dr Mody and his colleagues evaluated 102 patients with relapsed, refractory, or rare cancers. Their median age was 11.5 (range, 0-22).

The patients underwent integrative clinical exome (tumor and germline DNA) and transcriptome (tumor RNA) sequencing. Ninety-one patients (89%) had adequate tumor tissue to complete sequencing, including 28 patients (31%) with hematologic malignancies and 63 (69%) with solid tumors.

All sequencing results were discussed at a precision medicine tumor board, which included pediatric and adult oncologists, pathologists, genetics specialists, and other professionals. This group discussed the results and assessed the feasibility of pursuing treatment options based on the findings.

Actionable findings

Forty-two patients (46%) had potentially actionable findings, 15 (54%) with hematologic malignancies and 27 (43%) with solid tumors.

Actionable findings included a change in diagnosis (n=2), the presence of a genetic anomaly that could be targeted by an approved or experimental drug (n=31), and the need for genetic counseling for inherited cancer risk that could affect the patient or the whole family (n=9).

“We were excited to see an actionable finding in such a substantial percentage of patients, and we think it could potentially be higher over time,” said study author Arul Chinnaiyan, MD, PhD, also of the University of Michigan.

“These are patients who had exhausted all proven therapeutic options or who had an extremely rare diagnosis. If we can find a clinically actionable event and have a chance to act upon it, we show in this study that it can have a big impact on that patient.”

Actions were taken in 23 of the 42 patients. Fourteen patients (15%) had their treatment changed, and 9 of these patients (10%) had durable partial or complete remissions (CRs) as a result.

Nine patients (10%) underwent genetic counseling because of sequencing results. The researchers noted that 4 of these patients had no notable family history to suggest an inherited risk, and they would not otherwise have been referred for genetic counseling.

Hematologic malignancies

Fifteen patients with hematologic malignancies had potentially actionable findings, and 4 underwent treatment changes as a result. (None of the patients required genetic counseling.)

For a patient with pre-B acute lymphoblastic leukemia (ALL), sequencing revealed a homozygous CDKN2A deletion and an ETV6-ABL1 fusion. So the patient was placed on imatinib and had a sustained CR for 21 months.

A patient with early T-cell precursor ALL had a FLT3-ITD mutation, Chr16p gain, Chr16q loss, and FLT3 overexpression. The patient achieved a CR after transplant, was placed on the FLT3 inhibitor sorafenib, and remained in CR for 15 months.

Another patient with pre-B ALL had a FLT3 nonframeshift deletion and BLK and FLT3 overexpression. The patient was in CR for 9 months after a transplant and received sorafenib for 6 months.

A patient with biphenotypic leukemia had mutations in NRAS and PHF6; SPI1, ASXL1, and CBLC frameshift insertions; a JAK3-activating mutation; and JAK3 overexpression. The patient received the JAK3 inhibitor tofacitinib but could not tolerate the full dose and died of progressive disease.

Cost and turn-around time

The cost for sequencing was approximately $6000 per patient and was covered under the research protocol.

It took the researchers about 7 to 8 weeks to report the sequencing results back to treating physicians and families.

“These are early days, and the full promise of precision medicine is yet to be fully realized,” Dr Mody said. “We need better targeted therapies designed for children, and turnaround time for sequencing needs to be less than 2 weeks for it to be a regular part of a patient’s treatment plan.”