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leading to safer treatment and better outcomes, according to a recent review.
Nanomedicines homing in on the Wnt/beta-catenin signaling pathway could be particularly impactful, Mamatha Bhat, MD, PhD, a hepatologist and clinician-scientist at Toronto General Hospital Research Institute, and colleagues reported, as this is one of the most up-regulated pathways in HCC.
To date, however, agents addressing this pathway have been hindered by off-target toxicity, suggesting that more work is needed to develop the right payload for nanoparticle delivery, the investigators wrote in Gastro Hep Advances.
“Although nanotherapeutics offers an unmatched improvement in drug delivery, due to the limited impact and treatment-resistance demonstrated by the current systemic therapies, there is currently no approved nanomedicine for the treatment of HCC,” the investigators wrote. “Therefore, it is of utmost importance to dig deeper into understanding the signaling pathways that govern hepatocarcinogenesis and identify novel targets that can be used to develop more specific and targeted nanotherapies.”
Their review focused on the Wnt/beta-catenin signaling pathway, but first, Dr. Bhat and colleagues discussed the characteristics of inorganic versus lipid nanoparticles, as these differences can determine liver uptake.
Inorganic nanoparticles have a high surface-to-volume ratio, leading to increased surface charges that enhance cellular uptake. However, they are prone to oxidation, requiring surface modifications or short circulation times to prevent degradation. These nanoparticles are limited in delivering chemotherapeutic drugs and peptides, and are not suitable for encapsulating nucleic acids.
In contrast, lipid nanoparticles are preferred for targeted delivery in HCC, according to the investigators. They have a natural affinity for apolipoprotein E (apo E), resembling lipoproteins, which aids in specific liver cell targeting. When lipid nanoparticles enter the bloodstream, they interact with apo E–rich lipoproteins like HDL cholesterol and LDL cholesterol, leading to formation of complexes recognized by LDL cholesterol receptors on liver cells. This triggers receptor-mediated endocytosis, internalizing apo E–lipid nanoparticle complexes into HCC cells.
The other major variable is the selected treatment target. Dr. Bhat and colleagues made the case for the Wnt/beta-catenin signaling pathway based on alterations found in approximately two-thirds of patients with HCC.
“Aberrant activation of this pathway and mutations in genes encoding key components are characteristic to hepatocarcinogenesis and promote tumor growth and dedifferentiation,” they wrote.
Although beta-catenin itself makes for an obvious molecular target, especially considering known associations with drug resistance, its flat structure lacks deep binding pockets that would be suitable for small-molecule inhibitors, and any available pockets may be altered by numerous posttranscriptional modifications. Instead, beta-catenin could be indirectly modulated by nanoparticle-mediated siRNA therapy, as this would allow for precise delivery of siRNA to cancer cells, minimizing off-target toxicity.
Alternative approaches could involve targeting proteasomal degradation of beta-catenin, transcriptional coactivators of beta-catenin, or different oncogenes in HCC, all of which are described in further detail in the review, along with promising preclinical findings.
“With ongoing advancements in nanotechnology, there is optimism that it will continue to play a vital role in overcoming the challenges associated with HCC management and contribute to further advancements in therapeutic outcomes for patients,” the authors concluded.
One coauthor disclosed external funding by a Mitacs Elevate postdoctoral fellowship in collaboration with Highland Therapeutics. The remaining authors disclosed no conflicts of interest.
Hepatocellular Carcinoma (HCC) remains a major health problem associate with increasing prevalence and mortality rates worldwide. Around 50-60% of HCC patients are exposed to systemic therapies during their natural history. Atezolizumab plus bevacizumab (median OS: 19.2mo, ORR 30%), and durvalumab plus tremelimumab (median OS: 16.4mo, ORR: 20%) are considered first line treatment options for advanced HCC, and sorafenib or lenvatinib are recommended for patients with any contraindication for immune checkpoint inhibitors. These therapies are indicated for ‘all comers’ an no molecular markers /personalize medicine is currently available for this cancer. The lack of precision oncology relates to the fact that the most common mutations ( i.e TERT, TP53,CTNNB1) are unactionable targets. In this scenario, advances in precision oncology are an unmet medical need.
The Wnt/B-catenin signaling pathway is a master regulator of oncogenesis in HCC and defines one of the molecular subclasses characterized by CTNNB1 mutations (~25-30%) or AXIN1 mutations (~5-10%). Most of these tumors have an immune excluded/desert phenotype. Thus, targeting this pathway is expected to provide a primary antitumoral effect along with an immune-modulatory effect rescuing cases with an immune excluded phenotype.
In this review, the authors discuss the applicability of precision oncology in HCC targeting the WNT/B-catenin pathway by inhibiting the interaction with transcriptional coactivators of B-catenin such as CBP and TCF or by enhancing the proteasomal degradation of B-catenin, reducing pathway activation, with drugs like Tankyrase inhibitors and casein kinase 1a activators. These approaches are challenging due to its associated off-target toxicity and its complexity. To overcome these caveats, the author propose to utilization of nanotechnology to deliver Wnt inhibitors, an approach that currently requires further research to refine the most promising strategies and drugs suitable for clinical implementation.
Josep M. Llovet, MD, PhD, FAASLD, director, Mount Sinai Liver Cancer Program in New York, and head of translational research in the Liver Cancer Group, Liver Unit, IDIBAPS, Hospital Clínic Barcelona. Dr. Llovet receives research support from Bayer Pharmaceuticals, Eisai Inc, Bristol-Myers Squibb and Ipsen.
Hepatocellular Carcinoma (HCC) remains a major health problem associate with increasing prevalence and mortality rates worldwide. Around 50-60% of HCC patients are exposed to systemic therapies during their natural history. Atezolizumab plus bevacizumab (median OS: 19.2mo, ORR 30%), and durvalumab plus tremelimumab (median OS: 16.4mo, ORR: 20%) are considered first line treatment options for advanced HCC, and sorafenib or lenvatinib are recommended for patients with any contraindication for immune checkpoint inhibitors. These therapies are indicated for ‘all comers’ an no molecular markers /personalize medicine is currently available for this cancer. The lack of precision oncology relates to the fact that the most common mutations ( i.e TERT, TP53,CTNNB1) are unactionable targets. In this scenario, advances in precision oncology are an unmet medical need.
The Wnt/B-catenin signaling pathway is a master regulator of oncogenesis in HCC and defines one of the molecular subclasses characterized by CTNNB1 mutations (~25-30%) or AXIN1 mutations (~5-10%). Most of these tumors have an immune excluded/desert phenotype. Thus, targeting this pathway is expected to provide a primary antitumoral effect along with an immune-modulatory effect rescuing cases with an immune excluded phenotype.
In this review, the authors discuss the applicability of precision oncology in HCC targeting the WNT/B-catenin pathway by inhibiting the interaction with transcriptional coactivators of B-catenin such as CBP and TCF or by enhancing the proteasomal degradation of B-catenin, reducing pathway activation, with drugs like Tankyrase inhibitors and casein kinase 1a activators. These approaches are challenging due to its associated off-target toxicity and its complexity. To overcome these caveats, the author propose to utilization of nanotechnology to deliver Wnt inhibitors, an approach that currently requires further research to refine the most promising strategies and drugs suitable for clinical implementation.
Josep M. Llovet, MD, PhD, FAASLD, director, Mount Sinai Liver Cancer Program in New York, and head of translational research in the Liver Cancer Group, Liver Unit, IDIBAPS, Hospital Clínic Barcelona. Dr. Llovet receives research support from Bayer Pharmaceuticals, Eisai Inc, Bristol-Myers Squibb and Ipsen.
Hepatocellular Carcinoma (HCC) remains a major health problem associate with increasing prevalence and mortality rates worldwide. Around 50-60% of HCC patients are exposed to systemic therapies during their natural history. Atezolizumab plus bevacizumab (median OS: 19.2mo, ORR 30%), and durvalumab plus tremelimumab (median OS: 16.4mo, ORR: 20%) are considered first line treatment options for advanced HCC, and sorafenib or lenvatinib are recommended for patients with any contraindication for immune checkpoint inhibitors. These therapies are indicated for ‘all comers’ an no molecular markers /personalize medicine is currently available for this cancer. The lack of precision oncology relates to the fact that the most common mutations ( i.e TERT, TP53,CTNNB1) are unactionable targets. In this scenario, advances in precision oncology are an unmet medical need.
The Wnt/B-catenin signaling pathway is a master regulator of oncogenesis in HCC and defines one of the molecular subclasses characterized by CTNNB1 mutations (~25-30%) or AXIN1 mutations (~5-10%). Most of these tumors have an immune excluded/desert phenotype. Thus, targeting this pathway is expected to provide a primary antitumoral effect along with an immune-modulatory effect rescuing cases with an immune excluded phenotype.
In this review, the authors discuss the applicability of precision oncology in HCC targeting the WNT/B-catenin pathway by inhibiting the interaction with transcriptional coactivators of B-catenin such as CBP and TCF or by enhancing the proteasomal degradation of B-catenin, reducing pathway activation, with drugs like Tankyrase inhibitors and casein kinase 1a activators. These approaches are challenging due to its associated off-target toxicity and its complexity. To overcome these caveats, the author propose to utilization of nanotechnology to deliver Wnt inhibitors, an approach that currently requires further research to refine the most promising strategies and drugs suitable for clinical implementation.
Josep M. Llovet, MD, PhD, FAASLD, director, Mount Sinai Liver Cancer Program in New York, and head of translational research in the Liver Cancer Group, Liver Unit, IDIBAPS, Hospital Clínic Barcelona. Dr. Llovet receives research support from Bayer Pharmaceuticals, Eisai Inc, Bristol-Myers Squibb and Ipsen.
leading to safer treatment and better outcomes, according to a recent review.
Nanomedicines homing in on the Wnt/beta-catenin signaling pathway could be particularly impactful, Mamatha Bhat, MD, PhD, a hepatologist and clinician-scientist at Toronto General Hospital Research Institute, and colleagues reported, as this is one of the most up-regulated pathways in HCC.
To date, however, agents addressing this pathway have been hindered by off-target toxicity, suggesting that more work is needed to develop the right payload for nanoparticle delivery, the investigators wrote in Gastro Hep Advances.
“Although nanotherapeutics offers an unmatched improvement in drug delivery, due to the limited impact and treatment-resistance demonstrated by the current systemic therapies, there is currently no approved nanomedicine for the treatment of HCC,” the investigators wrote. “Therefore, it is of utmost importance to dig deeper into understanding the signaling pathways that govern hepatocarcinogenesis and identify novel targets that can be used to develop more specific and targeted nanotherapies.”
Their review focused on the Wnt/beta-catenin signaling pathway, but first, Dr. Bhat and colleagues discussed the characteristics of inorganic versus lipid nanoparticles, as these differences can determine liver uptake.
Inorganic nanoparticles have a high surface-to-volume ratio, leading to increased surface charges that enhance cellular uptake. However, they are prone to oxidation, requiring surface modifications or short circulation times to prevent degradation. These nanoparticles are limited in delivering chemotherapeutic drugs and peptides, and are not suitable for encapsulating nucleic acids.
In contrast, lipid nanoparticles are preferred for targeted delivery in HCC, according to the investigators. They have a natural affinity for apolipoprotein E (apo E), resembling lipoproteins, which aids in specific liver cell targeting. When lipid nanoparticles enter the bloodstream, they interact with apo E–rich lipoproteins like HDL cholesterol and LDL cholesterol, leading to formation of complexes recognized by LDL cholesterol receptors on liver cells. This triggers receptor-mediated endocytosis, internalizing apo E–lipid nanoparticle complexes into HCC cells.
The other major variable is the selected treatment target. Dr. Bhat and colleagues made the case for the Wnt/beta-catenin signaling pathway based on alterations found in approximately two-thirds of patients with HCC.
“Aberrant activation of this pathway and mutations in genes encoding key components are characteristic to hepatocarcinogenesis and promote tumor growth and dedifferentiation,” they wrote.
Although beta-catenin itself makes for an obvious molecular target, especially considering known associations with drug resistance, its flat structure lacks deep binding pockets that would be suitable for small-molecule inhibitors, and any available pockets may be altered by numerous posttranscriptional modifications. Instead, beta-catenin could be indirectly modulated by nanoparticle-mediated siRNA therapy, as this would allow for precise delivery of siRNA to cancer cells, minimizing off-target toxicity.
Alternative approaches could involve targeting proteasomal degradation of beta-catenin, transcriptional coactivators of beta-catenin, or different oncogenes in HCC, all of which are described in further detail in the review, along with promising preclinical findings.
“With ongoing advancements in nanotechnology, there is optimism that it will continue to play a vital role in overcoming the challenges associated with HCC management and contribute to further advancements in therapeutic outcomes for patients,” the authors concluded.
One coauthor disclosed external funding by a Mitacs Elevate postdoctoral fellowship in collaboration with Highland Therapeutics. The remaining authors disclosed no conflicts of interest.
leading to safer treatment and better outcomes, according to a recent review.
Nanomedicines homing in on the Wnt/beta-catenin signaling pathway could be particularly impactful, Mamatha Bhat, MD, PhD, a hepatologist and clinician-scientist at Toronto General Hospital Research Institute, and colleagues reported, as this is one of the most up-regulated pathways in HCC.
To date, however, agents addressing this pathway have been hindered by off-target toxicity, suggesting that more work is needed to develop the right payload for nanoparticle delivery, the investigators wrote in Gastro Hep Advances.
“Although nanotherapeutics offers an unmatched improvement in drug delivery, due to the limited impact and treatment-resistance demonstrated by the current systemic therapies, there is currently no approved nanomedicine for the treatment of HCC,” the investigators wrote. “Therefore, it is of utmost importance to dig deeper into understanding the signaling pathways that govern hepatocarcinogenesis and identify novel targets that can be used to develop more specific and targeted nanotherapies.”
Their review focused on the Wnt/beta-catenin signaling pathway, but first, Dr. Bhat and colleagues discussed the characteristics of inorganic versus lipid nanoparticles, as these differences can determine liver uptake.
Inorganic nanoparticles have a high surface-to-volume ratio, leading to increased surface charges that enhance cellular uptake. However, they are prone to oxidation, requiring surface modifications or short circulation times to prevent degradation. These nanoparticles are limited in delivering chemotherapeutic drugs and peptides, and are not suitable for encapsulating nucleic acids.
In contrast, lipid nanoparticles are preferred for targeted delivery in HCC, according to the investigators. They have a natural affinity for apolipoprotein E (apo E), resembling lipoproteins, which aids in specific liver cell targeting. When lipid nanoparticles enter the bloodstream, they interact with apo E–rich lipoproteins like HDL cholesterol and LDL cholesterol, leading to formation of complexes recognized by LDL cholesterol receptors on liver cells. This triggers receptor-mediated endocytosis, internalizing apo E–lipid nanoparticle complexes into HCC cells.
The other major variable is the selected treatment target. Dr. Bhat and colleagues made the case for the Wnt/beta-catenin signaling pathway based on alterations found in approximately two-thirds of patients with HCC.
“Aberrant activation of this pathway and mutations in genes encoding key components are characteristic to hepatocarcinogenesis and promote tumor growth and dedifferentiation,” they wrote.
Although beta-catenin itself makes for an obvious molecular target, especially considering known associations with drug resistance, its flat structure lacks deep binding pockets that would be suitable for small-molecule inhibitors, and any available pockets may be altered by numerous posttranscriptional modifications. Instead, beta-catenin could be indirectly modulated by nanoparticle-mediated siRNA therapy, as this would allow for precise delivery of siRNA to cancer cells, minimizing off-target toxicity.
Alternative approaches could involve targeting proteasomal degradation of beta-catenin, transcriptional coactivators of beta-catenin, or different oncogenes in HCC, all of which are described in further detail in the review, along with promising preclinical findings.
“With ongoing advancements in nanotechnology, there is optimism that it will continue to play a vital role in overcoming the challenges associated with HCC management and contribute to further advancements in therapeutic outcomes for patients,” the authors concluded.
One coauthor disclosed external funding by a Mitacs Elevate postdoctoral fellowship in collaboration with Highland Therapeutics. The remaining authors disclosed no conflicts of interest.
FROM GASTRO HEP ADVANCES