Expanded genetic score improves risk prediction for type 2 diabetes

Use of an expanded genetic score in conjunction with the Framingham risk score improved risk prediction for type 2 diabetes, according to findings recently published in the journal Diabetes.

In an analysis of seven cohorts of European patients, a 65-SNP (single nucleotide polymorphism) genetic score alone detected 19.9% of incident cases with a 10% false-positive rate, compared with the Framingham risk model, which detected 30.7% (95% confidence interval, 27.5-33.8) of cases.

When combined, the two measures detected 37.3% (95% CI, 33.9-40.6) of cases, reported Dr. Philippa J. Talmud of the Centre for Cardiovascular Genetics at the Institute of Cardiovascular Science, University College London, and her associates.

The addition of a 65-SNP gene score improved correct classification of patients into higher risk disease categories by 6.2%.

Of the 13,294 patients included in the study, 804 developed type 2 diabetes during the study period. Patients were classified as having type 2 diabetes according to self-report, medical record review, prescription of glucose-lowering drugs, or a recorded fasting glucose of 7 mmol/L or greater, the authors said.

Genotyping was performed using MetaboChip array, which includes nearly 200,000 SNP loci for cardiometabolic disease and their genetic variants.

Area under the curve values for genetic score, Framingham risk model, and combined score were 0.60 (95% CI, 0.58-0.62), 0.75 (95% CI, 0.73-0.77), and 0.76 (95% CI, 0.75-0.78), respectively. The combined risk score net reclassification improvement (NRI) was 8.1% (P = 3.31 × 10^–7), the investigators reported (Diabetes 2015;64:1830-40).

The findings suggest that common variants of small effects in combination may help improve risk prediction for type 2 diabetes, Dr. Talmud and her coauthors said.

“For a gene score to be effective, it should improve the reclassification of individuals with [type 2 diabetes] into a more accurate risk category over and above the phenotypic risk score. The 65 SNP–weighted gene score did this,” they said.

“In actual terms, at a 10% [false-positive rate], the combined phenotypic and genetic risk score led to the correct identification of an additional 53 (6.6%) of the 804 cases,” they added.

This slight improvement demonstrates that the addition of a gene score to a phenotyping risk model could be a “potentially clinically important improvement” in disease discrimination and classification, Dr. Talmud and her associates concluded.

The study authors reported several sources of funding, including the British Heart Foundation, the Stroke Association, the National Heart, Lung, and Blood Institute, and others.

mrajaraman@frontlinemedcom.com

Use of an expanded genetic score in conjunction with the Framingham risk score improved risk prediction for type 2 diabetes, according to findings recently published in the journal Diabetes.

In an analysis of seven cohorts of European patients, a 65-SNP (single nucleotide polymorphism) genetic score alone detected 19.9% of incident cases with a 10% false-positive rate, compared with the Framingham risk model, which detected 30.7% (95% confidence interval, 27.5-33.8) of cases.

When combined, the two measures detected 37.3% (95% CI, 33.9-40.6) of cases, reported Dr. Philippa J. Talmud of the Centre for Cardiovascular Genetics at the Institute of Cardiovascular Science, University College London, and her associates.

The addition of a 65-SNP gene score improved correct classification of patients into higher risk disease categories by 6.2%.

Of the 13,294 patients included in the study, 804 developed type 2 diabetes during the study period. Patients were classified as having type 2 diabetes according to self-report, medical record review, prescription of glucose-lowering drugs, or a recorded fasting glucose of 7 mmol/L or greater, the authors said.

Genotyping was performed using MetaboChip array, which includes nearly 200,000 SNP loci for cardiometabolic disease and their genetic variants.

Area under the curve values for genetic score, Framingham risk model, and combined score were 0.60 (95% CI, 0.58-0.62), 0.75 (95% CI, 0.73-0.77), and 0.76 (95% CI, 0.75-0.78), respectively. The combined risk score net reclassification improvement (NRI) was 8.1% (P = 3.31 × 10^–7), the investigators reported (Diabetes 2015;64:1830-40).

The findings suggest that common variants of small effects in combination may help improve risk prediction for type 2 diabetes, Dr. Talmud and her coauthors said.

“For a gene score to be effective, it should improve the reclassification of individuals with [type 2 diabetes] into a more accurate risk category over and above the phenotypic risk score. The 65 SNP–weighted gene score did this,” they said.

“In actual terms, at a 10% [false-positive rate], the combined phenotypic and genetic risk score led to the correct identification of an additional 53 (6.6%) of the 804 cases,” they added.

This slight improvement demonstrates that the addition of a gene score to a phenotyping risk model could be a “potentially clinically important improvement” in disease discrimination and classification, Dr. Talmud and her associates concluded.

The study authors reported several sources of funding, including the British Heart Foundation, the Stroke Association, the National Heart, Lung, and Blood Institute, and others.

mrajaraman@frontlinemedcom.com

Use of an expanded genetic score in conjunction with the Framingham risk score improved risk prediction for type 2 diabetes, according to findings recently published in the journal Diabetes.

In an analysis of seven cohorts of European patients, a 65-SNP (single nucleotide polymorphism) genetic score alone detected 19.9% of incident cases with a 10% false-positive rate, compared with the Framingham risk model, which detected 30.7% (95% confidence interval, 27.5-33.8) of cases.

When combined, the two measures detected 37.3% (95% CI, 33.9-40.6) of cases, reported Dr. Philippa J. Talmud of the Centre for Cardiovascular Genetics at the Institute of Cardiovascular Science, University College London, and her associates.

The addition of a 65-SNP gene score improved correct classification of patients into higher risk disease categories by 6.2%.

Of the 13,294 patients included in the study, 804 developed type 2 diabetes during the study period. Patients were classified as having type 2 diabetes according to self-report, medical record review, prescription of glucose-lowering drugs, or a recorded fasting glucose of 7 mmol/L or greater, the authors said.

Genotyping was performed using MetaboChip array, which includes nearly 200,000 SNP loci for cardiometabolic disease and their genetic variants.

Area under the curve values for genetic score, Framingham risk model, and combined score were 0.60 (95% CI, 0.58-0.62), 0.75 (95% CI, 0.73-0.77), and 0.76 (95% CI, 0.75-0.78), respectively. The combined risk score net reclassification improvement (NRI) was 8.1% (P = 3.31 × 10^–7), the investigators reported (Diabetes 2015;64:1830-40).

The findings suggest that common variants of small effects in combination may help improve risk prediction for type 2 diabetes, Dr. Talmud and her coauthors said.

“For a gene score to be effective, it should improve the reclassification of individuals with [type 2 diabetes] into a more accurate risk category over and above the phenotypic risk score. The 65 SNP–weighted gene score did this,” they said.

“In actual terms, at a 10% [false-positive rate], the combined phenotypic and genetic risk score led to the correct identification of an additional 53 (6.6%) of the 804 cases,” they added.

This slight improvement demonstrates that the addition of a gene score to a phenotyping risk model could be a “potentially clinically important improvement” in disease discrimination and classification, Dr. Talmud and her associates concluded.

The study authors reported several sources of funding, including the British Heart Foundation, the Stroke Association, the National Heart, Lung, and Blood Institute, and others.

mrajaraman@frontlinemedcom.com