Your search keyword '"Michal Cohen-Shelly"' showing total 13 results

1. Leveraging Large Language Models to Enhance Digital Health in Cardiology: A Preview of a Cutting-Edge Language Generation Model

Author

Eyal Klang, MD, Michal Cohen-Shelly, BSc, and Francisco Lopez-Jimenez, MD, MSc, MBA

Subjects

Computer applications to medicine. Medical informatics, R858-859.7

Published

2023

2. Electrocardiogram-Artificial Intelligence and Immune-Mediated Necrotizing Myopathy: Predicting Left Ventricular Dysfunction and Clinical Outcomes

Author

Christopher J. Klein, MD, Ilke Ozcan, MD, Zachi I. Attia, PhD, Michal Cohen-Shelly, MS, Amir Lerman, MD, Jose R. Medina-Inojosa, MD, MS, Francisco Lopez-Jimenez, MD, Paul A. Friedman, MD, Margherita Milone, MD, PhD, and Shahar Shelly, MD

Subjects

Medicine (General), R5-920

Abstract

Objective: To characterize the utility of an existing electrocardiogram (ECG)-artificial intelligence (AI) algorithm of left ventricular dysfunction (LVD) in immune-mediated necrotizing myopathy (IMNM). Patients and Methods: A retrospective cohort observational study was conducted within our tertiary-care neuromuscular clinic for patients with IMNM meeting European Neuromuscular Centre diagnostic criteria (January 1, 2000, to December 31, 2020). A validated AI algorithm using 12-lead standard ECGs to detect LVD was applied. The output was presented as a percent probability of LVD. Electrocardiograms before and while on immunotherapy were reviewed. The LVD-predicted probability scores were compared with echocardiograms, immunotherapy treatment response, and mortality. Results: The ECG-AI algorithm had acceptable accuracy in LVD prediction in 74% (68 of 89) of patients with IMNM with available echocardiograms (discrimination threshold, 0.74; 95% CI, 0.6-0.87). This translates into a sensitivity of 80.0% and specificity of 62.8% to detect LVD. Best cutoff probability prediction was 7 times more likely to have LVD (odds ratio, 6.75; 95% CI, 2.11-21.51; P=.001). Early detection occurred in 18% (16 of 89) of patients who initially had normal echocardiograms and were without cardiorespiratory symptoms, of which 6 subsequently advanced to LVD cardiorespiratory failure. The LVD probability scores improved for patients on immunotherapy (median slope, −3.96; R = −0.12; P=.002). Mortality risk was 7 times greater with abnormal LVD probability scores (hazard ratio, 7.33; 95% CI, 1.63-32.88; P=.009). Conclusion: In IMNM, an AI-ECG algorithm assists detection of LVD, enhancing the decision to advance to echocardiogram testing, while also informing on mortality risk, which is important in the decision of immunotherapy escalation and monitoring.

Published

2022

3. Vascular Aging Detected by Peripheral Endothelial Dysfunction Is Associated With ECG‐Derived Physiological Aging

Author

Takumi Toya, Ali Ahmad, Zachi Attia, Michal Cohen‐Shelly, Ilke Ozcan, Peter A Noseworthy, Francisco Lopez‐Jimenez, Suraj Kapa, Lilach O Lerman, Paul A Friedman, and Amir Lerman

Subjects

artificial intelligence, peripheral microvascular endothelial dysfunction, physiological age, reactive hyperemia peripheral arterial tonometry index, vascular age, Diseases of the circulatory (Cardiovascular) system, RC666-701

Abstract

Background An artificial intelligence algorithm that detects age using the 12‐lead ECG has been suggested to signal “physiologic age.” This study aimed to investigate the association of peripheral microvascular endothelial function (PMEF) as an index of vascular aging, with accelerated physiologic aging gauged by ECG‐derived artificial intelligence–estimated age. Methods and Results This study included 531 patients who underwent ECG and a noninvasive PMEF assessment using reactive hyperemia peripheral arterial tonometry. Abnormal PMEF was defined as reactive hyperemia peripheral arterial tonometry index ≤2.0. Accelerated or delayed physiologic aging was calculated by the Δ age (ECG‐derived artificial intelligence–estimated age minus chronological age), and the association between Δ age and PMEF as well as its impact on composite major adverse cardiovascular events were investigated. Δ age was higher in patients with abnormal PMEF than in patients with normal PMEF (2.3±7.8 versus 0.5±7.7 years; P=0.01). Reactive hyperemia peripheral arterial tonometry index was negatively associated with Δ age after adjustment for cardiovascular risk factors (standardized β coefficient, –0.08; P=0.048). The highest quartile of Δ age was associated with an increased risk of major adverse cardiovascular events compared with the first quartile of Δ age in patients with abnormal PMEF, even after adjustment for cardiovascular risk factors (hazard ratio, 4.72; 95% CI, 1.24–17.91; P=0.02). Conclusions Vascular aging detected by endothelial function is associated with accelerated physiologic aging, as assessed by the artificial intelligence–ECG Δ age. Patients with endothelial dysfunction and the highest quartile of accelerated physiologic aging have a marked increase in risk for cardiovascular events.

Published

2021

4. Accelerated Aging in LMNA Mutations Detected by Artificial Intelligence ECG–Derived Age

Author

Shahar Shelly, Francisco Lopez-Jimenez, Audry Chacin-Suarez, Michal Cohen-Shelly, Jose R. Medina-Inojosa, Suraj Kapa, Zachi Attia, Anwar A. Chahal, Virend K. Somers, Paul A. Friedman, and Margherita Milone

Subjects

General Medicine

Published

2023

5. Artificial intelligence–derived cardiac ageing is associated with cardiac events post-heart transplantation

Author

Ilke Ozcan, Takumi Toya, Michal Cohen-Shelly, Hyun Woong Park, Ali Ahmad, Alp Ozcan, Peter A Noseworthy, Suraj Kapa, Lilach O Lerman, Zachi I Attia, Sudhir S Kushwaha, Paul A Friedman, and Amir Lerman

Subjects

General Engineering, General Earth and Planetary Sciences, General Environmental Science

Abstract

AimsAn artificial intelligence algorithm detecting age from 12-lead electrocardiogram (ECG) has been suggested to reflect ‘physiological age’. An increased physiological age has been associated with a higher risk of cardiac mortality in the non-transplant population. We aimed to investigate the utility of this algorithm in patients who underwent heart transplantation (HTx).Methods and resultsA total of 540 patients were studied. The average ECG ages within 1 year before and after HTx were used to represent pre- and post-HTx ECG ages. Major adverse cardiovascular event (MACE) was defined as any coronary revascularization, heart failure hospitalization, re-transplantation, and mortality. Recipient pre-transplant ECG age (mean 63 ± 11 years) correlated significantly with recipient chronological age (mean 49 ± 14 years, R = 0.63, P < 0.0001), while post-transplant ECG age (mean 54 ± 10 years) correlated with both the donor (mean 32 ± 13 years, R = 0.45, P < 0.0001) and the recipient ages (R = 0.38, P < 0.0001). During a median follow-up of 8.8 years, 307 patients experienced MACE. Patients with an increase in ECG age post-transplant showed an increased risk of MACE [hazard ratio (HR): 1.58, 95% confidence interval (CI): (1.24, 2.01), P = 0.0002], even after adjusting for potential confounders [HR: 1.58, 95% CI: (1.19, 2.10), P = 0.002].ConclusionElectrocardiogram age-derived cardiac ageing after transplantation is associated with a higher risk of MACE. This study suggests that physiological age change of the heart might be an important determinant of MACE risk post-HTx.

Published

2022

6. Real-world performance, long-term efficacy, and absence of bias in the artificial intelligence enhanced electrocardiogram to detect left ventricular systolic dysfunction

Author

David M Harmon, Rickey E Carter, Michal Cohen-Shelly, Anna Svatikova, Demilade A Adedinsewo, Peter A Noseworthy, Suraj Kapa, Francisco Lopez-Jimenez, Paul A Friedman, and Zachi I Attia

Abstract

Aims Some artificial intelligence models applied in medical practice require ongoing retraining, introduce unintended racial bias, or have variable performance among different subgroups of patients. We assessed the real-world performance of the artificial intelligence-enhanced electrocardiogram to detect left ventricular systolic dysfunction with respect to multiple patient and electrocardiogram variables to determine the algorithm’s long-term efficacy and potential bias in the absence of retraining. Methods and results Electrocardiograms acquired in 2019 at Mayo Clinic in Minnesota, Arizona, and Florida with an echocardiogram performed within 14 days were analyzed (n = 44 986 unique patients). The area under the curve (AUC) was calculated to evaluate performance of the algorithm among age groups, racial and ethnic groups, patient encounter location, electrocardiogram features, and over time. The artificial intelligence-enhanced electrocardiogram to detect left ventricular systolic dysfunction had an AUC of 0.903 for the total cohort. Time series analysis of the model validated its temporal stability. Areas under the curve were similar for all racial and ethnic groups (0.90–0.92) with minimal performance difference between sexes. Patients with a ‘normal sinus rhythm’ electrocardiogram (n = 37 047) exhibited an AUC of 0.91. All other electrocardiogram features had areas under the curve between 0.79 and 0.91, with the lowest performance occurring in the left bundle branch block group (0.79). Conclusion The artificial intelligence-enhanced electrocardiogram to detect left ventricular systolic dysfunction is stable over time in the absence of retraining and robust with respect to multiple variables including time, patient race, and electrocardiogram features.

Published

2022

7. Artificial Intelligence–Enhanced Electrocardiogram for the Early Detection of Cardiac Amyloidosis

Author

Grace Lin, Suraj Kapa, Dennis H. Murphree, Angela Dispenzieri, Paul A. Friedman, Francisco Lopez-Jimenez, Michal Cohen-Shelly, Zachi I. Attia, Omar F. Abou Ezzedine, Daniel D. Borgeson, and Martha Grogan

Subjects

Male, Youden's J statistic, Early detection, Left ventricular hypertrophy, Time-to-Treatment, Electrocardiography, Text mining, Artificial Intelligence, Predictive Value of Tests, medicine, Humans, Cutoff, Internal validation, Retrospective Studies, Amyloid Neuropathies, Familial, Receiver operating characteristic, business.industry, General Medicine, Middle Aged, medicine.disease, United States, Early Diagnosis, Cardiac amyloidosis, Area Under Curve, Female, Neural Networks, Computer, Artificial intelligence, Cardiomyopathies, business

Abstract

Objective To develop an artificial intelligence (AI)–based tool to detect cardiac amyloidosis (CA) from a standard 12-lead electrocardiogram (ECG). Methods We collected 12-lead ECG data from 2541 patients with light chain or transthyretin CA seen at Mayo Clinic between 2000 and 2019. Cases were nearest neighbor matched for age and sex, with 2454 controls. A subset of 2997 (60%) cases and controls were used to train a deep neural network to predict the presence of CA with an internal validation set (n=999; 20%) and a randomly selected holdout testing set (n=999; 20%). We performed experiments using single-lead and 6-lead ECG subsets. Results The area under the receiver operating characteristic curve (AUC) was 0.91 (CI, 0.90 to 0.93), with a positive predictive value for detecting either type of CA of 0.86. By use of a cutoff probability of 0.485 determined by the Youden index, 426 (84%) of the holdout patients with CA were detected by the model. Of the patients with CA and prediagnosis electrocardiographic studies, the AI model successfully predicted the presence of CA more than 6 months before the clinical diagnosis in 59%. The best single-lead model was V5 with an AUC of 0.86 and a precision of 0.78, with other single leads performing similarly. The 6-lead (bipolar leads) model had an AUC of 0.90 and a precision of 0.85. Conclusion An AI-driven ECG model effectively detects CA and may promote early diagnosis of this life-threatening disease.

Published

2021

8. Detection of hypertrophic cardiomyopathy by an artificial intelligence electrocardiogram in children and adolescents

Author

Zachi I. Attia, Michael J. Ackerman, Paul A. Friedman, Nasibeh Zanjirani Farahani, Kan Liu, Konstantinos C. Siontis, Michal Cohen-Shelly, Adelaide M. Arruda-Olson, J. Martijn Bos, and Peter A. Noseworthy

Subjects

Adult, Male, Adolescent, macromolecular substances, Electrocardiography, Artificial Intelligence, Positive predicative value, Humans, Mass Screening, Medicine, cardiovascular diseases, Child, Receiver operating characteristic, business.industry, Hypertrophic cardiomyopathy, Mean age, Cardiomyopathy, Hypertrophic, medicine.disease, Echocardiography, Child, Preschool, Cohort, cardiovascular system, Female, Artificial intelligence, Cardiology and Cardiovascular Medicine, business

Abstract

There is no established screening approach for hypertrophic cardiomyopathy (HCM). We recently developed an artificial intelligence (AI) model for the detection of HCM based on the 12‑lead electrocardiogram (AI-ECG) in adults. Here, we aimed to validate this approach of ECG-based HCM detection in pediatric patients (age ≤ 18 years).We identified a cohort of 300 children and adolescents with HCM (mean age 12.5 ± 4.6 years, male 68%) who had an ECG and echocardiogram at our institution. Patients were age- and sex-matched to 18,439 non-HCM controls. Diagnostic performance of the AI-ECG model for the detection of HCM was estimated using the previously identified optimal diagnostic threshold of 11% (the probability output derived by the model above which an ECG is considered to belong to an HCM patient).Mean AI-ECG probabilities of HCM were 92% and 5% in the case and control groups, respectively. The area under the receiver operating characteristic curve (AUC) of the AI-ECG model for HCM detection was 0.98 (95% CI 0.98-0.99) with corresponding sensitivity 92% and specificity 95%. The positive and negative predictive values were 22% and 99%, respectively. The model performed similarly in males and females and in genotype-positive and genotype-negative HCM patients. Performance tended to be superior with increasing age. In the age subgroup5 years, the test's AUC was 0.93. In comparison, the AUC was 0.99 in the age subgroup 15-18 years.A deep-learning, AI model can detect pediatric HCM with high accuracy from the standard 12‑lead ECG.

Published

2021

9. Artificial Intelligence-Enabled Electrocardiography to Screen Patients with Dilated Cardiomyopathy

Author

Margaret M. Redfield, Francisco Lopez-Jimenez, Liwei Wang, Grace Lin, Michal Cohen-Shelly, Sanskriti Shrivastava, Paul A. Friedman, Andrew N. Rosenbaum, Suraj Kapa, Naveen L. Pereira, Zachi I. Attia, Kent R. Bailey, and John R. Giudicessi

Subjects

Cardiomyopathy, Dilated, Male, medicine.medical_specialty, Cardiomyopathy, Asymptomatic, Ventricular Function, Left, Sudden cardiac death, Electrocardiography, Artificial Intelligence, Internal medicine, Humans, Mass Screening, Medicine, cardiovascular diseases, Ejection fraction, medicine.diagnostic_test, business.industry, Area under the curve, Reproducibility of Results, Dilated cardiomyopathy, Middle Aged, medicine.disease, Echocardiography, Cohort, Cardiology, Female, medicine.symptom, Cardiology and Cardiovascular Medicine, business, Algorithms

Abstract

Undiagnosed dilated cardiomyopathy (DC) can be asymptomatic or present as sudden cardiac death, therefore pre-emptively identifying and treating patients may be beneficial. Screening for DC with echocardiography is expensive and labor intensive and standard electrocardiography (ECG) is insensitive and non-specific. The performance and applicability of artificial intelligence-enabled electrocardiography (AI-ECG) for detection of DC is unknown. Diagnostic performance of an AI algorithm in determining reduced left ventricular ejection fraction (LVEF) was evaluated in a cohort that comprised of DC and normal LVEF control patients. DC patients and controls with 12-lead ECGs and a reference LVEF measured by echocardiography performed within 30 and 180 days of the ECG respectively were enrolled. The model was tested for its sensitivity, specificity, negative predictive (NPV) and positive predictive values (PPV) based on the prevalence of DC at 1% and 5%. The cohort consisted of 421 DC cases (60% males, 57±15 years, LVEF 28±11%) and 16,025 controls (49% males, age 69 ±16 years, LVEF 62±5%). For detection of LVEF≤45%, the area under the curve (AUC) was 0.955 with a sensitivity of 98.8% and specificity 44.8%. The NPV and PPV were 100% and 1.8% at a DC prevalence of 1% and 99.9% and 8.6% at a prevalence of 5%, respectively. In conclusion AI-ECG demonstrated high sensitivity and negative predictive value for detection of DC and could be used as a simple and cost-effective screening tool with implications for screening first degree relatives of DC patients.

Published

2021

10. Silent Progression Of Calcific Aortic Stenosis Detected By Artificial Intelligence Electrocardiogram: A Case Report

Author

Rick A. Nishimura, MD, Paul Friedman, Saki Ito, MD, Jae K. Oh, Atzhak Zachi Attia, Michal Cohen-Shelly, BSc, Awais Malik, MD, and David Harmon

Published

2022

11. Artificial intelligence derived age algorithm after heart transplantation

Author

Ilke Ozcan, Peter A. Noseworthy, Amir Lerman, Ali Ahmad, Michal Cohen-Shelly, L O Lerman, Takumi Toya, Paul A. Friedman, Zachi I. Attia, Suraj Kapa, Sudhir S. Kushwaha, and Michel T. Corban

Subjects

Heart transplantation, business.industry, medicine.medical_treatment, medicine, cardiovascular diseases, Artificial intelligence, Cardiology and Cardiovascular Medicine, business

Abstract

Background An artificial intelligence (AI) algorithm detecting age from 12-lead ECG has been suggested to signal “physiological age” of the individual. Importantly, increased physiological age gauged by an increased difference between ECG-age and chronological age has been associated with higher risk of cardiac events in non-transplant population. Purpose We sought to investigate the validity of the AI-derived ECG-age algorithm in patients who underwent heart transplantation and its relationship to major adverse cardiovascular events (MACE). Methods A total of 489 consecutive patients who had undergone heart transplantation in our institution between 1994 and 2018 were studied. AI-ECG age was calculated by a previously-trained artificial intelligence (AI) algorithm using a 12-lead ECG per patient. ECGs used in the training process of the algorithm were excluded. The average of the ECG-ages within one year before and one year after heart transplantation was used to represent pre- and post-transplant ECG-ages. MACE was defined as any incidence of revascularization, re-transplantation, and death. Results Pre-transplant ECG-age (mean 63±10 years) correlated significantly with recipient chronological age (mean 50±13 years, r=0.57, p Conclusion Post-transplant ECG-age correlates more faithfully with the donor's than the recipient's chronological age, suggesting that ECG-age more closely reflects cardiac age than the patient age. Furthermore, ECG-age derived cardiac aging after transplantation is associated with higher risk of MACE. Funding Acknowledgement Type of funding sources: None.

Published

2021

12. Vascular Aging Detected by Peripheral Endothelial Dysfunction Is Associated With ECG‐Derived Physiological Aging

Author

Francisco Lopez-Jimenez, Paul A. Friedman, Peter A. Noseworthy, Takumi Toya, Amir Lerman, Ilke Ozcan, Suraj Kapa, Lilach O. Lerman, Michal Cohen-Shelly, Zachi I. Attia, and Ali Ahmad

Subjects

Male, Aging, medicine.medical_specialty, 030204 cardiovascular system & hematology, Electrocardiography, Peripheral Arterial Disease, 03 medical and health sciences, 0302 clinical medicine, vascular age, Risk Factors, Internal medicine, reactive hyperemia peripheral arterial tonometry index, medicine, Humans, Preventive Cardiology, Endothelial dysfunction, Original Research, Retrospective Studies, 030304 developmental biology, physiological age, 0303 health sciences, business.industry, peripheral microvascular endothelial dysfunction, Arteries, Middle Aged, artificial intelligence, medicine.disease, Peripheral, Vasodilation, Cross-Sectional Studies, Physiological Aging, Microvessels, Cardiology, Female, Vascular aging, Endothelium, Vascular, Cardiology and Cardiovascular Medicine, business, Follow-Up Studies

Abstract

Background An artificial intelligence algorithm that detects age using the 12‐lead ECG has been suggested to signal “physiologic age.” This study aimed to investigate the association of peripheral microvascular endothelial function (PMEF) as an index of vascular aging, with accelerated physiologic aging gauged by ECG‐derived artificial intelligence–estimated age. Methods and Results This study included 531 patients who underwent ECG and a noninvasive PMEF assessment using reactive hyperemia peripheral arterial tonometry. Abnormal PMEF was defined as reactive hyperemia peripheral arterial tonometry index ≤2.0. Accelerated or delayed physiologic aging was calculated by the Δ age (ECG‐derived artificial intelligence–estimated age minus chronological age), and the association between Δ age and PMEF as well as its impact on composite major adverse cardiovascular events were investigated. Δ age was higher in patients with abnormal PMEF than in patients with normal PMEF (2.3±7.8 versus 0.5±7.7 years; P =0.01). Reactive hyperemia peripheral arterial tonometry index was negatively associated with Δ age after adjustment for cardiovascular risk factors (standardized β coefficient, –0.08; P =0.048). The highest quartile of Δ age was associated with an increased risk of major adverse cardiovascular events compared with the first quartile of Δ age in patients with abnormal PMEF, even after adjustment for cardiovascular risk factors (hazard ratio, 4.72; 95% CI, 1.24–17.91; P =0.02). Conclusions Vascular aging detected by endothelial function is associated with accelerated physiologic aging, as assessed by the artificial intelligence–ECG Δ age. Patients with endothelial dysfunction and the highest quartile of accelerated physiologic aging have a marked increase in risk for cardiovascular events.

Published

2021

13. Digitizing paper based ECG files to foster deep learning based analysis of existing clinical datasets: An exploratory analysis

Author

Demilade A. Adedinsewo, Habeeba Siddiqui, Patrick W. Johnson, Erika J. Douglass, Michal Cohen-Shelly, Zachi I. Attia, Paul Friedman, Peter A. Noseworthy, and Rickey E. Carter

Subjects

Artificial Intelligence, Medicine (miscellaneous), Health Informatics, Computer Science Applications

Published

2022