TY - JOUR
T1 - Identifying Diabetes Related-Complications in a Real-World Free-Text Electronic Medical Records in Hebrew Using Natural Language Processing Techniques
AU - Saban, Mor
AU - Lutski, Miri
AU - Zucker, Inbar
AU - Uziel, Moshe
AU - Ben-Moshe, Dror
AU - Israel, Ariel
AU - Vinker, Shlomo
AU - Golan-Cohen, Avivit
AU - Laufer, Izhar
AU - Green, Ilan
AU - Eldor, Roy
AU - Merzon, Eugene
N1 - Publisher Copyright:
© 2024 Diabetes Technology Society.
PY - 2024/1/1
Y1 - 2024/1/1
N2 - Background: Studies have demonstrated that 50% to 80% of patients do not receive an International Classification of Diseases (ICD) code assigned to their medical encounter or condition. For these patients, their clinical information is mostly recorded as unstructured free-text narrative data in the medical record without standardized coding or extraction of structured data elements. Leumit Health Services (LHS) in collaboration with the Israeli Ministry of Health (MoH) conducted this study using electronic medical records (EMRs) to systematically extract meaningful clinical information about people with diabetes from the unstructured free-text notes. Objectives: To develop and validate natural language processing (NLP) algorithms to identify diabetes-related complications in the free-text medical records of patients who have LHS membership. Methods: The study data included 2.3 million records of 41 469 patients with diabetes aged 35 or older between the years 2012 and 2017. The diabetes related complications included cardiovascular disease, diabetic neuropathy, nephropathy, retinopathy, diabetic foot, cognitive impairments, mood disorders and hypoglycemia. A vocabulary list of terms was determined and adjudicated by two physicians who are experienced in diabetes care board certified diabetes specialist in endocrinology or family medicine. Two independent registered nurses with PhDs reviewed the free-text medical records. Both rule-based and machine learning techniques were used for the NLP algorithm development. Precision, recall, and F-score were calculated to compare the performance of (1) the NLP algorithm with the reviewers’ comments and (2) the ICD codes with the reviewers’ comments for each complication. Results: The NLP algorithm versus the reviewers (gold standard) achieved an overall good performance with a mean F-score of 86%. This was better than the ICD codes which achieved a mean F-score of only 51%. Conclusion: NLP algorithms and machine learning processes may enable more accurate identification of diabetes complications in EMR data.
AB - Background: Studies have demonstrated that 50% to 80% of patients do not receive an International Classification of Diseases (ICD) code assigned to their medical encounter or condition. For these patients, their clinical information is mostly recorded as unstructured free-text narrative data in the medical record without standardized coding or extraction of structured data elements. Leumit Health Services (LHS) in collaboration with the Israeli Ministry of Health (MoH) conducted this study using electronic medical records (EMRs) to systematically extract meaningful clinical information about people with diabetes from the unstructured free-text notes. Objectives: To develop and validate natural language processing (NLP) algorithms to identify diabetes-related complications in the free-text medical records of patients who have LHS membership. Methods: The study data included 2.3 million records of 41 469 patients with diabetes aged 35 or older between the years 2012 and 2017. The diabetes related complications included cardiovascular disease, diabetic neuropathy, nephropathy, retinopathy, diabetic foot, cognitive impairments, mood disorders and hypoglycemia. A vocabulary list of terms was determined and adjudicated by two physicians who are experienced in diabetes care board certified diabetes specialist in endocrinology or family medicine. Two independent registered nurses with PhDs reviewed the free-text medical records. Both rule-based and machine learning techniques were used for the NLP algorithm development. Precision, recall, and F-score were calculated to compare the performance of (1) the NLP algorithm with the reviewers’ comments and (2) the ICD codes with the reviewers’ comments for each complication. Results: The NLP algorithm versus the reviewers (gold standard) achieved an overall good performance with a mean F-score of 86%. This was better than the ICD codes which achieved a mean F-score of only 51%. Conclusion: NLP algorithms and machine learning processes may enable more accurate identification of diabetes complications in EMR data.
KW - diabetes mellitus
KW - diabetes related-complications
KW - natural language processing
KW - text analytics
UR - http://www.scopus.com/inward/record.url?scp=85183832896&partnerID=8YFLogxK
U2 - 10.1177/19322968241228555
DO - 10.1177/19322968241228555
M3 - Article
C2 - 38288672
AN - SCOPUS:85183832896
SN - 1932-2968
JO - Journal of diabetes science and technology
JF - Journal of diabetes science and technology
ER -