Exploration of classical deep learning algorithm in intelligent classification of Chinese randomized controlled trials_Chinese Journal of Evidence-Based Medicine

Authors：

MAO Bochun ¹ , CHEN Shengkai ¹ , XIE Yu ¹ , YAO Pan ² ,  LI Chunjie ^1,3

1. State Key Laboratory of Oral Disease, National Clinical Research Center for Oral Diseases, West China Hospital of Stomatology, Sichuan University, Chengdu, 610041, P.R.China;
2. College of Computer Science, Sichuan University, Chengdu, 610065, P.R.China;
3. Department of Oral and Maxillofacial Surgery, Department of Evidence Based Dentistry, West China Hospital of Stomatology, Sichuan University, Chengdu, 610041, P.R.China;

Corresponding author：

LI Chunjie, Email: lichunjie07@qq.com

Keywords：

Deep learning; Randomized controlled trial; Literature screening; Evidence-based medicine

DOI：

10.7507/1672-2531.201906050

Video：

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Abstract Full text Figures/Tables Video References Cited by

Objectives To explore the effect of the deep learning algorithm convolutional neural network (CNN) in screening of randomized controlled trials (RCTs) in Chinese medical literatures.Methods Literature with the topic " oral science” published in 2014 were retrieved from CNKI and exported citations containing title and abstract. RCTs screening was conducted by double independent screening, checking and peer discussion. The final results of the citations were used for CNN algorithm model training. After completing the algorithm model training, a prospective comparative trial was organized by searching all literature with the topic "oral science" published in CNKI from January to March 2018 to compare the sensitivity (SEN) and specificity (SPE) of algorithm with manual screening. The initial results of a single screener represented the performance of manual screening, and the final results after peer discussion were used as the gold standard. The best thresholds of algorithm were determined with the receptor operative characteristic (ROC) curve.Results A total of 1 246 RCTs and 4 754 non-RCTs were eventually included for training and testing of CNN algorithm model. 249 RCTs and 949 non-RCTs were included in the prospective trial. The SEN and SPE of manual screening were 98.01% and 98.82%. For the algorithm model, the SEN of RCTs screening decreased with the increase of threshold value while the SPE increased with the increase of threshold value. After 27 changes of threshold value, ROC curve were obtained. The area under the ROC curve was 0.9977, unveiling the optimal accuracy threshold (Threshold=0.4, SEN=98.39%, SPE=98.84%) and high sensitivity threshold (Threshold=0.06, SEN=99.60%, SPE=94.10%).Conclusions A CNN algorithm model is trained with Chinese RCTs classification database established in this study and shows an excellent classification performance in screening RCTs of Chinese medical literature, which is proved to be comparable to the manual screening performance in the prospective controlled trial.

Citation： MAO Bochun, CHEN Shengkai, XIE Yu, YAO Pan, LI Chunjie. Exploration of classical deep learning algorithm in intelligent classification of Chinese randomized controlled trials. Chinese Journal of Evidence-Based Medicine, 2019, 19(11): 1262-1267. doi: 10.7507/1672-2531.201906050 Copy

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2. Borah R, Brown AW, Capers PL, et al. Analysis of the time and workers needed to conduct systematic reviews of medical interventions using data from the PROSPERO registry. BMJ Open, 2017, 7(2): e012545.
3. McKibbon KA, Wilczynski NL, Haynes RB, et al. Retrieving randomized controlled trials from medline: a comparison of 38 published search filters. Health Info Libr J, 2009, 26(3): 187-202.
4. Wallace BC, Noel-Storr A, Marshall IJ, et al. Identifying reports of randomized controlled trials (RCTs) via a hybrid machine learning and crowdsourcing approach. J Am Med Inform Assoc, 2017, 24(6): 1165-1168.
5. Marshall IJ, Kuiper J, Wallace BC. RobotReviewer: evaluation of a system for automatically assessing bias in clinical trials. J Am Med Inform Assoc, 2016, 23(1): 193-201.
6. Elliott JH, Synnot A, Turner T, et al. Living systematic review: 1. Introduction-the why, what, when, and how. J Clin Epidemiol, 2017, 91: 23-30.
7. Thomas J, Noel-Storr A, Marshall I, et al. Living systematic reviews: 2. Combining human and machine effort. J Clin Epidemiol, 2017, 91: 31-37.
8. Simmonds M, Salanti G, McKenzie J, et al. Living systematic reviews: 3. Statistical methods for updating meta-analyses. J Clin Epidemiol, 2017, 91: 38-46.
9. Akl EA, Meerpohl JJ, Elliott J, et al. Living systematic reviews: 4. Living guideline recommendations. J Clin Epidemiol, 2017, 91: 47-53.
10. Sutton AJ. Not enough I say! Expand the remit of living systematic reviews to inform future research. J Clin Epidemiol, 2017, 91: 54-55.
11. Wallace BC, Trikalinos TA, Lau J, et al. Semi-automated screening of biomedical citations for systematic reviews. BMC Bioinformatics, 2010, 11: 55.
12. Marshall IJ, Noel-Storr A, Kuiper J, et al. Machine learning for identifying randomized controlled trials: an evaluation and practitioner's guide. Res Synth Methods, 2018, 9(4): 602-614.
13. 刘群, 张华平, 俞鸿魁, 等. 基于层叠隐马模型的汉语词法分析. 计算机研究与发展, 2004, (8): 1421-1429.
14. 薛松. 基于机器学习的文本处理技术研究与应用. 北京: 北京邮电大学, 2015.
15. Ely JW, Osheroff JA, Ebell MH, et al. Obstacles to answering doctors' questions about patient care with evidence: qualitative study. BMJ, 2002, 324(7339): 710.
16. Haynes RB, McKibbon KA, Wilczynski NL, et al. Optimal search strategies for retrieving scientifically strong studies of treatment from Medline: analytical survey. BMJ, 2005, 330(7501): 1179.
17. Robinson KA, Dickersin K. Development of a highly sensitive search strategy for the retrieval of reports of controlled trials using PubMed. Int J Epidemiol, 2002, 31(1): 150-153.
18. Nwosu CR, Khan KS, Chien PF. A two-term MEDLINE search strategy for identifying randomized trials in obstetrics and gynecology. Obstet Gynecol, 1998, 91(4): 618-622.
19. Duggan LM, Morris M, Adams CE. Prevalence study of the randomized controlled trials in the Journal of Intellectual Disability Research: 1957-1994. J Intellect Disabil Res, 1997, 41(Pt 3): 232-237.
20. Glanville JM, Lefebvre C, Miles JN, et al. How to identify randomized controlled trials in MEDLINE: ten years on. J Med Libr Assoc, 2006, 94(2): 130-136.
21. Cohen AM, Smalheiser NR, McDonagh MS, et al. Automated confidence ranked classification of randomized controlled trial articles: an aid to evidence-based medicine. J Am Med Inform Assoc, 2015, 22(3): 707-717.
22. O'Mara-Eves A, Thomas J, McNaught J, et al. Using text mining for study identification in systematic reviews: a systematic review of current approaches. Syst Rev, 2015, 4: 5.

Chinese Journal of Evidence-Based Medicine

Exploration of classical deep learning algorithm in intelligent classification of Chinese randomized controlled trials

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