Page 48 - Read Online

P. 48

Fuleihan et al. Art Int Surg 2024;4:288-95 https://dx.doi.org/10.20517/ais.2024.39 Page 294

using supervised methods with electronic health record data. Stud Health Technol Inform 2015;216:706-10. PubMed PMC
14. Pellisé F, Serra-Burriel M, Smith JS, et al; International Spine Study Group, European Spine Study Group. Development and
validation of risk stratification models for adult spinal deformity surgery. J Neurosurg Spine 2019;31:587-99. DOI PubMed
15. El Moheb M, Gebran A, Maurer LR, et al. Artificial intelligence versus surgeon gestalt in predicting risk of emergency general
surgery. J Trauma Acute Care Surg 2023;95:565-72. DOI PubMed
16. Ames CP, Smith JS, Pellisé F, et al; European Spine Study Group, International Spine Study Group. Artificial intelligence based
hierarchical clustering of patient types and intervention categories in adult spinal deformity surgery: towards a new classification
scheme that predicts quality and value. Spine 2019;44:915-26. DOI PubMed
17. Choy W, Azad TD, Scheer JK, Safaee MM, Ames CP. Biomarkers in adult spinal deformity surgery. Semin Spine Surg
2023;35:101058. DOI
18. Topol EJ. As artificial intelligence goes multimodal, medical applications multiply. Science 2023;381:adk6139. DOI PubMed
19. Goedmakers CMW, Lak AM, Duey AH, et al. Deep learning for adjacent segment disease at preoperative MRI for cervical
radiculopathy. Radiology 2021;301:664-71. DOI PubMed
20. Mirza FN, Tang OY, Connolly ID, et al. Using ChatGPT to facilitate truly informed medical consent. NEJM AI 2024;1:AIcs2300145.
DOI
21. Ali R, Connolly ID, Tang OY, et al. Bridging the literacy gap for surgical consents: an AI-human expert collaborative approach. NPJ
Digit Med 2024;7:63. DOI PubMed PMC
22. Solanki SL, Pandrowala S, Nayak A, Bhandare M, Ambulkar RP, Shrikhande SV. Artificial intelligence in perioperative management
of major gastrointestinal surgeries. World J Gastroenterol 2021;27:2758-70. DOI PubMed PMC
23. Dave M, Patel N. Artificial intelligence in healthcare and education. Br Dent J 2023;234:761-4. DOI PubMed PMC
24. Boczar D, Sisti A, Oliver JD, et al. Artificial intelligent virtual assistant for plastic surgery patient’s frequently asked questions: a pilot
study. Ann Plast Surg 2020;84:e16-21. DOI PubMed
25. Ni L, Lu C, Liu N, Liu J. MANDY: towards a smart primary care chatbot application. Commun Comput Inform Sci 2017;780:38-52.
DOI
26. Ino T, Samukawa M, Ishida T, et al. Validity of AI-based gait analysis for simultaneous measurement of bilateral lower limb
kinematics using a single video camera. Sensors 2023;23:9799. DOI PubMed PMC
27. Keller AV, Torres-Espin A, Peterson TA, et al. Unsupervised machine learning on motion capture data uncovers movement strategies
in low back pain. Front Bioeng Biotechnol 2022;10:868684. DOI PubMed PMC
28. Rasouli JJ, Shao J, Neifert S, et al. Artificial intelligence and robotics in spine surgery. Global Spine J 2021;11:556-64. DOI PubMed
PMC
29. Mascagni P, Alapatt D, Sestini L, et al. Computer vision in surgery: from potential to clinical value. NPJ Digit Med 2022;5:163. DOI
PubMed PMC
30. Goodman ED, Patel KK, Zhang Y, et al. Analyzing surgical technique in diverse open surgical videos with multitask machine learning.
JAMA Surg 2024;159:185-92. DOI PubMed PMC
31. Lavanchy JL, Zindel J, Kirtac K, et al. Automation of surgical skill assessment using a three-stage machine learning algorithm. Sci Rep
2021;11:5197. DOI PubMed PMC
32. Levin M, McKechnie T, Khalid S, Grantcharov TP, Goldenberg M. Automated methods of technical skill assessment in surgery: a
systematic review. J Surg Educ 2019;76:1629-39. DOI PubMed
33. Lam K, Chen J, Wang Z, et al. Machine learning for technical skill assessment in surgery: a systematic review. NPJ Digit Med
2022;5:24. DOI PubMed PMC
34. Abdelhady AM, Davis CR. Plastic surgery and artificial intelligence: how ChatGPT improved operation note accuracy, time, and
education. Mayo Clin Proc 2023;1:299-308. DOI
35. Zaidat B, Tang J, Arvind V, et al. Can a novel natural language processing model and artificial intelligence automatically generate
billing codes from spine surgical operative notes? Global Spine J 2024;14:2022-30. DOI PubMed PMC
36. Alsareii SA, Raza M, Alamri AM, et al. Machine learning and internet of things enabled monitoring of post-surgery patients: a pilot
study. Sensors 2022;22:1420. DOI PubMed PMC
37. Lee HJ, Jin SM, Kim SJ, et al. Development and validation of an artificial intelligence-based motion analysis system for upper
extremity rehabilitation exercises in patients with spinal cord injury: a randomized controlled trial. Healthcare 2023;12:7. DOI
PubMed PMC
38. Karhade AV, Ogink PT, Thio QCBS, et al. Development of machine learning algorithms for prediction of prolonged opioid
prescription after surgery for lumbar disc herniation. Spine J 2019;19:1764-71. DOI PubMed
39. Wells CI, Xu W, Penfold JA, et al. Wearable devices to monitor recovery after abdominal surgery: scoping review. BJS Open
2022;6:zrac031. DOI PubMed PMC
40. Dawes AJ, Lin AY, Varghese C, Russell MM, Lin AY. Mobile health technology for remote home monitoring after surgery: a meta-
analysis. Br J Surg 2021;108:1304-14. DOI PubMed
41. McGirt MJ, Sivaganesan A, Asher AL, Devin CJ. Prediction model for outcome after low-back surgery: individualized likelihood of
complication, hospital readmission, return to work, and 12-month improvement in functional disability. Neurosurg Focus
2015;39:E13. DOI PubMed
42. Vedula SS, Hager GD. Surgical data science: the new knowledge domain. Innov Surg Sci 2017;2:109-21. DOI PubMed PMC

43 44 45 46 47 48 49 50 51 52 53