Page 29 - Read Online
P. 29
Page 265 Toossi et al. Art Int Surg 2024;4:258-66 https://dx.doi.org/10.20517/ais.2024.27
18. Mekhael E, El Rachkidi R, Saliby RM, et al. Functional assessment using 3D movement analysis can better predict health-related
quality of life outcomes in patients with adult spinal deformity: a machine learning approach. Front Surg 2023;10:1166734. DOI
PubMed PMC
19. Nassim N, Mekhael E, Rachkidi RE, et al. Global Sagittal Angle and T9-tilt seem to be the most clinically and functionally relevant
global alignment parameters in patients with Adult Spinal Deformity. Brain Spine 2024;4:102805. DOI PubMed PMC
20. Diebo BG, Oren JH, Challier V, et al. Global sagittal axis: a step toward full-body assessment of sagittal plane deformity in the human
body. J Neurosurg Spine 2016;25:494-9. DOI PubMed
21. Legaye J, Duval-Beaupere G. Sagittal plane alignment of the spine and gravity: a radiological and clinical evaluation. Acta Orthop
Belg 2005;71:213-20. PubMed
22. Williamson TK, Krol O, Tretiakov P, et al. Crossing the bridge from degeneration to deformity: when does sagittal correction impact
outcomes in adult spinal deformity surgery? Spine 2023;48:E25-32. DOI PubMed
23. Johnson GW, Chanbour H, Ali MA, et al. Artificial intelligence to preoperatively predict proximal junction kyphosis following adult
spinal deformity surgery: soft tissue imaging may be necessary for accurate models. Spine 2023;48:1688-95. DOI PubMed PMC
24. Scheer JK, Oh T, Smith JS, et al; International Spine Study Group. Development of a validated computer-based preoperative predictive
model for pseudarthrosis with 91% accuracy in 336 adult spinal deformity patients. Neurosurg Focus 2018;45:E11. DOI PubMed
25. Burström G, Buerger C, Hoppenbrouwers J, et al. Machine learning for automated 3-dimensional segmentation of the spine and
suggested placement of pedicle screws based on intraoperative cone-beam computer tomography. J Neurosurg Spine 2019;31:147-54.
DOI PubMed
26. Siemionow KB, Forsthoefel CW, Foy MP, Gawel D, Luciano CJ. Autonomous lumbar spine pedicle screw planning using machine
learning: A validation study. J Craniovertebr Junction Spine 2021;12:223-7. DOI PubMed PMC
27. Wilson JP Jr, Kumbhare D, Kandregula S, Oderhowho A, Guthikonda B, Hoang S. Proposed applications of machine learning to
intraoperative neuromonitoring during spine surgeries. Neurosci Inf 2023;3:100143. DOI
28. Pierce KE, Kapadia BH, Naessig S, et al. Validation of the ACS-NSQIP risk calculator: a machine-learning risk tool for predicting
complications and mortality following adult spinal deformity corrective surgery. Int J Spine Surg 2021;15:1210-6. DOI PubMed
PMC
29. Kim JS, Arvind V, Oermann EK, et al. Predicting surgical complications in patients undergoing elective adult spinal deformity
procedures using machine learning. Spine Deform 2018;6:762-70. DOI PubMed
30. Raman T, Vasquez-Montes D, Varlotta C, Passias PG, Errico TJ. Decision tree-based modelling for identification of predictors of
blood loss and transfusion requirement after adult spinal deformity surgery. Int J Spine Surg 2020;14:87-95. DOI PubMed PMC
31. De la Garza Ramos R, Hamad MK, Ryvlin J, et al. An artificial neural network model for the prediction of perioperative blood
transfusion in adult spinal deformity surgery. J Clin Med 2022;11:4436. DOI PubMed PMC
32. Durand WM, DePasse JM, Daniels AH. Predictive modeling for blood transfusion after adult spinal deformity surgery: a tree-based
machine learning approach. Spine 2018;43:1058-66. DOI PubMed
33. Ames CP, Smith JS, Pellisé F, et al; European Spine Study Group, International Spine Study Group. Development of deployable
predictive models for minimal clinically important difference achievement across the commonly used health-related quality of life
instruments in adult spinal deformity surgery. Spine 2019;44:1144-53. DOI PubMed
34. Patel AV, White CA, Schwartz JT, et al. Emerging technologies in the treatment of adult spinal deformity. Neurospine 2021;18:417-
27. DOI PubMed PMC
35. Löchel J, Putzier M, Dreischarf M, et al. Deep learning algorithm for fully automated measurement of sagittal balance in adult spinal
deformity. Eur Spine J 2024;Online ahead of print. DOI PubMed
36. Hopkins BS, Mazmudar A, Driscoll C, et al. Using artificial intelligence (AI) to predict postoperative surgical site infection: a
retrospective cohort of 4046 posterior spinal fusions. Clin Neurol Neurosurg 2020;192:105718. DOI PubMed
37. Schonfeld E, Pant A, Shah A, et al. Evaluating computer vision, large language, and genome-wide association models in a limited
sized patient cohort for pre-operative risk stratification in adult spinal deformity surgery. J Clin Med 2024;13:656. DOI PubMed
PMC
38. Jain D, Durand W, Burch S, Daniels A, Berven S. Machine learning for predictive modeling of 90-day readmission, major medical
complication, and discharge to a facility in patients undergoing long segment posterior lumbar spine fusion. Spine 2020;45:1151-60.
DOI PubMed
39. Arora A, Demb J, Cummins DD, et al. Development and internal validation of predictive models to assess risk of post-acute care
facility discharge in adults undergoing multi-level instrumented fusions for lumbar degenerative pathology and spinal deformity. Spine
Deform 2023;11:163-73. DOI PubMed PMC
40. Lee CH, Jo DJ, Oh JK, et al. Development and validation of an online calculator to predict proximal junctional kyphosis after adult
spinal deformity surgery using machine learning. Neurospine 2023;20:1272-80. DOI PubMed PMC
41. Noh SH, Lee HS, Park GE, et al. Predicting mechanical complications after adult spinal deformity operation using a machine learning
based on modified global alignment and proportion scoring with body mass index and bone mineral density. Neurospine 2023;20:265-
74. DOI PubMed PMC
42. Balaban B, Yilgor C, Yucekul A, et al. Building clinically actionable models for predicting mechanical complications in
postoperatively well-aligned adult spinal deformity patients using XGBoost algorithm. Inform Med Unlocked 2023;37:101191. DOI
43. Lovecchio F, Lafage R, Sheikh Alshabab B, et al. Can discharge radiographs predict junctional complications? A decision tree
