Brenac et al. Art Int Surg 2024;4:296-315  https://dx.doi.org/10.20517/ais.2024.49                                                                                                                                                       Page 308



 targeting HDAC4                            treatment method with broad applications in biomedical
 (3) Develop a microneedle-mediated patch for   fields
 TSA delivery to improve treatment efficacy and
 reduce secondary damage
 3D and predictive   Knoops   A machine learning framework for   2019 Scientific Reports  (1) Develop a ML framework for automated   (1) This approach offers high diagnostic accuracy
 [42]
 modeling  et al.  automated diagnosis and   diagnosis, risk stratification, and treatment in PRS   (95.5% sensitivity and 95.2% specificity) and simulates
 computer-assisted planning in   (2) Enhance precision and efficiency in ML-  surgical outcomes with a mean accuracy of 1.1 ±  0.3
 plastic and reconstructive surgery  assisted surgical planning to improve clinical   mmc
 decision making and outcomes               (2) This framework can automate diagnosis and provide
                                            patient-specific training from 3D models
 [55]
 Knoops et al.  A novel soft tissue prediction   2018 PloS One  (1) Develop a probabilistic FEM to predict   (1) The probabilistic FEM was validated on 8 patients
 methodology for orthognathic   postoperative facial soft tissues following   (2) The FEM accurately predicted changes in the nose
 surgery based on probabilistic finite   orthognathic surgery   and upper lip but underestimated changes in the cheeks
 element modeling  (2) Addressing the limitations of prediction models  and lower lip
 by including variability and uncertainty in the   (3) This model offers patients and surgeons a more
 prediction process                         comprehensive understanding of surgical impacts
 [62]
 3D printing for   Chae et al.  3D volumetric analysis for planning  2014 Breast Cancer   (1) Develop a new approach to volumetric analysis  (1) Multiple techniques for volumetric analysis for breast
 planning and   breast reconstructive surgery  Research and   for breast reconstructive surgery using 3D   asymmetry were reported
 implantation  Treatment  photography       (2) Breast volumes can be visualized through 3D images,
 (2) Improve accuracy in assessing breast volume,   accurately calculated, and produced as 3D haptic models
 shape, and projection compared to traditional 2D   for operative guidance
 photography


 AI: Artificial intelligence; ASRM: American Society of Reconstructive Microsurgery; ASPS: American Society of Plastic Surgeons; NIH: National Institute of Health; AIVAs: artificial intelligence virtual assistants; FAQs:
 frequently asked questions; CT: computed tomography; CV: computer vision; DIEP: deep inferior epigastric perforators; ML: machine learning; AUC: area under the curve; FACE-Q: Facial Appearance and Cosmetic
 Surgery Quality of Life Questionnaire; CNN: convolutional neural networks; CS: craniosynostosis; 3DMM: 3D morphable model; BMI: body mass index; ED: emergency department; CTR: carpal tunnel release; TSA:
 trichostatin A; HDAC4: histone deacetylase 4; PRS: plastic and reconstructive surgery; FEM: finite element model.



 it can also be used as a tool for enhancing communication between patient and physician. ML has been explored in combination with photographic data to

                     [39]
 maintain proper standardization of procedures and offer more precise postoperative assessment . Using pre- and postoperative pictures, Zhang et al. showed
                               [39]
 that neural networks could identify preoperative age and facial age reduction following facelift surgery . A positive correlation between the algorithmically
 determined result and patient satisfaction after facelift was identified, representing a validated method of quantifying postoperative results and efficacy for

 [39]
 plastic surgeons . In another study, Boonipat et al. used ML to assess postoperative facial expression improvement after facial reanimation surgery .
                                                                                           [40]
 Recording of facial expressions was performed for each patient in a video clip and analyzed with ML software to detect facial expressions . ML algorithms
                                                                         [40]
 were found to be capable of reading facial emotional expressions and providing a quantification of those expressions. These tools may thus be helpful in
 [40]
 assessing facial palsy and the success of postoperative outcomes . Moreover, corrective procedures, the use of neurotoxins, or soft tissue fillers could utilize
 ML as an assessment tool for photographic or recorded data [39,40] .