Quantization of extraoral free flap monitoring for venous congestion with deep learning integrated iOS applications on smartphones: a diagnostic study

Shao-Yun Hsu; Li-Wei Chen; Ren-Wen Huang; Tzong Yueh Tsai; Shao-Yu Hung; David Chon-Fok Cheong; Johnny Chuieng-Yi Lu; Tommy Nai-Jen Chang; Jung-Ju Huang; Chung-Kan Tsao; Chih-Hung Lin; David Chwei-Chin Chuang; Fu-Chan Wei; Huang-Kai Kao

doi:10.1097/JS9.0000000000000391

Quantization of extraoral free flap monitoring for venous congestion with deep learning integrated iOS applications on smartphones: a diagnostic study

Int J Surg. 2023 Jun 1;109(6):1584-1593. doi: 10.1097/JS9.0000000000000391.

Authors

Shao-Yun Hsu^{1

2

3

4}, Li-Wei Chen⁴, Ren-Wen Huang^{3

4

5}, Tzong Yueh Tsai⁴, Shao-Yu Hung^{2

3

4}, David Chon-Fok Cheong^{2

3

4}, Johnny Chuieng-Yi Lu^{2

3

4}, Tommy Nai-Jen Chang^{2

3

4}, Jung-Ju Huang^{2

3

4}, Chung-Kan Tsao^{2

3

4}, Chih-Hung Lin^{2

3

4}, David Chwei-Chin Chuang^{2

3

4}, Fu-Chan Wei^{2

3

4}, Huang-Kai Kao^{2

3

4}

Affiliations

¹ School of Biological Sciences, Georgia Institute of Technology, Atlanta, Georgia, USA.
² Division of Reconstructive Microsurgery, Department of Plastic and Reconstructive Surgery.
³ Department of Plastic and Reconstructive Surgery, Chang Gung Memorial Hospital, Linkou.
⁴ College of Medicine, Chang Gung University.
⁵ Division of Traumatic Plastic Surgery, Department of Plastic and Reconstructive Surgery, Chang Gung Memorial Hospital, Taoyuan, Taiwan.

Abstract

Background: Free flap monitoring is essential for postmicrosurgical management and outcomes but traditionally relies on human observers; the process is subjective and qualitative and imposes a heavy burden on staffing. To scientifically monitor and quantify the condition of free flaps in a clinical scenario, we developed and validated a successful clinical transitional deep learning (DL) model integrated application.

Material and methods: Patients from a single microsurgical intensive care unit between 1 April 2021 and 31 March 2022, were retrospectively analyzed for DL model development, validation, clinical transition, and quantification of free flap monitoring. An iOS application that predicted the probability of flap congestion based on computer vision was developed. The application calculated probability distribution that indicates the flap congestion risks. Accuracy, discrimination, and calibration tests were assessed for model performance evaluations.

Results: From a total of 1761 photographs of 642 patients, 122 patients were included during the clinical application period. Development (photographs =328), external validation (photographs =512), and clinical application (photographs =921) cohorts were assigned to corresponding time periods. The performance measurements of the DL model indicate a 92.2% training and a 92.3% validation accuracy. The discrimination (area under the receiver operating characteristic curve) was 0.99 (95% CI: 0.98-1.0) during internal validation and 0.98 (95% CI: 0.97-0.99) under external validation. Among clinical application periods, the application demonstrates 95.3% accuracy, 95.2% sensitivity, and 95.3% specificity. The probabilities of flap congestion were significantly higher in the congested group than in the normal group (78.3 (17.1)% versus 13.2 (18.1)%; 0.8%; 95% CI, P <0.001).

Conclusion: The DL integrated smartphone application can accurately reflect and quantify flap condition; it is a convenient, accurate, and economical device that can improve patient safety and management and assist in monitoring flap physiology.

MeSH terms

Deep Learning*
Free Tissue Flaps*
Humans
Hyperemia*
Retrospective Studies
Smartphone