Decision Analysis and Reinforcement Learning in Surgical Decision-making

Overview

Journal Surgery

Specialty General Surgery

Date 2020 Jun 17

PMID 32540036

Citations 8

Authors

Tyler J Loftus

Amanda C Filiberto

Yanjun Li

Jeremy Balch

Allyson C Cook

Patrick J Tighe

Philip A Efron

Gilbert R Upchurch Jr

Parisa Rashidi

Xiaolin Li

Azra Bihorac

Affiliations

Soon will be listed here.

Abstract

Background: Surgical patients incur preventable harm from cognitive and judgment errors made under time constraints and uncertainty regarding patients' diagnoses and predicted response to treatment. Decision analysis and techniques of reinforcement learning theoretically can mitigate these challenges but are poorly understood and rarely used clinically. This review seeks to promote an understanding of decision analysis and reinforcement learning by describing their use in the context of surgical decision-making.

Methods: Cochrane, EMBASE, and PubMed databases were searched from their inception to June 2019. Included were 41 articles about cognitive and diagnostic errors, decision-making, decision analysis, and machine-learning. The articles were assimilated into relevant categories according to Preferred Reporting Items for Systematic Reviews and Meta-Analyses extension for Scoping Reviews guidelines.

Results: Requirements for time-consuming manual data entry and crude representations of individual patients and clinical context compromise many traditional decision-support tools. Decision analysis methods for calculating probability thresholds can inform population-based recommendations that jointly consider risks, benefits, costs, and patient values but lack precision for individual patient-centered decisions. Reinforcement learning, a machine-learning method that mimics human learning, can use a large set of patient-specific input data to identify actions yielding the greatest probability of achieving a goal. This methodology follows a sequence of events with uncertain conditions, offering potential advantages for personalized, patient-centered decision-making. Clinical application would require secure integration of multiple data sources and attention to ethical considerations regarding liability for errors and individual patient preferences.

Conclusion: Traditional decision-support tools are ill-equipped to accommodate time constraints and uncertainty regarding diagnoses and the predicted response to treatment, both of which often impair surgical decision-making. Decision analysis and reinforcement learning have the potential to play complementary roles in delivering high-value surgical care through sound judgment and optimal decision-making.

Citing Articles

Use of artificial intelligence in breast surgery: a narrative review.

Seth I, Lim B, Joseph K, Gracias D, Xie Y, Ross R Gland Surg. 2024; 13(3):395-411.

PMID: 38601286 PMC: 11002485. DOI: 10.21037/gs-23-414.

Identifying acute illness phenotypes via deep temporal interpolation and clustering network on physiologic signatures.

Ren Y, Li Y, Loftus T, Balch J, Abbott K, Ruppert M Sci Rep. 2024; 14(1):8442.

PMID: 38600110 PMC: 11006654. DOI: 10.1038/s41598-024-59047-x.

Personalized decision-making for acute cholecystitis: Understanding surgeon judgment.

Filiberto A, Efron P, Frantz A, Bihorac A, Upchurch Jr G, Loftus T Front Digit Health. 2022; 4:845453.

PMID: 36339515 PMC: 9632988. DOI: 10.3389/fdgth.2022.845453.

Present and future of machine learning in breast surgery: systematic review.

Soh C, Shah V, Arjomandi Rad A, Vardanyan R, Zubarevich A, Torabi S Br J Surg. 2022; 109(11):1053-1062.

PMID: 35945894 PMC: 10364755. DOI: 10.1093/bjs/znac224.

Advancements of Artificial Intelligence in Liver-Associated Diseases and Surgery.

Taha A, Ochs V, Kayhan L, Enodien B, Frey D, Krahenbuhl L Medicina (Kaunas). 2022; 58(4).

PMID: 35454298 PMC: 9029673. DOI: 10.3390/medicina58040459.

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