Obesity is a critical healthcare issue affecting the United States. The least risk treatments available for obesity are behavioral interventions meant to promote diet and exercise. Often these interventions contain a mobile component that allows interventionists to collect participant-level data and provide participants with incentives and goals to promote long-term behavioral change. Recently, there has been interest in using direct financial incentives to promote behavior change. In general these are operationalized by having a single intervention budget distributed equally across all participants, meaning intervention costs scale linearly with enrollment. However, as each participant will react differently to different incentive structures and amounts, there has been recent interest by clinicians in using personalized models to more effectively allocate intervention budgets. The key challenge for personalization is that the clinicians do not know a priori which participants will be most responsive to these incentives, and moreover how to administer their scarce budget to maximize cohort health outcomes. In this paper, we consider this challenge of designing personalized weight loss interventions that use direct financial incentives to motivate weight loss while remaining within a budget. We create a predictive model that can predict how individuals may react to different incentive schedules within the context of a behavioral intervention. We integrated this predictive model in an adaptive optimization framework that over the course of the intervention computes what incentives to disburse to participants and remain within the study budget. We show that our optimization framework is asymptotically optimal. We demonstrate the effectiveness of our approach using real-world data from a real world weight loss trial that used financial incentives to incentives weight loss. Our results show that using an 60–80% smaller budget, our adaptive optimization framework is able to help the same number of participants lose weight as an existing one-size-fits-all intervention. Furthermore, using our adaptive optimization framework would spend only $6 per individual across 26 weeks as opposed to the current intervention which would spend $42 per individual in the same time frame to achieve similar clinical outcomes. Our results highlight that providers who choose to implement behavioral interventions at scale will need to use a personalized approach to effectively use their limited budgets.
AcharyaSDElciOUSereikaSM, et al. (2009) Adherence to a behavioral weight loss treatment program enhances weight loss and improvements in biomarkers. Patient Preference and Adherence3: 151.
2.
AdamsKBBoutilierJJDeoS, et al. (2023) Planning a community approach to diabetes care in low-and middle-income countries using optimization. arXiv preprint arXiv:2305.06426.
3.
AkrourRNeumannGAbdulsamadH, et al. (2016) Model-free trajectory optimization for reinforcement learning. In: ICML, pp.2961–2970. PMLR.
4.
AlmeidaFAYouWHardenSM, et al. (2015) Effectiveness of a worksite-based weight loss randomized controlled trial: The worksite study. Obesity23(4): 737–745.
5.
AswaniAKaminskyPMintzY, et al. (2019) Behavioral modeling in weight loss interventions. European Journal of Operational Research (EJOR)272(3): 1058–1072.
6.
AswaniAShenZJSiddiqA (2018) Inverse optimization with noisy data. Operations Research66(3): 870–892.
7.
AwasthiPMaoAMohriM, et al. (2022) H-consistency bounds for surrogate loss minimizers. In: ICML, pp.1117–1174. PMLR.
8.
AyerTAlagozOStoutNK (2012) Or forum—a POMDP approach to personalize mammography screening decisions. Operations Research60(5): 1019–1034.
9.
AyerTZhangCBonifonteA, et al. (2019) Prioritizing hepatitis c treatment in us prisons. Operations Research67(3): 853–873.
10.
BarlowPReevesAMcKeeM, et al. (2016) Unhealthy diets, obesity and time discounting: A systematic literature review and network analysis. Obesity Reviews17(9): 810–819.
11.
BartlettPLJordanMIMcAuliffeJD (2006) Convexity, classification, and risk bounds. The Journal of the Acoustical Society of America (JASA)101(473): 138–156.
12.
BastaniHBayatiM (2020) Online decision making with high-dimensional covariates. Operations Research68(1): 276–294.
13.
BatterhamMTapsellLCharltonK, et al. (2017) Using data mining to predict success in a weight loss trial. Journal of Human Nutrition and Dietetics30(4): 471–478.
14.
BertsekasD (2012) Dynamic Programming and Optimal Control: Volume I. Belmont, MA: Athena scientific.
15.
BertsimasDGuptaVPaschalidisICH (2015) Data-driven estimation in equilibrium using inverse optimization. Master of Public Administration153: 595–633.
16.
BickelPJDoksumKA (2015) Mathematical Statistics: Basic Ideas and Selected Topics, Volumes I-II Package. New York, NY: Chapman and Hall/CRC.
17.
BreimanL (2001) Random forests. Machine Learning45: 5–32.
18.
BrombergerBPorrettPChoudhuryR, et al. (2014) Weight loss interventions for morbidly obese patients with compensated cirrhosis: A markov decision analysis model. Journal of Gastrointestinal Surgery18(2): 321–327.
19.
CawleyJ (2004) An economic framework for understanding physical activity and eating behaviors. American Journal of Preventive Medicine27(3): 117–125.
20.
ChenTGuestrinC (2016) Xgboost: A scalable tree boosting system. In: Proceedings of the 22nd ACM sigkdd international conference on knowledge discovery and data mining, pp.785–794.
21.
ChildersAKVisagamurthyGTaaffeK (2009) Prioritizing patients for evacuation from a health-care facility. Transportation Research Record2137(1): 38–45.
22.
ChudzynskiJRollJMMcPhersonS, et al. (2015) Reinforcement schedule effects on long-term behavior change. The Psychological Record65: 347–353.
23.
ColsonBMarcottePSavardG (2007) An overview of bilevel optimization. Annals of Operations Research153: 235–256.
24.
DaiJGShiP (2019) Inpatient overflow: An approximate dynamic programming approach. Manufacturing & Service Operations Management21(4): 894–911.
25.
DeciELRyanRM (2013) Intrinsic Motivation and Self-determination in Human Behavior. New York, NY: Springer Science & Business Media.
26.
DeoSIravaniSJiangT, et al. (2013) Improving health outcomes through better capacity allocation in a community-based chronic care model. Operations Research61(6): 1277–1294.
27.
EdererFHoldenRMeyerMA, et al. (2013) Gaming and Strategic Ambiguity in Incentive Provision. Hoboken, NJ: Centre for Economic Policy Research.
28.
EkiciAKeskinocakPSwannJL (2014) Modeling influenza pandemic and planning food distribution. Manufacturing & Service Operations Management16(1): 11–27.
29.
EllisJDStrubleCAFodorMC, et al. (2021) Contingency management for individuals with chronic health conditions: A systematic review and meta-analysis of randomized controlled trials. Behaviour Research and Therapy136: 103781.
30.
ErdoganSADentonB (2013) Dynamic appointment scheduling of a stochastic server with uncertain demand. International Journal of Communication25(1): 116–132.
31.
FersterCBSkinnerBF (1957) Mixed schedules.
32.
FukuokaYLindgrenTGMintzYD, et al. (2018) Applying natural language processing to understand motivational profiles for maintaining physical activity after a mobile app and accelerometer-based intervention: The mped randomized controlled trial. JMIR mHealth and uHealth6(6): e10042.
33.
GohSTRudinC (2018) A minimax surrogate loss approach to conditional difference estimation. arXiv preprint arXiv:1803.03769.
34.
GolayAYbarraJ (2005) Link between obesity and type 2 diabetes. Best Practice & Research Clinical Endocrinology & Metabolism19(4): 649–663.
35.
GriloCMMashebRMWilsonGT, et al. (2011) Cognitive–behavioral therapy, behavioral weight loss, and sequential treatment for obese patients with binge-eating disorder: A randomized controlled trial. Journal of Consulting and Clinical Psychology79(5): 675.
HastieTTibshiraniRFriedmanJH, et al. (2009) The Elements of Statistical Learning: Data Mining, Inference, and Prediction, Volume 2. New York, NY: Springer.
38.
HeQMintzY (2023) Model based reinforcement learning for personalized heparin dosing. arXiv preprint arXiv:2304.10000.
39.
HillCWeirBWFuentesLW, et al. (2018) Relationship between weekly patterns of caloric intake and reported weight loss outcomes: Retrospective cohort study. JMIR mHealth and uHealth6(4): e8320.
40.
JakicicJMDavisKKRogersRJ, et al. (2016) Effect of wearable technology combined with a lifestyle intervention on long-term weight loss: The idea randomized clinical trial. Journal of the American Medical Association316(11): 1161–1171.
41.
JohnLKLoewensteinGTroxelAB, et al. (2011) Financial incentives for extended weight loss: A randomized, controlled trial. Journal of General Internal Medicine26(6): 621–626.
42.
KautMSteinW (2003) Evaluation of Scenario-generation Methods for Stochastic Programming. Yokohama, Japan: Humboldt-Universität zu Berlin, Mathematisch-Naturwissenschaftliche Fakultät.
43.
KeshavarzAWangYBoydS (2011) Imputing a convex objective function. In: 2011 IEEE international symposium on intelligent control, pp.613–619. IEEE.
44.
KotuVDeshpandeB (2019) Chapter 12 - time series forecasting. In: Kotu V and Deshpande B (eds.) Data Science (Second Edition), 2nd edition. Morgan Kaufmann. ISBN 978-0-12-814761-0, pp.395–445. https://doi.org/10.1016/B978-0-12-814761-0.00012-5.
45.
KrentzAFujiokaKHompeschM (2016) Evolution of pharmacological obesity treatments: Focus on adverse side-effect profiles. Diabetes, Obesity and Metabolism18(6): 558–570.
46.
LachoutPLiebscherEVogelS (2005) Strong convergence of estimators as n-minimisers of optimisation problemsof optimisation problems. Annals of the Institute of Statistical Mathematics57(2): 291–313.
47.
LeaheyTMSubakLLFavaJ, et al. (2015) Benefits of adding small financial incentives or optional group meetings to a web-based statewide obesity initiative. Obesity23(1): 70–76.
48.
LeeELavieriMSVolkM (2019) Optimal screening for hepatocellular carcinoma: A restless bandit model. Manufacturing & Service Operations Management21(1): 198–212.
49.
LeeSHHanPHalesRK, et al. (2020) Multi-view radiomics and dosiomics analysis with machine learning for predicting acute-phase weight loss in lung cancer patients treated with radiotherapy. Physics in Medicine & Biology65(19): 195015.
50.
LemstraMBirdYNwankwoC, et al. (2016) Weight loss intervention adherence and factors promoting adherence: A meta-analysis. Patient Preference and Adherence10: 1547.
51.
McKenzieBLCoyleDHSantosJA, et al. (2021) Investigating sex differences in the accuracy of dietary assessment methods to measure energy intake in adults: A systematic review and meta-analysis. The American Journal of Clinical Nutrition113(5): 1241–1255.
52.
MifflinMDSt JeorSTHillLA, et al. (1990) A new predictive equation for resting energy expenditure in healthy individuals. The American Journal of Clinical Nutrition51(2): 241–247.
53.
MintzYAswaniAKaminskyP, et al. (2020) Nonstationary bandits with habituation and recovery dynamics. Operations Research68(5): 1493–1516.
54.
MintzYAswaniAKaminskyP, et al. (2023) Behavioral analytics for myopic agents. European Journal of Operational Research310(2): 793–811.
55.
MurphySAVan der VaartAW (2000) On profile likelihood. Journal of the American Statistical Association95(450): 449–465.
56.
Nahum-ShaniIGreerZMTrellaAL, et al. (2024) Optimizing an adaptive digital oral health intervention for promoting oral self-care behaviors: Micro-randomized trial protocol. Contemporary Clinical Trials139: 107464.
57.
NguyenXWainwrightMJJordanMI (2009) On surrogate loss functions and f-divergences.
58.
OsbandIVan RoyB (2014) Model-based reinforcement learning and the eluder dimension. NeurIPS27.
59.
PedregosaFVaroquauxGGramfortA, et al. (2011) Scikit-learn: Machine learning in python. Journal of Machine Learning Research 12: 2825–2830.
60.
RaberMLiaoYRaraA, et al. (2021) A systematic review of the use of dietary self-monitoring in behavioural weight loss interventions: Delivery, intensity and effectiveness. Public Health Nutrition24(17): 5885–5913.
61.
ResnickSI (2013) Adventures in Stochastic Processes. New York, NY: Springer Science & Business Media.
62.
RyanRMDeciEL (2000) Self-determination theory and the facilitation of intrinsic motivation, social development, and well-being. American Psychologist55(1): 68.
63.
SchellGJMarreroWJLavieriMS, et al. (2016) Data-driven Markov decision process approximations for personalized hypertension treatment planning. MDM Policy & Practice1(1): 2381468316674214.
64.
StiermanBAffulJCarrollM, et al. (2021) National health and nutrition examination survey 2017–march 2020 prepandemic data files-development of files and prevalence estimates for selected health outcomes. National Health Statistics Reports158. DOI: https://doi.org/10.15620/cdc:106273.
SuttonRSBartoAG (2018) Reinforcement Learning: An Introduction. Cambridge, MA: MIT press.
67.
ThomasDMMartinCKHeymsfieldS, et al. (2011) A simple model predicting individual weight change in humans. Journal of Biological Dynamics5(6): 579–599.
68.
Van RossumGDrakeFL (2009) Python 3 Reference Manual. Scotts Valley, CA: CreateSpace. ISBN 1441412697.
69.
VoilsCILevineEGierischJM, et al. (2018) Study protocol for log2lose: A feasibility randomized controlled trial to evaluate financial incentives for dietary self-monitoring and interim weight loss in adults with obesity. Contemporary Clinical Trials65: 116–122.
70.
VoilsCIPendergastJHaleSL, et al. (2021) A randomized feasibility pilot trial of a financial incentives intervention for dietary self-monitoring and weight loss in adults with obesity. Translational Behavioral Medicine11(4): 954–969.
71.
VolppKGJohnLKTroxelAB, et al. (2008) Financial incentive–based approaches for weight loss: A randomized trial. The Journal of the American Medical Association300(22): 2631–2637.
72.
WardZJBleichSNLongMW, et al. (2021) Association of body mass index with health care expenditures in the united states by age and sex. PloS one16(3): e0247307.
73.
WingRRKoeskeREpsteinLH, et al. (1987) Long-term effects of modest weight loss in type ii diabetic patients. Archives of Internal Medicine147(10): 1749–1753.
74.
WolseyLANemhauserGL (1999) Integer and Combinatorial Optimization, Volume 55. New York, NY: John Wiley & Sons.
75.
YuHBertsekasD (2012) Discretized approximations for POMDP with average cost. arXiv preprint arXiv:1207.4154.
76.
YuHBertsekasDP (2008) On near optimality of the set of finite-state controllers for average cost POMDP. Mathematical of Operations Research33(1): 1–11.
77.
ZhangJNiCSzepesvariC, et al. (2021) On the convergence and sample efficiency of variance-reduced policy gradient method. NeurIPS34: 2228–2240.
78.
ZhouMMintzYFukuokaY, et al. (2018) Personalizing mobile fitness apps using reinforcement learning. In: CEUR, Vol. 2068. NIH Public Access.
Supplementary Material
Please find the following supplemental material available below.
For Open Access articles published under a Creative Commons License, all supplemental material carries the same license as the article it is associated with.
For non-Open Access articles published, all supplemental material carries a non-exclusive license, and permission requests for re-use of supplemental material or any part of supplemental material shall be sent directly to the copyright owner as specified in the copyright notice associated with the article.
