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Optimizing adaptive stepped-care interventions to change adults’ health behaviors: A systematic review

Published online by Cambridge University Press:  25 August 2023

McKenzie K. Roddy Open the ORCID record for McKenzie K. Roddy [Opens in a new window] ,
Angela F. Pfammatter  and
Lindsay S. Mayberry
McKenzie K. Roddy*
Affiliation:
Department of Medicine, Vanderbilt University Medical Center, Nashville, TN, USA Center for Health Behavior and Health Education, Vanderbilt University Medical Center, Nashville, TN, USA
Angela F. Pfammatter
Affiliation:
College of Education, Health, and Human Sciences, University of Tennessee, Knoxville, TN, USA
Lindsay S. Mayberry
Affiliation:
Department of Medicine, Vanderbilt University Medical Center, Nashville, TN, USA Center for Health Behavior and Health Education, Vanderbilt University Medical Center, Nashville, TN, USA
*
Corresponding author: M. K. Roddy, PhD; Email: mckenzie.roddy@vumc.org
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Abstract

Chronic diseases are ubiquitous and costly in American populations. Interventions targeting health behavior change to manage chronic diseases are needed, but previous efforts have fallen short of producing meaningful change on average. Adaptive stepped-care interventions, that tailor treatment based on the needs of the individual over time, are a promising new area in health behavior change. We therefore conducted a systematic review of tests of adaptive stepped-care interventions targeting health behavior changes for adults with chronic diseases. We identified 9 completed studies and 13 research protocols testing adaptive stepped-care interventions for health behavior change. The most common health behaviors targeted were substance use, weight management, and smoking cessation. All identified studies test intermediary tailoring for treatment non-responders via sequential multiple assignment randomized trials (SMARTs) or singly randomized trials (SRTs); none test baseline tailoring. From completed studies, there were few differences between embedded adaptive interventions and minimal differences between those classified as treatment responders and non-responders. In conclusion, updates to this work will be needed as protocols identified here publish results. Future research could explore baseline tailoring variables, apply methods to additional health behaviors and target populations, test tapering interventions for treatment responders, and consider adults’ context when adapting interventions.

Keywords

Systematic reviewhealth behavioradaptive interventionsdecision ruleSMART
Type
Review Article
Information
Journal of Clinical and Translational Science , Volume 7 , Issue 1 , 2023 , e190
Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Association for Clinical and Translational Science

Introduction

Chronic diseases, noncommunicable diseases that last at least a year and require ongoing medical attention (e.g., cancer, diabetes, obesity, and heart disease), are the leading cause of death and disability as well as being responsible for the largest proportion of US healthcare costs [1]. Furthermore, in 2019, more than half of Americans between the ages of 18 and 34 reported having at least one chronic disease [Reference Watson, Carlson and Loustalot2], highlighting that the burden of chronic diseases will continue to grow as the population ages. Many chronic diseases are caused or exacerbated by health behaviors including tobacco use, poor nutrition, and physical inactivity [1]. Interventions targeting health behavior change are well positioned to address these growing problems in the population, and numerous such interventions exist.

However, health behavior change interventions have small or null effects on average. A review of internet delivered interventions to promote health behavior change reported a small average effect (d = 0.16, 95% CI 0.09–0.23) [Reference Webb, Joseph, Yardley and Michie3]. Within specific disease contexts, research has found response to weight loss interventions is suboptimal [Reference Franz, VanWormer and Crain4] and mixed results for improving hemoglobin A1c (HbA1c) for adults with diabetes [Reference Greenwood, Gee, Fatkin and Peeples5,Reference Fitzpatrick, Schumann and Hill-Briggs6]. Further, response to treatment is often heterogeneous across individuals. For example, research shows adults with elevated baseline HbA1c have greater reductions in HbA1c during a self-care support intervention than adults with moderately elevated baseline HbA1c.[Reference Chrvala, Sherr and Lipman7] Finally, many chronic conditions wax and wane over time and the intervention needs of individuals are therefore not static [Reference Almirall, Nahum-Shani, Sherwood and Murphy8]. With this context in mind, there have been calls for further research and applications of adaptive interventions in the management of chronic diseases [Reference Collins, Murphy and Strecher9,Reference Collins, Murphy and Bierman10].

Adaptive interventions are defined by a sequence of decision rules or if-then statements that specify whether, when, and how to alter the intervention [Reference Almirall, Nahum-Shani, Sherwood and Murphy8,Reference Collins, Murphy and Bierman10]. For example, an adaptive intervention for weight loss might specify that all participants receive diet and exercise counseling for 8 weeks. At 8 weeks, if participants have not lost>5lbs, they are referred to group sessions for an additional 6 weeks. However, if at 8 weeks participants have lost ≥ 5lbs, they continue with their current treatment plan. As in this example, decision rules for adaptive interventions are centered on characteristics of the individual such as level of the outcome measured at baseline or progress towards the outcome measured during the intervention [Reference Almirall, Nahum-Shani, Sherwood and Murphy8]. Clinical judgment and prior research inform the timing of when decision rules are applied, as well as the decision rules themselves, and what adaptations are applied [Reference Collins, Murphy and Bierman10]. Adaptive interventions are well suited to heterogeneous populations, populations with heterogeneous treatment responses, and/or conditions with high frequency of relapse or waxing and waning of symptoms. Benefits of adaptive interventions include reducing wasted resources, increasing compliance, reducing negative effects associated with inappropriate treatment for certain individuals, and enhancing potency [Reference Collins, Murphy and Bierman10].

Broadly, there are two classes of adaptive interventions: dynamic and stepped care. Dynamic interventions, including just-in-time adaptive interventions (JITAI), tailor the intervention daily or hourly in response to the state of the individual which frequently changes (e.g., urges to smoke). Stepped care interventions tailor the intervention less often, based on individuals’ responses to the intervention (e.g., weight loss). This review will focus on stepped care adaptive interventions, where care is viewed as a continuum through which individuals can move – increasing treatment for nonresponders and tapering treatment as individuals progress over weeks or months.

Clinical trials of stepped-care adaptive interventions are designed to test the decision rules that form the backbone of the final intervention. If an adaptive intervention is developed using prior literature and clinical judgment only to inform the decision rules, the specific decision rules cannot be empirically tested. Rather, adaptive interventions iteratively developed by creating and then testing decision rules serve to produce the most knowledge efficiently. The aspects of decision rules to be tested include the baseline tailoring variables and the intermediary tailoring variables to be used (if any) and at what levels. Aspects of a decision rule to be tested could also include when to tailor the intervention and/or what type of treatment or modality of treatment delivery should be used in different cases. Trials of adaptive interventions can test the efficacy of multiple embedded interventions [Reference Nahum-Shani, Dziak, Walton and Dempsey11]. They often include options for further exploratory analyses beyond the main research questions, though, similar to other experimental designs, power may be a concern due to small sample sizes in some cells (e.g., when testing moderation of treatment effects).

A Sequential Multiple Assignment Randomized Trial (SMART) is a research design developed for testing adaptive interventions systematically and efficiently. SMARTs are inherently resource efficient, asking multiple questions about the components of an adaptive intervention in a high-quality manner without unduly increasing sample size [Reference Collins, Murphy and Strecher9]. Further, adaptive interventions tested via SMARTs mirror clinical practice in that individuals’ unique needs and circumstances inform the treatment delivered [Reference Collins, Nahum-Shani and Almirall12]. Importantly, when designed to systematically test decision rules, adaptive interventions are replicable in ways that traditional clinical practice is not [Reference Collins, Murphy and Bierman10]. Due to their multiple randomization points, SMARTs are especially well suited to test the rules that govern decisions made in stepped-care adaptive interventions.

Current Study

Rigorous tests optimizing adaptive interventions are relatively new experimental designs that are being applied to health behavior interventions. Interventions for health behavior change have historically struggled to, on average, produce clinically meaningful change and maintain results, providing opportunity for adaptive interventions to improve outcomes. Within the field of health behavior interventions, there are often target behaviors (e.g., increasing physical activity), which can impact several outcomes of interest (e.g., weight management, glycemic control). Additionally, there are target behaviors (e.g., medication adherence) that are applicable in multiple contexts (e.g., type 2 diabetes, HIV prevention and treatment). Given the emerging state of these methods in this field and the commonality of behaviors targeted throughout the field, we seek to systematically review applications of optimization methods to adaptive intervention development. Specifically, we are interested in optimization of adaptive interventions for adults to change health behaviors to learn how tailoring is being done and tested. Results may help highlight the types of questions being asked about adaptive interventions and inform future trial designs.

Materials and Methods

Data Sources

Our systematic review covered studies published up to December 2022. The investigators searched Google Scholar for eligible studies using a combination of key words (sequential multiple assignment randomized trial, SMART, adaptive, optimize AND health behaviors, behavior change, alcohol, and drug). We also systematically searched the reference lists of included studies and recent reviews of similar topics (e.g., Bigirumurame et al. [Reference Bigirumurame, Uwimpuhwe and Wason13], Jaehne et al. [Reference Jaehne, Loessl, Frick, Berner, Hulse and Balmford14], and Miller [Reference Miller15]), as well as searched for papers that cite key methodological references (e.g., Murphy [Reference Murphy16] and Collins et al. [Reference Collins, Murphy and Strecher9])

Study Selection and Data Extraction

We reviewed titles and abstracts of citations and identified eligible articles. Inclusion criteria were studies that (1) seek to optimize adaptive stepped-care interventions, (2) target an observable health behavior change as proximal or distal outcome, (3) test one or more decision rules, (4) are systematically different across individuals and/or across time based on participant characteristics or clinical characteristic (vs. fixed intervention, where all participants in a condition receive identical treatment), (5) included adults in the sample, and 6) were published in English.

We included both protocol papers and articles with results from such studies. Investigators collected the following information from each article that was eligible: description of the sample, research design, initial treatment, duration to tailoring, definition of treatment non-response, subsequent treatments and tailoring, and outcomes when available or decisions to be tested for protocols.

Literature searches yielded 149 articles. The first author read the titles and abstracts of these articles to determine if they were appropriate for initial inclusion, resulting in 87 articles. Of these, 61 articles were excluded because they described studies testing dynamic interventions (e.g., JITAI or micro randomized trials; n = 7), did not evaluate health behavior change (n = 13), did not test decision rules (n = 29), theoretically described methods only (n = 8), or studied exclusively child/adolescent populations (n = 4). The resulting sample yielded n = 26 studies describing k = 22 unique research projects, see Fig. 1 for flow diagram of inclusion. If a study had published results and a published protocol, or multiple papers describing results, they were grouped together for description below.

Figure 1. Systematic review inclusion flow diagram.

Given the diversity of health behaviors targeted and methods employed, we used a narrative synthesis approach to describe and identify patterns of tests of decision rules across included studies.[Reference Roberts, Sowden, Petticrew, Arai, Rodgers and Britten17] We provide results overall and also separately, studies reporting outcomes of trials and studies reporting protocols.

Results

Of the 22 included research projects, 9 tested decision rules for adaptive stepped-care interventions and 13 were research protocols (See Table 1). All studies were optimization studies; however, one compared a control condition to a SMART [Reference Patrick, Lyden and Morrell18]. Almost all studies (25/26) were published in the last 18 years since 2005. All included projects utilized Sequential Multiple Assignment Randomized Trials (SMARTs) or singly randomized trials (SRTs; an experimental design where participants are randomized once over the course of treatment – here mid-way through treatment) [Reference Almirall, Nahum-Shani, Wang and Kasari19]. Every project but one [Reference Germeroth, Benno and Kolko Conlon20] tested intermediary tailoring for treatment nonresponders based on progress towards the primary outcome. No studies evaluated change in hypothesized behavioral mediators as indicative of nonresponse to the intervention to inform tailoring. Intermediary tailoring occurred between 2 and 14 weeks. Only three protocols tested stepping down or tapering care for treatment responders [Reference Belzer, MacDonell and Ghosh21Reference Fu, Rothman and Vock23], while no completed studies tested reducing care for responders. No identified projects tested baseline tailoring. Two studies randomized the length of time to tailoring or initial intervention [Reference Fu, Rothman and Vock23,Reference Sherwood, Butryn and Forman24]. No participants received an intervention with the first stage tailored to their presenting criteria (e.g., baseline disease severity).

Table 1. Characteristics of included studies (k = 22)

Several projects targeted substance use (k = 6) [Reference Patrick, Lyden and Morrell18,Reference Borsari, Tevyaw, Barnett, Kahler and Monti25Reference Schmitz, Stotts and Vujanovic31]. weight management (k = 5) [Reference Germeroth, Benno and Kolko Conlon20,Reference Sherwood, Butryn and Forman24,Reference Carels, Young and Coit32Reference Carels, Miller and Selensky35], and smoking cessation (k = 4) [Reference Fu, Rothman and Vock23,Reference Edelman, Dziura and Deng36Reference Zhao, Weng and Luk38]; fewer targeted medication adherence (k = 3) [Reference Belzer, MacDonell and Ghosh21,Reference Naar, Parsons and Stanton22,Reference Comins, Schwartz and Phetlhu39,Reference Velloza, Poovan and Ndlovu40], physical activity (k = 3) [Reference Gonze, Padovani and Simoes41Reference Simoes, de Barros Gonze and Leite Proenca43], and glycemic management (k = 1) [Reference Corbin, Igudesman and Addala44]. The projects targeting medication adherence were focused on antiretroviral therapy (ART) for human immunodeficiency virus (HIV) [Reference Belzer, MacDonell and Ghosh21,Reference Naar, Parsons and Stanton22,Reference Comins, Schwartz and Phetlhu39] and pre-exposure prophylaxis (PrEP) for HIV prevention [Reference Velloza, Poovan and Ndlovu40]. Of note, alcohol use studies were mostly tested in college populations with an aim of prevention following early warning signs [Reference Borsari, Tevyaw, Barnett, Kahler and Monti25,Reference Borsari, Hustad and Mastroleo26,Reference Lyden, Vock, Sur, Morrell, Lee and Patrick28]. Some smoking cessation and cocaine use projects tested combined behavioral and pharmaceutical stepped-care interventions [Reference Schmitz, Stotts and Vujanovic31,Reference Zhao, Weng and Luk38].

Completed Research

Completed Research Design. Of the 9 projects, 5 were SRTs and 4 were SMARTs. The median [25th, 75th interquartile range (IQR)] sample size of completed research was 136 [55, 500]. All SRTs provided the same intervention to all participants initially and randomized nonresponders to subsequent intervention elements (Table 2). In all completed studies, responders continued the first line of treatment or moved to assessment only but were not randomly assigned. All SMARTs tested personalization[Reference Patrick, Lyden and Morrell18,Reference Gonze, Padovani and Simoes41] and duration to tailoring[Reference McKay, Drapkin and Van Horn30,Reference Sherwood, Crain and Seburg33] in the first randomization and additional resources or swapping to the alternate condition during subsequent tailoring for non-responders.

Table 2. Description of included studies

HIV = human immunodeficiency virus; SMART = sequential multiple assignment randomized trial; BMI = body mass index; HbA1c = hemoglobin A1c; PrEP = preexposure prophylaxis; RCT = randomized control trial; SRT = single randomized trial.

Completed Research Context and Findings. Completed research has tested decision rules for health behaviors including substance use [Reference Patrick, Lyden and Morrell18,Reference Borsari, Tevyaw, Barnett, Kahler and Monti25Reference Breslin, Sobell, Sobell, Cunningham, Sdao-Jarvie and Borsoi27,Reference McKay, Drapkin and Van Horn30], weight loss [Reference Carels, Young and Coit32,Reference Sherwood, Crain and Seburg33,Reference Carels, Miller and Selensky35,Reference Carels, Wott and Young45], and physical activity [Reference Gonze, Padovani and Simoes41]. In general, there were few differences between embedded adaptive interventions in the completed research studies, meaning there were not differential effects found for various treatments or modalities tested. As no completed studies tested tapering, we are unable to draw conclusions about the appropriateness of discontinuing treatment for responders. Furthermore, most studies did not report finding differences among treatment nonresponders who were rerandomized, meaning providing additional or different treatment elements to nonresponders did not change their trajectories [Reference Patrick, Lyden and Morrell18,Reference Borsari, Tevyaw, Barnett, Kahler and Monti25,Reference Breslin, Sobell, Sobell, Cunningham, Sdao-Jarvie and Borsoi27,Reference Carels, Young and Coit32,Reference Sherwood, Crain and Seburg33,Reference Carels, Miller and Selensky35,Reference Gonze, Padovani and Simoes41,Reference Carels, Wott and Young45]. For example, the addition of brief motivational interviewing for nonresponders to brief advice sessions for alcohol misuse did not reduce alcohol consumption [Reference Borsari, Tevyaw, Barnett, Kahler and Monti25,Reference Borsari, Hustad and Mastroleo26]. Therapist-assisted self-help did not outperform self-help, and adding group-delivered behavioral weight loss programing for non-responders did not improve weight loss [Reference Carels, Young and Coit32]. Delivering an alcohol prevention program prior to or during the first semester had similar outcomes [Reference Patrick, Lyden and Morrell18]. However, there were two exceptions: Bosari and colleagues did not find differences on their main outcome of alcohol consumption but did see an effect for reducing number of alcohol-related problems for nonresponders who were randomized to receive additional treatment components [Reference Borsari, Hustad and Mastroleo26]. Additionally, McKay and colleagues found motivational interviewing for intensive outpatient treatment had better outcomes than motivational interviewing for patient choice[Reference McKay, Drapkin and Van Horn30].

Protocols

Protocol Design. All 13 of the protocols described herein employ SMARTs to optimize adaptive interventions, randomizing at least twice during the intervention (Table 2). The median [IQR] sample size of protocols is 400 [190, 800]. Protocols are posing questions during the first phase of treatment regarding modality of delivery or theoretical orientation [Reference Belzer, MacDonell and Ghosh21,Reference Schmitz, Stotts and Vujanovic31,Reference Comins, Schwartz and Phetlhu39,Reference Velloza, Poovan and Ndlovu40,Reference Simoes, de Barros Gonze and Leite Proenca43], benefit of adding treatment to standard care [Reference Germeroth, Benno and Kolko Conlon20,Reference Pfammatter, Nahum-Shani and DeZelar34,Reference Edelman, Dziura and Deng36,Reference Zhao, Weng and Luk38,Reference Buchholz, Wilbur and Halloway42], implementation strategies [Reference Fernandez, Schlechter and Del Fiol37], or duration of time to tailoring [Reference Fu, Rothman and Vock23]. Additionally, most studies are using subsequent randomization for treatment nonresponders. In an effort to enhance effects for treatment non-responders, protocols are testing strategies to include adding incentives [Reference Belzer, MacDonell and Ghosh21], adding human-delivered elements such as calls or counseling [Reference Pfammatter, Nahum-Shani and DeZelar34,Reference Edelman, Dziura and Deng36,Reference Fernandez, Schlechter and Del Fiol37,Reference Buchholz, Wilbur and Halloway42], adding prescription medication [Reference Schmitz, Stotts and Vujanovic31,Reference Edelman, Dziura and Deng36,Reference Zhao, Weng and Luk38], adding texts [Reference Pfammatter, Nahum-Shani and DeZelar34,Reference Fernandez, Schlechter and Del Fiol37,Reference Zhao, Weng and Luk38], adding medication counseling or feedback [Reference Fu, Rothman and Vock23,Reference Velloza, Poovan and Ndlovu40], combining treatments [Reference Comins, Schwartz and Phetlhu39], adding peer elements [Reference Simoes, de Barros Gonze and Leite Proenca43], and adding custom diets [Reference Pfammatter, Nahum-Shani and DeZelar34,Reference Corbin, Igudesman and Addala44]. For example, Bucholz and colleagues [Reference Buchholz, Wilbur and Halloway42] are enrolling 312 inactive women in a SMART aimed to increase physical activity. Initially, all women are provided an enhanced physical activity monitor and are randomized to additionally receive text messages or not. At 8 weeks, women who do not exceed the target step count or had missing data are rerandomized to add personal calls or group meetings while continuing their first-stage treatment. Women who respond to the first stage of treatment as indicated by meeting or exceeding the targe step count continued with their initial treatment assignment.

There are three notable exceptions to the common approach taken by protocols described above. Fernandez and colleagues are cluster randomizing wherein the first-stage clinics are randomized to opt-in or opt-out implementation strategies and patients are randomized at the second stage based on treatment response [Reference Fernandez, Schlechter and Del Fiol37]. Corbin and colleagues randomize participants to one of three diets and rerandomize treatment nonresponders to unassigned diets resulting in participants being exposed to between one and three diets depending on treatment response [Reference Corbin, Igudesman and Addala44]. Finally, Germeroth and colleagues are using a design where everyone is rerandomized, regardless of response status, such that some individuals remain with their original treatment assignment and others swap [Reference Germeroth, Benno and Kolko Conlon20].

Finally, in addition to testing adaptations for treatment nonresponders, Belzer and colleagues [Reference Belzer, MacDonell and Ghosh21], Fu and colleagues [Reference Fu, Rothman and Vock23], and Comins and colleagues [Reference Comins, Schwartz and Phetlhu39] are testing adaptations for treatment responders including tapering vs standard care, decreasing frequency of care, and continuing treatment as assigned vs standard care, respectively.

Protocol Context. Protocols are set to test a variety of health behaviors including smoking cessation [Reference Fu, Rothman and Vock23,Reference Edelman, Dziura and Deng36Reference Zhao, Weng and Luk38], medication adherence [Reference Belzer, MacDonell and Ghosh21,Reference Comins, Schwartz and Phetlhu39,Reference Velloza, Poovan and Ndlovu40], physical activity [Reference Buchholz, Wilbur and Halloway42,Reference Simoes, de Barros Gonze and Leite Proenca43], glycemic management [Reference Corbin, Igudesman and Addala44], weight management [Reference Germeroth, Benno and Kolko Conlon20,Reference Pfammatter, Nahum-Shani and DeZelar34], and cocaine abstinence [Reference Schmitz, Stotts and Vujanovic31]. All protocols are set in outpatient or community settings.

Discussion

Adaptive interventions for health behavior change are a developing area of science. All (but one study) were published in the last 18 years (since 2005) and the majority (73%; 19/26) were published in the last 5 years (since 2018). Optimization methods for adaptive interventions have recently gained traction. Given the time needed to procure grant funding and publish results, more research in this area is expected soon. Indeed, this review found more studies as protocols than completed work, highlighting the infancy of this field and the promise of more information coming. Of note, SRTs were present in completed studies but not in protocols, likely due to the availability of a more novel trial design (SMART) better suited to answer questions about adaptive interventions with repeated opportunities for randomization. It is therefore likely that uptake of these methods will continue to increase. Our review can inform this uptake; therefore, we make the following commentary on design and contextual considerations.

Design Considerations

Intermediary tailoring was ubiquitous among reviewed studies, mostly focusing on treatment nonresponse defined by progress toward the primary outcome. Models of adaptive interventions have suggested using known treatment mediators or proximal outcomes to inform intermediary tailoring [Reference Collins, Murphy and Bierman10]. It is possible these approaches are not being utilized as strong treatment mediators are difficult to identify, or because health behaviors themselves are often the proximal outcomes in relation to more distal outcomes of clinical indicators, morbidity, and mortality. One study used engagement as the intermediary tailoring variable [Reference Fernandez, Schlechter and Del Fiol37], and this approach could likewise be used in future trials.

A minority of studies are systematically testing intervention reductions for treatment responders. These questions have important implications for the cost-effectiveness of interventions, namely providing enough resources to achieve the desired outcomes without providing additional unnecessary resources. Continuing to test tapering or stepping down care for treatment responders is an important question to consider in future work.

There is a paucity of research testing baseline tailoring variables. In the future, it may be useful to explore tailoring at baseline where individuals are receiving a first-stage treatment that is likely to be effective for them. The literature can help to generate hypotheses about which treatment may be best for a particular individual or subgroup. Variables that moderate fixed interventions may be informative for identifying baseline tailoring variables to test. However, it may be that a cluster or composite of variables create a behavioral phenotype (rather than a single variable) that would be predictive of treatment success. In fact, there is emerging work identifying associations between clusters of lifestyle risk factors and overweight/obesity [Reference Liberali, Del Castanhel, Kupek and Assis46] as well as typologies of family functioning related to depressive symptoms for patients with heart failure [Reference Bouldin, Aikens, Piette and Trivedi47] and self-management and psychosocial well-being for adults with type 2 diabetes [Reference Mayberry, Greevy, Huang, Zhao and Berg48]. An interesting future direction for this work would test these typologies or behavioral phenotypes as predictors of treatment outcome and potentially used as tailoring variables in the future.

One novel study described here by Fernandez and colleagues is combining implementation methods with adaptive methods [Reference Fernandez, Schlechter and Del Fiol37]. Developing stepped care interventions that are ready to be implemented holds promise, and future work in adaptive methods could contain more implementation methods and measures in order to ready these interventions for uptake in the real world.

Contextual Considerations

The most frequent health behaviors to be tested in optimizing adaptive methods were substance use, weight management, and tobacco cessation. It is logical these were some of the first health behaviors targeted by these methods due to modest effect sizes [Reference Franz, VanWormer and Crain4,Reference Dansinger, Tatsioni, Wong, Chung and Balk49] and high rates of relapse [Reference Panel50]. In fact, a prior systematic review on stepped care interventions for alcohol and tobacco cessation identified a number of interventions being tested [Reference Jaehne, Loessl, Frick, Berner, Hulse and Balmford14]. Likewise, a previous review of adaptive interventions (including JITAI) for weight loss or sedentary behavior identified eight adaptive interventions which showed initial promise for JITAI to reduce sedentary behaviors [Reference Miller15], but to our knowledge these studies largely have not been replicated. More recent efforts include these domains as well as expanding into medication adherence, physical activity, glycemic management, and cocaine abstinence. More research is needed in these and other areas. Adaptive interventions for medication adherence are currently only being tested with adults with HIV and in the prevention of HIV (PrEP) [Reference Belzer, MacDonell and Ghosh21,Reference Comins, Schwartz and Phetlhu39,Reference Velloza, Poovan and Ndlovu40]. Opportunities for medication adherence interventions for adults with chronic diseases such as type 2 diabetes, heart failure, or chronic kidney disease could benefit from their learnings and further these methods. Additionally, interventions that target multiple self-management behaviors such as medication adherence as well as healthy diet, exercise, and stress management could be applicable to multiple chronic disease contexts. There is opportunity to test an adaptive, trans-diagnostic self-management intervention across multiple disease contexts.

In addition to continuing to explore individual variables to use as baseline and intermediary tailoring variables, optimizing adaptive interventions could investigate factors external to the individual to inform optimization of adaptive interventions. Understanding the larger context in which adults are making health behavior changes could further match interventions to individuals in order to maximize effects and enhance engagement. For example, the social context in which adults are making behavior changes could inform which type of intervention is offered (i.e., individual or family). Alternatively, the environment in which adults are making behavior change (i.e., proximity to community health centers) could inform the delivery modality (i.e., in-person or telehealth). Health behavior changes occur in the daily lives and environments of adults seeking to implement them. Finally, all studies reviewed here occurred in the outpatient or community setting. Given the ability of adaptive interventions to change the course of treatment over time, there is opportunity to recruit participants and/or test adaptive interventions in-patient as well as through transitions of care.

Early Findings Considerations

There are a few key learnings from the findings of completed research studies. First, most did not find differential benefit from adaptations tested. Health behavior change is difficult historically, and that trend continues here. However, the number of decision rules available to be tested is nearly limitless. More work is needed to understand what adaptations are needed for whom. Second, the samples in which these studies were conducted were majority non-Hispanic white. More diversity is needed in the samples used to develop adaptive interventions. Third, several completed research studies had small or moderate sample sizes. Finally, there may be characteristics of individuals that inform intervention readiness or motivation that could be used as baseline tailoring variables to match intervention to person and tailor interventions. Continued intervention optimization could untangle these questions.

Limitations and Future Directions

Despite the thorough search strategy used, some work optimizing adaptive interventions for health behavior change may have not been identified and omitted from this review. Specifically, we did not search for dissertations or other unpublished documents on this topic. Given the early stage at which this area of research is currently situated, future work will be needed to update the results described here. Due to the wide variety of health behaviors targeted, variety of decision rules tested, and limited number of studies with results, we were unable to complete a meta-analysis. No studies employed factorial designs when testing aspects of decision rules; however, this presents an area of opportunity in the future.

Studies were limited to using two research trial designs: the SRT and the SMART. While SMART lends itself well to testing specific questions regarding the decision rules used to adapt an intervention, other trial designs could be a better fit depending on the research question. For example, if multiple intervention components need testing alongside a single point of adaptation, a factorial trial might be a better option. For example, a factorial trial can answer questions about an adaptation such as adding a component or not after a time of nonresponse while simultaneously testing components to add to a constant intervention component. In this situation, one of the factors to be tested could be adding a coach at the midpoint for nonresponders. This factor could have two levels (yes/no) and groups in the “yes” level would add a coach for nonresponders at the midpoint, while groups in the “no” level would not. Additionally, there are emerging methods for hybrid experimental designs – combining stepped care adaptations with dynamic adaptations for interventions that adapt at multiple timescales [Reference Nahum-Shani, Dziak, Walton and Dempsey11]. As health behavior intervention science progresses, we expect that more designs will be used to optimize interventions in various ways.

Despite these limitations, to our knowledge this is the first systematic review to highlight the application of optimizing adaptive interventions for health behavior change, broadly. Given the nascency of the field, looking across health behaviors rather than focus on a particular behavior or disease context allows us to learn from a variety of well-designed studies.

Conclusions

Behavior change interventions have had small average effects historically [Reference Webb, Joseph, Yardley and Michie3]. These novel designs can help us test adaptations of treatments to be a better fit across the board thereby increasing effects and having positive outcomes for more of the population. Additionally, focusing efforts on improving effects for individuals who have not benefited from interventions historically serves to improve the equity of this work as well as boost the overall or average effect sizes of interventions. Methods for optimizing adaptive interventions are being applied to interventions for health behavior change. There are several published examples and more protocols that will soon have results to add to the field. Opportunities for future research are abundant including identifying and testing baseline tailoring variables, applying the methods to additional health behaviors and target populations, rigorous testing of tapering interventions for treatment responders, and considering adults’ context or modality of delivery when adapting interventions.

Acknowledgments

The content is solely the responsibility of the authors and does not necessarily represent the official views of the NIH.

Funding statement

MKR is supported by the Vanderbilt Faculty Research Scholars. AFP is funded by the National Institute of Diabetes and Digestive and Kidney Diseases of the National Institutes of Health (NIH; R01DK125749).

Competing interests

The authors have no conflicts of interest to declare.

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Figure 0

Figure 1. Systematic review inclusion flow diagram.

Figure 1

Table 1. Characteristics of included studies (k = 22)

Figure 2

Table 2. Description of included studies