Introduction

Lumbosacral radiculopathy is one of the leading complaints evaluated by interventional pain physicians and spine surgeons alike [1]. Caused primarily by degenerative spondylosis with stenosis due to disc and/or bony sources [2], lumbar radiculopathy is characterized by pain in the lower back which radiates down to one or both legs. Compared to patients who have LBP without radiculopathy, those who also report radiculopathy have more severe pain intensity, increased somatosensory abnormalities, and more pronounced loss of small fiber function [3]. While prevalence estimates range from 3–5% of the general population, back pain with a radicular component accounts for a disproportionately high amount of the associated financial care costs; the average costs associated with an individual suffering from neuropathic back pain is 67% higher than that of a patient with nociceptive back pain only [4]. Lastly, lumbosacral radiculopathy is associated with high rates of disability [5] and decreased quality of life [6].

Epidural steroid injection (ESI) is the most common outpatient procedure performed for the treatment of spinal pain [7, 8], and it involves injecting one or more anti-inflammatory medications directly in the epidural space surrounding spinal nerves to address related neuropathic pain. Particularly for patients with radicular pain who have not responded to other moderate approaches, ESIs are increasingly being utilized. Between 2000 and 2011, ESI utilization grew 665% among Medicare beneficiaries alone [9]. Despite the dramatic increase in ESI utilization, important controversies remain with regard to efficacy within certainly sub-populations of patients with chronic LBP [10, 11] and cost-ineffectiveness [12]. Specifically for long-term pain improvement, past research is mixed with regard to the durability of the effect of ESIs, which must, at minimum, be repeated periodically to re-instate pain relief [13–20]. When pain relief is not achieved or sustained, some patients undergo repeat procedures or delay surgical interventions, depending on the etiology of lumbosacral radiculopathy, which results in additional utilization of health care resources [21, 22]. While ESIs are generally considered to have a favorable safety profile when performed according to clinical practice guidelines [23, 24], particularly when compared to opioid pain medications and surgery, they do carry potential risks including infection, spinal fluid leak, and other rare but non-trivial complications [25–27].

Concerns about the long-term efficacy and/or need for ongoing repeat ESIs in specific sub-populations coupled with the cost considerations and potential side effects of such procedures highlight the need for further understanding of the factors that influence patients’ response to ESIs. To date, research examining predictive factors for ESI response has focused heavily on electrodiagnostic [28–30] and imaging variables [31, 32], as well as route of injection [33], and agents injected [18, 19, 34, 35]. A large body of research consistently links psychosocial functioning with chronic pain intervention outcomes in general [36, 37], but there is scant research examining psychological factors as predictors of ESI outcomes despite promising studies published for other pain procedures. Studies on back surgery, for example, demonstrate that psychosocial variables play a critical role in how CLBP patients respond to surgical interventions. A recent review of 96 articles reported that among patients undergoing spine surgery, those with underlying psychological disease have longer hospital stays and higher rates of re-admission [38]. Other back surgery studies have shown that anxiety is associated with worse post-operative pain [39], depression increases the incidence of neurological complications and failed back surgery syndrome [40], and psychological distress predicts more severe post-operative disability [41]. Conversely, both pre-intervention [42, 43] and post-intervention [39] improvements in psychological distress are associated with better back surgery outcomes, so better understanding of psychosocial factors predicting ESI outcomes could lead to better treatment response with ESI.

Psychosocial factors may help explain differences in ESI response, however, these factors are infrequently studied and there is little consensus on their role in ESI. Thus, the purpose of this scoping review is to examine literature on the treatment response to ESI in individuals with LBP with or without lumbosacral radiculopathy, describe current knowledge about psychosocial factors and the role they play in ESI treatment response, note gaps in the literature, and discuss implications for future research.

Methods

The present review followed the methodological procedures outlined by the Preferred Reporting Items for Systematic Reviews and Meta- Analysis Extension for Scoping Reviews [PRISMA-ScR] framework [44]. Scoping reviews are the preferred methodology when the objectives of the research involve determining the extent, range, and nature of the empirical evidence concerning a topic, along with identifying gaps in the literature [44]. Given our aims of examining the ESI literature for any evidence of the role that psychosocial factors play in treatment response, describing the expected weak state of this literature, and noting any significant gaps, scoping review is the ideal method. The literature search was performed electronically using relevant databases: PubMed, CINAHL, Scopus, PsycINFO, and Google Scholar. The search strategy, which was completed in September 2023, was developed iteratively by the research team in conjunction with an experienced health sciences librarian and encompassed both Medical Subject Headings terms and text words. The objective of this search was to capture studies reporting pain outcomes following ESI for the treatment of chronic LBP with or without lumbosacral radiculopathy, and which also included a focus on psychosocial factors.

Throughout the entire process of the scoping review, including screening, selection, and data extraction, six authors worked in dyads, such that three experienced pain researchers/faculty members were each paired with three PhD psychology interns, respectively. During the initial screening, each individual reviewed the title and abstracts of the articles independently. Next, each dyad met to compare and contrast screening decisions and rationales. In the event there was disagreement between the two dyad members, they worked collaboratively to examine and explain each person’s respective decision. This included reading the abstract together and discussing the basis for one’s opinion. If, after this discussion, the disagreement was not resolved, the issue was then brought to the whole group of six authors. This same process was followed for the full-text review phase. Any disagreements on the inclusion of studies were resolved through consensus as a group, wherein the authors met together, discussed rationales for their opinions, and adjudicated any disagreements. Had the authors continued to disagree, a qualified third-party individual would have been invited to consult.

Inclusion criteria for the review were as follows: collection of empirical data on ESI, the ESI is for the treatment of neuropathic pain related to the lower back (lumbosacral) region, both pre-injection and post-injection pain intensity scores are reported, at least one psychosocial measure reported, any age range for sample, any timeframe for publication date, published in English, and full text available. For this search, “psychosocial variable” meant any measure related to the following factors: anxiety, depression, affect, quality of life, sleep/insomnia, stress, mood, outcome expectancy, self-efficacy, and essentially any DSM-V condition. We chose these specific operational definitions of “psychosocial variables” because they can be easily assessed, are relevant to pain experience, and are modifiable (i.e., can be changed pre-ESI with some intervention). Exclusion criteria included the following: qualitative studies, review papers, animal or cadaver studies, studies that only examined ESI in combination with another intervention (e.g., medication, physical rehabilitation, educational intervention, etc.), studies that assessed an epidural injection without steroid, ESI for pain in the cervical or thoracic regions rather than the lower back, studies that did not have both pre and post-injection pain scores, and, most importantly, a lack of psychosocial measure(s) reported (See online Supplementary material file S1 File for full search strategy).

The first author developed a standardized data form for this review that facilitated the process of systematically extracting data from the included articles. The following data points were extracted: publication year, sample size, participants’ average age and standard deviation, proportion of male vs female, study design, route of epidural steroid injection, psychosocial variable(s) reported, pain measures, and relationship between psychosocial variables and pain. In cases where the study did not provide the mean age, the median or range was instead reported with estimated variances [45]. For studies that provided separate means and standard deviation for each treatment group (without a summary for the combined sample), the pooled average and standard deviation were reported. The extraction of data also followed the procedures previously outlined, such that it was first done independently, then discussed among the dyads, and then brought to the group as a whole on an as-needed basis. Study quality was assessed using the standardized Delphi list [46].

Results

From the initial search, a total of 544 articles were identified prior to de-duplication: PubMed (195), Scopus (262), Google Scholar (42), CINAHL (36), PsycINFO (9). After duplicates were removed, a total of 356 articles were identified, and the title/abstracts were reviewed to assess suitability for full-text review. Following this step, a total of 106 full text articles were retrieved and assessed for relevance. Articles were excluded for a variety of reasons, including a focus on a spinal procedure other than ESI, a lack of psychosocial variables included, and the fact that pain was not an assessed outcome variable. Because the focus of this study was on chronic LBP and lower extremity radiculopathy, studies on ESIs for non-back pain (e.g., cervical or thoracic pain) were also excluded. Studies which examined ESI in combination with a different interventional procedure rather than ESI alone were also excluded, to avoid confounding findings. Ultimately, 51 studies met the inclusion criteria and were included in the present scoping review (see Fig 1).

[Figure omitted. See PDF.]

Study characteristics

The 51 included studies ranged in sample size from 12 to 5,104 totaling 10,447 participants. More than half of the studies (n = 27) reported an average (or median) sample age ≥ 50 years old. The following conditions were reported as the chief pain complaint: lumbar disc herniation, spinal stenosis, degenerative disc disease, nonspecific lower back pain, lumbosacral radiculopathy, sciatica, spondylolisthesis, and post-laminectomy syndrome. Studies implemented a variety of empirical research designs (see Table 1), including: Prospective observational (n = 27), Randomized controlled trial (n = 17), Retrospective observational (n = 4), and Other (n = 3). Routes of administration (type of injection) reported in the 51 studies included transforaminal (n = 16), interlaminar (n = 8) and caudal (n = 5), with n = 15 studies examining multiple injection routes and n = 7 that did not clearly report route of administration. The post-injection follow-up timepoints ranged from 15 minutes after the ESI was administered to 24 months post-injection.

[Figure omitted. See PDF.]

Psychosocial variables

A total of 19 different psychosocial variables were represented amongst the N = 51 included studies. Despite a large variety of variables represented, three constructs were most used: depression (n = 27), anxiety (n = 14), and quality of life (n = 10). Eight of the psychosocial variables identified in this scoping review were only examined in a single study (see Table 2).

[Figure omitted. See PDF.]

While it was common for studies to utilize validated instruments to measure their psychosocial variables, unvalidated approaches were used in some cases, such as rating one’s own mental health on a basic, novel numeric rating scale or simply answering “Yes or No” rather completing a validated scale. Also, certain psychosocial variables were pulled from patients’ medical charts rather than being patient-reported directly. Further, some studies reported their data in a way that prevented them from being meaningfully analyzed. Examples of this issue ranged from stating that a psychosocial construct was administered but then never reporting any of the values for the measure, to reporting a composite score of many different factors, but not specifying the psychosocial subscale values.

Relationship between psychosocial variables and post-injection pain severity

Of the 51 studies included in this review, a total of only 10 studies analyzed and reported on the relationship between at least one pre-injection psychosocial variable and post-injection pain at any follow-up timepoint. The longest duration of follow-up among these 10 studies was a 12-month post-injection timepoint. The extracted data from these 10 studies are summarized below in Table 3, and the summary table of the other 41 studies can be found online (see Supplementary S1 Table) [12, 16, 21, 47–84]. It should be noted that these other 41 studies reported on psychosocial variables but did not include any analyses explaining how the psychosocial variable is related to post-injection pain (the primary outcome of this review). Accordingly, this means that the large majority of the included studies collected patient-reported scores on psychosocial measures but did not include any of these variables as predictive factors for post-injection pain.

[Figure omitted. See PDF.]

Among the 10 main studies [85–94], there were a total of 28 instances in which a pre-injection psychosocial variable was analyzed in relation to post-injection pain, with the following results: n = 14 cases of worse psychosocial functioning being associated with worse pain; n = 0 cases of worse psychosocial functioning being associated with improved pain; and n = 14 cases in which psychosocial functioning and pain did not have a statistically significant relationship. Depression was directly analyzed in relation to pain in six studies; four of them found that more severe depression is associated with more severe pain or, inversely, smaller pain reductions [85, 86, 91, 94]. The other two studies found that the depression-pain relationship was not statistically significant [88, 92]. Anxiety was found to be not statistically significant in relation to pain for all three instances in which it was analyzed [85, 87, 94]. Both of the studies that examined sleep as a predictor of pain reported that sleep disturbance results in significantly smaller pain improvements at follow-up [86, 90]. Somatization variables were analyzed in relation to pain twice, with one study finding that greater somatic perception predicted higher pain scores at follow-up [88], and the other study reporting non-significance [85]. Both higher quality of life [93, 94] and health-related quality of life [89] are associated with lower pain scores. Of the three studies that examined pre-injection treatment expectations in relation to post-injection pain, one found that more favorable outcome expectations were associated with lower pain intensity at two weeks for female patients [87], while the other two studies reported non-significance between these two variables [86, 94]. Regarding prior opioid use, both studies that examined its use in relation to pain reported non-significance [86, 89].

Seven pre-injection psychosocial variables were analyzed in relation to post-injection pain on only one occasion. The following variables were found to be predictive of worse pain at follow-up: substance abuse [86], presence of any psychiatric condition [86], and maladaptive pain coping [87]. The following variables were found to be not significantly related to pain at follow-up: psychological distress [88], negative affect [90], pain catastrophizing [94], and fear avoidance [94].

It is important to note that while eight of these 10 main studies explicitly noted that the aim of the research was, at least in part, to examine pre-procedural patient-level individual or clinical characteristics (i.e., psychosocial variables) as predictors of ESI response, only two [86, 94] of these eight studies included an explicit explanation about having sufficient statistical power to address such an aim; these studies found that depression, insomnia, substance abuse, presence of any psychiatric condition, and low quality of life are all predictive of smaller pain reductions or treatment failure at follow-up after ESI. Regarding the measure of post-injection pain among these studies, the most common pain measures were Visual Analog and Numeric Pain Rating, both of which are validated, reputable measures for pain [95]. One study [90], however, used an unvalidated measure that was vaguely described as a “global report of back and/or leg pain.” It may be noted that the investigators examined and extracted a key procedural variable for this scoping review, type of injection (transforaminal, interlaminar, and caudal), however, there was no evidence from the reviewed studies showing an interaction between injection type and psychosocial variables (i.e., the role of depression symptom severity in outcomes of transforaminal versus interlaminar ESI) in their analyses of ESI outcomes.

Study quality

The quality of the 10 studies that reported on the relationship of a pre-injection psychosocial variable with post-injection pain severity outcomes is presented in Table 4. Of these studies, only one was graded as a high quality randomized controlled trial [93]. There was one moderate quality wait list control group study [92], and the remaining eight trials were of lower quality (not highly controlled) prospective observational trials. These findings support the need for higher quality randomized controlled replication trials of ESI that include both pre-injection assessment of psychosocial variables and post-injection pain rating outcomes to develop reliable predictive models.

[Figure omitted. See PDF.]

Discussion

This scoping review is the first study to comprehensively examine the empirical literature on the relationship between psychosocial variables and ESIs and for the treatment of chronic LBP with or without lumbosacral radiculopathy. A large body of research attempting to describe if patients achieve significant pain relief following ESI has been amassed over the last several decades, yet our review identified only 10 studies that explicitly analyzed the psychosocial-pain relationship in this context. Despite the field’s leading theoretical framework, the biopsychosocial model of pain [96], explicitly naming their importance, psychosocial variables appear to be only marginally represented in the ESI literature. This runs counter to a large body of past research consistently linking psychological factors with chronic LBP, including prevalent psychiatric co-morbidities [97] and maladaptive thinking patterns and behaviors tied to pain chronicity [98]. We argue that the gross underrepresentation of psychosocial factors in research on ESI, the most common outpatient procedure performed for back pain, is a critical oversight. As it stands, estimates of ESI efficacy are based on misspecified or incomplete models; the omission of important psychosocial variables likely introduces bias and skews the estimated effect of other predictors, thus failing to accurately capture the real relationship between the ESI procedure and patients’ treatment response. Our findings highlight a potential missed opportunity in understanding ESI treatment response (or non-response) and establishing screening or intervention methods to address psychosocial factors that could maximize ESI outcomes.

Amongst the 51 studies included in the present review, a total of 19 different psychosocial variables were identified. Depression, anxiety, and quality of life were the three most commonly used constructs. However, only roughly half of all the studies included in the review included a measure of depression (even fewer for anxiety) despite the availability of brief assessment options for these constructs and their broadly recognized importance in the field [99]. The 10 studies that analyzed and reported on the relationship between pre-injection psychosocial variables and post-injection pain at any follow-up timepoint indicated that poor psychosocial functioning was associated with worse ESI outcomes n = 14 cases and improved pain in n = zero cases; in n = 14 cases, psychosocial functioning and pain did not have a statistically significant relationship. While the reason for statistical insignificance varies by study, we point to instances of small sample size [87, 89, 92], use of invalidated or unknown measures (i.e., failure to report how something was measured [85], and poor methodological study quality. Most studies that examined a direct relationship specifically between depression and post-treatment pain outcomes showed significantly less pain improvement after ESI in individuals with greater depression symptoms. Only two studies did not find a relationship between depression and pain outcomes after ESI. However, one of these studies had a small sample size (N = 36), which may explain the lack of statistical significance observed. No study observed a relationship between poor psychosocial functioning and improved pain relief post-injection. Collectively, these findings suggest that the psychological state in which patients present to the clinic for their ESI may have important implications on their pain outcomes and considerations for treatment selection as well as concomitant psychosocial and medical interventions.

The consideration of psychosocial factors in interventions performed for chronic LBP is not a new concept. ESIs in their different approaches are the most commonly performed outpatient procedure for LBP with radiculopathy [100], but they are not the only intervention performed for this purpose. Spinal cord stimulation (SCS) is an additional, albeit more invasive and costly, procedural intervention often used in refractory cases of back pain, as well as other painful conditions. The relationship between psychosocial factors and SCS outcome has been extensively described and is compelling enough to lead many clinical services and third party payors to require psychological screening and evaluation as a prerequisite to be considered for this intervention [101–104]. Likewise, the spinal surgery literature has also made strides in accounting for psychosocial factors on surgical outcomes, demonstrating that greater presence of pre-surgical anxiety, depression, and psychological distress limit positive back surgery outcomes for CLBP patients specifically [39–41]. Pain outcomes related to psychosocial variables among SCS and surgical patients may provide a useful framework for which psychosocial variables to further study in the context of ESI response. Specifically, we recommend that the following psychosocial factors (and corresponding validated assessment tools) be considered in future work: depression (PHQ-9), anxiety (GAD-7), pan catastrophizing (PCS), and fear avoidance (FAB-Q). Not only are these variables consistently correlated with pain outcomes, but their inclusion across studies will facilitate future comparisons and synthesis of findings while likely strengthening predictive models by accounting for previously ignored mechanisms of response.

Given that the majority of the reviewed studies in this paper included no analysis of the relationship between psychosocial variables and post-injection pain, it is important to consider possible reasons for this underrepresentation of psychosocial factors. Historically, there has been an inherent bias in the medical research community whereby biological and physical factors are prioritized over psychological and social factors [105, 106]. It is only recently that biostatistical and theoretical frameworks have evolved to account for psychosocial functioning [107, 108]. It may also be noted that, by and large, research on ESIs is typically conducted by medical doctors who perform this procedure in their pain practice. It is possible that physicians’ greater experience with procedural relative to psychosocial variables, and possible motivation in some cases to demonstrate efficacy of the procedures they routinely perform, are driving the underrepresentation. Methodological challenges likely also impact the underrepresentation of psychosocial variables in ESI research. For example, psychosocial assessments may not be routinely performed in clinical pain management settings [109], so clinical datasets may not typically contain in-depth psychosocial measures. Thus, these assessments should be added into the normal flow of care prospectively, unlike procedural variables that occur as part of the routine ESI process (e.g., imaging, needle placement, etc.). The psychosocial assessments, depending on what is being administered, may be lengthy and consume a considerable amount of time; this can potentially introduce logistical challenges or cause assessment burden for the patients, the latter of which may increase risk of study attrition. However, recently evolutions in psychosocial assessment have led to much briefer options (cf. PHQ-4) [110]. In conclusion, we surmise that researcher biases, methodological challenges, and lack of behavioral investigators in this area are driving the underrepresentation of psychosocial factors in ESI research. It is our hope that future research will trend in the right direction and increasingly recognize the predictive value of including psychosocial assessments in ESI research, and, eventually, clinical care.

In line with the biopsychosocial model of pain, our review highlights the increasing need for research on individual differences that explain ESI patient outcomes, particularly in light of the documented variability and mixed findings regarding ESI effectiveness [13–16]. We highly encourage researchers to include assessments of psychosocial factors in future studies so that these critical variables can be appropriately included in statistical models of ESI treatment response. The inclusion of psychosocial variables in future ESI research supports precision medicine and could have a large impact on research and patient care [111]; equipped with an improved understanding of individuals’ likelihood of responding favorably to ESI, we can ensure those who are most likely to respond favorably receive the treatment, help connect those least likely to respond favorably to alternative therapies, and lower the rate of adverse events. Future studies may benefit from examining the role of potentially modifiable psychosocial outcomes, such as quality of life and mental health, on ESI outcomes. Additionally, these studies must be designed in such a manner and properly powered to ensures that the psychosocial variables are robustly tested as predictors. Understanding the impact of these psychosocial factors on pain outcomes is crucial for developing comprehensive treatment approaches that address both the physical and psychological aspects of back pain. Future research may also consider exploring the potential moderating and mediating roles of psychosocial factors in the relationship between ESI and pain relief. Additionally, investigating the mechanisms through which psychosocial variables affect ESI pain-related outcomes could provide valuable insights for clinical practice and the mechanisms of pain.

Because many of the discussed psychosocial variables are modifiable, it may be plausible that implementing a brief pre-injection intervention would increase a patient’s chance of responding well to ESI. This intervention could be rooted in cognitive-behavioral therapy, mindfulness, or relaxion techniques, all of which have shown promise in addressing the psychosocial factors covered in this scoping review [112–114]. With this approach, we can increase the volume of patients who benefit from the most commonly-performed outpatient back procedure in the United States, thereby optimizing patient care.

While we did not include self-reported disability in the present review, we note the importance of the field recognizing this important variable as a psychosocial predictor of ESI response in future research. The concept of disability itself is a subjective, socially-determined notion that can fluctuate over time [115]. Furthermore, self-reported disability is different than an objective physical test of functioning, as it simultaneously captures perceptions of one’s physical aspects, but also subjective appraisal of one’s emotional well-being [116]. Past research shows that self-reported disability is both highly-correlated with [117] and mediated by [118] psychosocial variables relevant to chronic pain. Understanding how patients perceive their own degree of pain-related disability may provide important psychosocial insights into the nature of their ESI response.

Limitations

Although the PRISMA-ScR guidelines for scoping reviews were followed, [44] there are several limitations to note in the present study. Because the review was limited only to studies published in English, the comprehensiveness of the findings may be impacted. The authors presented a descriptive summary of the findings that does not explain the relationships, causes, or effects of findings. Furthermore, this scoping review included heterogeneous studies that utilized various interventions and assessment tools as well as heterogeneous samples, all of which may impact the interpretation of findings. The data extraction process is inherently subject to the possibility of selection bias, however, this was diminished via the use of a systematic approach and multiple authors reaching consensus on all decisions.

Conclusion

ESI is the most common outpatient pain management procedure used for the treatment of LBP with or without lumbosacral radiculopathy, however, there are controversies regarding its efficacy when used within specific sub-populations. In order to better understand why results may vary, it is necessary to gain insight into what factors may affect patients’ response to ESI. Although studies on surgical procedures have supported the significance of psychosocial factors in treatment outcome, the existing literature on ESI has not sufficiently addressed the predictive role of pre-treatment psychosocial variables on treatment outcomes. The current findings highlight the need for further investigation of these variables in better understanding patients’ treatment response to ESI.

Supporting information

S1 Checklist. Preferred Reporting Items for Systematic reviews and Meta-Analyses extension for Scoping Reviews (PRISMA-ScR) checklist.

https://doi.org/10.1371/journal.pone.0316366.s001

(DOCX)

S1 Table. Additional studies.

Characteristics of studies that report on psychosocial variable(s) but did not include any analyses explaining how the psychosocial variable(s) are related to main outcome of post-injection pain (N = 41).

https://doi.org/10.1371/journal.pone.0316366.s002

(DOCX)

S1 File. Search syntax.

Review strategy by database.

https://doi.org/10.1371/journal.pone.0316366.s003

Acknowledgments

We wish to sincerely thank Chris Gaspard, health sciences librarian, for her expertise and assistance provided during the literature search phase. Her support for the study was instrumental to its successful completion.

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Citation: Stensland M, McGeary D, Covell C, Fitzgerald E, Mojallal M, Lugosi S, et al. (2025) The role of psychosocial factors in mediating the treatment response of epidural steroid injections for low back pain with or without lumbosacral radiculopathy: A scoping review. PLoS ONE 20(1): e0316366. https://doi.org/10.1371/journal.pone.0316366

About the Authors:

Meredith Stensland

Roles: Conceptualization, Data curation, Investigation, Methodology, Project administration, Supervision, Writing – original draft, Writing – review & editing

E-mail: [email protected]

Affiliation: Department of Psychiatry and Behavioral Sciences, University of Texas Health Science Center at San Antonio, San Antonio, TX, United States of America

ORICD: https://orcid.org/0000-0002-5829-5580

Donald McGeary

Roles: Conceptualization, Data curation, Investigation, Project administration, Supervision, Writing – original draft, Writing – review & editing

Affiliations: Department of Psychiatry and Behavioral Sciences, University of Texas Health Science Center at San Antonio, San Antonio, TX, United States of America, South Texas Veterans Health Care System, San Antonio, TX, United States of America, Department of Psychology, University of Texas at San Antonio, San Antonio, TX, United States of America

Caleigh Covell

Roles: Conceptualization, Data curation, Writing – original draft, Writing – review & editing

Affiliation: Department of Psychiatry and Behavioral Sciences, University of Texas Health Science Center at San Antonio, San Antonio, TX, United States of America

Elizabeth Fitzgerald

Roles: Conceptualization, Data curation, Writing – original draft, Writing – review & editing

Affiliation: Department of Psychiatry and Behavioral Sciences, University of Texas Health Science Center at San Antonio, San Antonio, TX, United States of America

Mahsa Mojallal

Roles: Conceptualization, Data curation, Writing – original draft, Writing – review & editing

Affiliation: Department of Psychiatry and Behavioral Sciences, University of Texas Health Science Center at San Antonio, San Antonio, TX, United States of America

Selena Lugosi

Roles: Writing – review & editing

Affiliation: School of Medicine, University of Texas Health Science Center at San Antonio, San Antonio, TX, United States of America

Luke Lehman

Roles: Writing – review & editing

Affiliation: Department of Rehabilitation Medicine, University of Texas Health Science Center at San Antonio, San Antonio, TX, United States of America

Zachary McCormick

Roles: Writing – review & editing

Affiliation: Department of Physical Medicine and Rehabilitation, University of Utah School of Medicine, Salt Lake City, UT, United States of America

Paul Nabity

Roles: Conceptualization, Data curation, Methodology, Writing – original draft, Writing – review & editing

Affiliations: Department of Psychiatry and Behavioral Sciences, University of Texas Health Science Center at San Antonio, San Antonio, TX, United States of America, South Texas Veterans Health Care System, San Antonio, TX, United States of America