|Home | About | Journals | Submit | Contact Us | Français|
To determine whether combat-acquired traumatic brain injury (TBI) is associated with post-deployment frequent binge drinking among a random sample of active duty military personnel (ADMP).
ADMP who returned home within the past year from deployment to a combat theater of operations and completed a survey health assessment (N = 7,155).
Cross-sectional observational study with multivariate analysis of responses to the 2008 Department of Defense Survey of Health Related Behaviors among Active Duty Military Personnel, an anonymous, random population-based assessment of the Armed Forces.
Frequent binge drinking: five or more drinks on the same occasion, at least once per week, in the past 30 days. TBI-AC: self-reported altered consciousness only; loss of consciousness of less than 1 minute (TBI-LOC<1); and LOC of 1 minute or greater (TBI-LOC 1+) after combat injury event exposure.
Of ADMP who had a past year combat deployment, 25.6% were frequent binge drinkers and 13.9% reported experiencing a TBI on the deployment, primarily TBI-AC (7.5%). In regression models adjusting for demographics and positive screen for posttraumatic stress disorder, ADMP with TBI had increased odds of frequent binge drinking compared to those with no injury exposure or without TBI: TBI-AC (AOR 1.48, 95% CI, 1.18–1.84); TBI-LOC 1+ (AOR 1.67, 95% CI, 1.00–2.79).
TBI was significantly associated with past month frequent binge drinking after controlling for posttraumatic stress disorder, combat exposure, and other covariates.
Unhealthy alcohol use is common and persistent among military personnel returning from the conflicts in Iraq and Afghanistan, with a consistent association of deployment and combat exposure to unhealthy alcohol use1–9. One-third of military personnel in 2008 reported drinking at or above hazardous drinking levels, including five percent who met screening criteria for possible alcohol dependence10. These trends are even more apparent among younger enlisted military personnel11,12. Annual prevalence of monthly binge drinking (five or more drinks on one occasion for men, four or more drinks for women) among military personnel and their civilian counterparts who are 21 to 25 year olds were 60% vs. 46% and among 17 to 20 year olds were 44% vs. 33%11,13. A recent study comparing drinking behaviors of male military personnel to those of civilians found that both the number of combat traumas and positive screens for probable post-traumatic stress disorder (PTSD) or depression were associated with increased frequency of binge drinking among male military personnel9.
Binge drinking is associated with numerous negative consequences for both civilians and military personnel - alcohol-impaired driving1,13–15, criminal violations13,16, and military-specific job-performance problems13,17, all of which limit the Department of Defenses’ (DOD) ability to promote the force readiness of its troops1,13,18,19. A recent analysis of the 2008 Department of Defense Health Related Behaviors among Active Duty Military Personnel Survey found that frequent binge drinkers (defined in that report as those who binge drink at least once a week in the past month) reported almost three times the rate of alcohol-related serious consequences and over twice the rate of alcohol-related productivity loss compared to moderate/heavy drinkers17. Thus, military personnel who reported frequent binge drinking had more negative alcohol-related outcomes from their drinking compared to another group of more infrequent unhealthy drinkers. This study did not examine the impact of deployment or combat exposure in relation to drinking behaviors or drinking-related consequences or productivity loss.
Combat-acquired traumatic brain injury (TBI) is frequently found among military personnel who have served in Afghanistan and Iraq20–22. Unique to military personnel, combat-acquired TBI is commonly caused by a blast or explosion, prompting an alteration of consciousness or brief loss of consciousness, most often resulting in a mild TBI20,21,23–28. While the majority of civilians who experience a mild TBI undergo a restorative brain process within the first few months after injury, a small minority experience ongoing residual effects29. Military personnel with combat-acquired TBI may experience persistent physical and psychological symptoms, particularly because combat-acquired TBIs are often accompanied by other physical and emotional trauma associated with combat exposure30.
Studies of civilian populations suggest that drinking alcohol after experiencing a TBI may be problematic31–33; however, research on alcohol use after combat-acquired TBI is just beginning 34. Some civilians who experience a TBI decrease their alcohol use following injury35, while others may increase their alcohol use36. Further, a recent study of over 4,000 United Kingdom military personnel returning from Afghanistan/Iraq found that those who experienced a mild TBI were 2.3 times more likely to report alcohol misuse, compared to those without a TBI37. Another study examined the medical records of over 3,000 US military personnel who deployed to OEF/OIF from 2004 to 2007 and were treated for blast-induced injuries. Blast-injury patients with a mild TBI had a slightly higher unadjusted rate of alcohol use disorders compared to those without a TBI (6% vs. 4.9%); however, the rates were not statistically significant in multivariate analyses38. A third study using Veterans Administration administrative health records found that OEF/OIF veterans with a positive TBI screen were twice as likely to have alcohol or drug-related diagnoses compared to OEF/OIF veterans without a TBI22.
Nevertheless, what we know from military studies is limited because the studies have been based on those seeking health services, rather than population-based, or have been limited to post-deployment assessment where personnel may be reluctant to divulge injury information as they prepare to transition home from deployment. Research designed to identify factors that contribute to unhealthy drinking is a crucial topic with implications for the health and readiness of the U.S. military, as we know that military personnel have high rates of excessive binge drinking placing them at higher risk for alcohol-related health and social consequences and other negative effects on the military readiness of the Armed Forces13,19,39. The present study is the first to use a population-based survey to assess the association of self-reported, combat-acquired TBI with post-deployment frequent binge drinking among United States (U.S.) active duty military personnel who returned from a combat deployment within the past year. Given prior findings22,36– 38, we hypothesize that military personnel with a self-reported combat-related TBI1 would be more likely to be frequent binge drinkers. This study is a significant contribution to what is currently known, as we control for other characteristics of military personnel, including combat exposure and symptoms of posttraumatic stress disorder (PTSD) or depression, factors that may confound the association of drinking behaviors and TBI.
The 2008 Department of Defense Survey of Health Related Behaviors among Active Duty Military Personnel (HRB Survey) is an anonymous, population-based assessment of the active duty component of the U.S. military under a contract for the TRICARE Management Activity and the U.S. Coast Guard1. The instrument includes numerous items related to drinking behaviors and its consequences as well as measures of deployment history, combat exposure, demographics, and mental health issues. While the 2008 HRB survey is the 10th in a series of surveys sponsored by the DOD since 1980, it is the first in its history to include the TBI screening questions. These items are similar to those used by the DOD in its post-deployment health assessments.40
The survey was administered anonymously to 28,546 active duty personnel from all service branches. In order to capture the worldwide distribution of the U.S. Armed Forces, a dual-mode administration was used. The primary data collection method was group administration at military installations with mailed surveys used at smaller locations. Using multiple stages, a random sample of personnel was selected with military installations as the first-stage units and then random selection of 12 strata formed by gender and pay grade combinations. The survey was administered between May and June of 2008, took an hour to complete, and had an overall response rate of 70.6%. Details of the sampling design, multi-level sampling frame, and data collection methods have been published elsewhere1.
To examine our research question, we selected from all HRB respondents those who reported returning from a combat deployment in the past 12 months. This selection allowed us to identify those with a recent combat-acquired TBI, and then to examine post-deployment drinking behaviors soon after return from the deployment. Of the 28,546 military personnel who completed the 2008 HRB survey, 7,169 (25.1%) met the criterion of a combat deployment in the past 12 months; 14 were excluded because they did not complete items regarding drinking status, for a final study sample of 7,155. Figure 1 describes the respondents included in this sample.
The dependent variable was frequent binge drinking which was assessed on the questionnaire by asking military personnel on how many of the past 30 days did they drink five or more drinks on the same occasion (four or more for women); one or more days was defined as binge drinking. Frequent binge drinking was defined as a minimum of weekly binge drinking episodes during the month, also referred to as heavy drinking in some literature39,41. The other group includes non-drinkers, those who drink but do not binge, and those who binge but do not meet the requirement for frequent binge drinking. Prior research has shown that frequent binge drinking, compared to less frequent binging and unhealthy drinking behaviors other than binging, is associated with increased alcohol-related serious consequences and productivity loss among male military personnel17.
The key independent variable is self-reported, combat-acquired TBI during the last deployment. TBI was defined with three subgroups: 1) those reporting altered consciousness but no actual loss of consciousness (TBI-AC), 2) those reporting loss of consciousness of less than 1 minute (TBI-LOC<1), and 3) those reporting a LOC of 1 minute or greater (TBI-LOC 1+). The classification for self-reported TBI was based on responses to two item sets. Both item sets asked only about the respondent’s most recent deployment, and therefore did not assess possible TBIs that may have occurred on prior deployments or over a lifetime. The first item set asked respondents whether they had experienced a blast or explosion, vehicle accident, a fragment or bullet wound above the shoulders, a fall, or other injury event during their last deployment. From these items, we defined two mechanisms of potential injury event exposures: 1) blast/explosion exposure and 2) other injury etiologies. The second item set assessed possible symptoms that may be associated with the injury event, including length of LOC or being “knocked out” (less than 1 minute, 1 to 20 minutes, or more than 20 minutes), being ‘dazed, confused, or saw stars’ (altered consciousness), or not remembering an injury event (altered consciousness). The questionnaire does not require that the respondent assess whether or not his/her symptoms are the result of a particular injury.
Responses to these two items allowed us to construct, among those with an injury event, a three-level ordinal variable to reflect the intensity of TBI. While guided by the Ohio State University TBI Identification Method, we had insufficient information to map these levels accurately42. The current questionnaire permits reporting of multiple symptoms but does not allow distinctions between one or more than one injury events. We coded type of symptoms based on this hierarchy: TBI-LOC 1+, TBI-LOC<1, TBI-AC when multiple symptoms were reported. Due to small sample size, we collapsed those with a LOC of 1–20 minutes and those with a LOC of 20 minutes or greater into one response category (TBI-LOC 1+). The HRB Survey symptom response groups permit recoding LOC as under 20 minutes or 20 minutes or greater. This provides insufficient information to code LOC using the American Congress of Rehabilitation Medicine’s definition of mild TBI which has a cutoff of under 30 minutes26. Eighty-nine respondents reported a LOC of 20 minutes or greater of which an unknown number may have had a moderate or severe TBI. The reference group in our analysis is comprised of those with no exposure to an injury event and those with exposure but no self-reported TBI symptoms.
We constructed several comorbidity measures based on responses about recent symptoms. Posttraumatic stress disorder was assessed using the PTSD Checklist-Civilian (PCL-C), which consists of 17 symptoms present in the past 30 days, from trauma events during military or nonmilitary experiences based on the diagnostic definition of PTSD. The standard diagnostic cutoff score of 50 or greater was used to classify a positive screen for current PTSD 43,44. Depression was assessed with the Version A Burnam depression screen that included one item from the Center for Epidemiologic Studies (Depression Scale) and two items from the Diagnostic Interview Schedule10,45,46. A positive screen for past year depression was coded if the respondent reported symptoms for over two weeks in the past year, or reported two or more lifetime years of feeling depressed ‘much of the time’ and reported feeling depressed at least one day in the past week. Suicidal ideation was assessed as present if a respondent reported seriously considering suicide in the past year.
Lifetime combat exposure was assessed with 17 questions about different combat experiences such as handling dead bodies or witnessing members of a unit being killed. Respondents reported the number of times they experienced each of the 17 items encompassing all previous deployments. We classified respondents based on their summary score value as none (0), moderate (1–9), and high (10+) combat exposure levels10,47.
Demographic variables considered in the analysis were sex, and dummy variables for age category (17–20, 21–25, 26–34, and 35+), service branch (Army, Navy, Marine Corps, Air Force, and Coast Guard), race/ethnicity (White/non-Hispanic, Black/non-Hispanic, Hispanic, Other), marital status (never married, married/living as married, divorced/separated, and widowed), education level (high school or less, some college, and college graduate), and pay grade (junior enlisted/E1-E6, senior enlisted/E7-E9, warrant officer/W1-W5, officer/O1-O10).
All analyses were weighted to account for the complex sampling design of the HRB Survey. Frequencies were calculated for two groups, frequent binge drinkers and ‘others’ inclusive of drinkers and non-drinkers, along with design-based F tests to assess significance levels of the bivariate relationships. Multivariate logistic regression on frequent binge drinking was used to estimate unadjusted odds ratios (OR) associated with the combat-acquired TBI subgroup (Model 1). Model 2 added possible risk factors for frequent binge drinking (demographics and lifetime combat exposure) to estimate the adjusted odds ratios (AOR) associated with TBI subgroup. We excluded age group from these models because of its multicollinearity with pay grade, and opted to include pay grade instead of age because it is military-specific and often included in studies of military populations. Model 3 added various measures for comorbidity to the adjusted model, 3A added PTSD, and Model 3B added depression and suicidal ideation. PTSD and depression were not included in the same model due to their high inter-relationship. The sample sizes for specific multivariate models varied due to non-response to some of the covariates. We conducted a post-hoc sensitivity analysis on the multivariate models to determine if the TBI-LOC 1+ results were being driven by the 89 cases where LOC was 20 minutes or greater, cases which may include those with moderate or severe TBIs.
All analyses were conducted in STATA 1048 using survey (svy) and subpopulation (subpop) commands to take into account response weights.
The HRB Survey was conducted with approval by the Department of Defense/TRICARE Management Activity (TMA) and RTI International Institutional Review Boards. The de-identified dataset analyzed here was released by the DOD/TMA privacy office upon determination that the study was exempt by both TMA’s Human Research Protection Program and Brandeis University’s Committee for Projection of Human Subjects.
Table 1 shows the distributions of characteristics of the study population in two drinking groups, frequent binge and others (including no drinking). The overall sample is comprised of mostly males (89.0%), those who identified as White/non-Hispanic (63.1%), married personnel (61.7%), those with some college education (46.2%), with an average age of 28.6 years (data not shown). The majority of the sample is enlisted personnel (85.9%), with at least two deployments since 9/11/01 (55.3%), with moderate or heavy combat exposure (73.7%), with the greatest representation from the Army (37.3%) and Navy (27.2%). Almost one-fourth of the overall sample reported past year depression, 13.4% had a positive PTSD screen in the past month, and 5.0% reported suicidal ideation in the past year.
Over one-fourth (25.6%) of those on a combat deployment in the past year reported frequent binge drinking. Compared to those who do not binge drink on a weekly basis, frequent binge drinkers were more likely to be male, to be in the youngest age range (17–25), white, single (never married or divorced/separated), and have a high school education or less. In terms of military characteristics, frequent binge drinkers compared to others were more likely to be in the Army or Marine Corps, have a junior enlisted (E1-E6) pay grade, and have high lifetime combat exposure. In terms of clinical characteristics, frequent binge drinkers were more likely than others to have a positive screen for current PTSD, past year depression, and report suicidal ideation in the past year.
Among the study sample, 39.3% reported being exposed to at least one injury event on the most recent combat deployment. These events were post-coded as a blast/explosion, ‘other’ injury etiology (e.g, vehicular accident/crash, fragment or bullet wound above the shoulders, fall) or both blast and other event (see Table 2). Most common was the report of experiencing both a blast and other injury etiology (19.8%) during the most recent combat deployment, with similar proportions experiencing blast only (9.7%) or other injury etiologies only (9.8%). In total, almost one-third (29.5%) of the study sample had experienced a blast. We could not determine whether personnel experienced one or more injury events.
Overall, 13.9% of the study population reported experiencing a TBI after an injury exposure during their most recent deployment. The most common type of TBI was TBI-AC (7.5%), followed by TBI-LOC<1 (3.5%), and TBI-LOC 1+ (2.8%). Proportions at each TBI level varied by type of injury event exposure (see Table 2). The highest rate of self-reported TBI (49.3%) was among those personnel who experienced both a blast and other injury etiology. Those with a blast exposure only reported the lowest rate of each TBI level. Almost 15% of males reported a TBI while only 4.9% of females did so (data not shown). There was a dose response relation between both TBI and PTSD and TBI and depression. For example, the relation between TBI and PTSD revealed that among those with TBI-AC, 26.8% had a positive PTSD screen, 41.5% of those with TBI-LOC<1 reported PTSD, and 59.7% of those with TBI-LOC 1+ had a positive PTSD screen (data not shown).
Table 3 presents the unadjusted and adjusted association of TBI with the probability of frequent binge drinking. Unadjusted analyses showed that military personnel with a TBI were significantly more likely to report frequent binge drinking in the past month compared to those without a TBI. As TBI severity increased, the odds of frequent binge drinking also increased in a dose relation. Model 2 showed that when controlling for demographic characteristics and combat exposure, the adjusted odds ratios (AOR) for each TBI level decreased slightly but remained significant.
In all three adjusted models, several demographic and combat exposure variables were significantly associated with frequent binge drinking. Males had higher odds of frequent binge drinking than females. Those in the Air Force had lower odds of frequent binge drinking than those in the Army, but those in the other branches were not significantly different from the Army. Military personnel who identified as Black or ‘other’ race/ethnicity had lower odds of frequent binge drinking compared to white personnel. Those married or living as married had lower odds of frequent binge drinking compared to those who had never been married. Military personnel at the E7-E9 pay-grade, warrant officers, and commissioned officers all had lower odds of frequent binge drinking than those at the lowest pay-grades (E1-E6). And those with high lifetime combat exposure had higher odds of frequent binge drinking compared to those with no lifetime combat exposure.
In Model 3a, a positive screen for PTSD had a significant association with frequent binge drinking, yet two levels of combat-acquired TBI remained significantly associated as well. Those with a TBI-AC had increased odds of frequent binge drinking, as did TBI-LOC 1+. In Model 3B, a positive depression screen and suicidal ideation in the past year were both significantly associated with frequent binge drinking; however, once again, TBI-AC and TBI-LOC 1+ remained significantly associated with frequent binge drinking, although the AORs were attenuated and smaller than observed when PTSD was the covariate.
When we conducted sensitivity analyses after dropping 89 cases with a LOC of 20 minutes or greater, the coefficient for those with TBI-LOC 1+ was only slightly smaller (AOR 1.25, 95% CI, 0.69–2.27) and was not statistically significant (p = .45), which may be related to a substantially smaller TBI-LOC 1+ group (data not shown).
There are significant costs of frequent binge drinking among returning active duty military personnel. Drinking at unhealthy levels may interfere with reintegration and complicate other combat-related injuries and conditions. Over one-fourth (25.6%) of military personnel who had been on a combat deployment in the past year reported frequent binge drinking, placing themselves at very high-risk of negative drinking consequences such as poor job performance and alcohol-impaired driving13,19, which may compromise their readiness for a subsequent deployment. Multivariate analyses indicated that those personnel with a TBI during their most recent combat deployment were more likely to be frequent binge drinkers compared to those without TBI, controlling for demographics, lifetime combat exposure, and comorbidity. While we cannot draw causal inferences from this cross-sectional analysis, our findings suggest that experiencing a TBI is one driver of unhealthy drinking post-deployment.
Service members with a positive PTSD screen had higher odds of frequent binge drinking compared to those without a positive screen. The findings also suggest that PTSD may partially mediate the relation between TBI and frequent binge drinking. When PTSD was added, the AORs for all TBI level variables decreased from Model 2. While reduced in magnitude, TBI-AC and TBI-LOC 1+ remained significant. Thus, TBI has an apparent independent relation to frequent binge drinking.
Importantly, this study also demonstrates that TBI-AC increased the likelihood of frequent binge drinking in all models. The dose-response relation between TBI and frequent binge drinking apparent in the unadjusted Model 1 was not as evident in models 2 and 3. However, the most severe TBI (TBI-LOC 1+) retained the highest AOR in all models. We can only speculate at this time about the diminution in dose relation of TBI level and frequent binge drinking in models 2 and 3. It may be an artifact of sample size, or more severe injury may be protective due to unknown mediating factors (e.g., more likely to be on a prescription medication for symptom relief; more likely to have been advised not to drink to excess). There was also confounding of TBI level and positive PTSD screen, and the TBI-AC participants had the lowest proportion of positive PTSD screens. The TBI-LOC <1 group did not differ significantly from the other TBI groups with regard to prevalence of positive PTSD or depression screens. Finally, improved measurement of type of injury, particularly among those exposed to blasts, may provide additional, useful information about the nature of the TBI. Future studies could examine whether there are other injury characteristics associated with drinking behavior.
Almost 40% of the sample reported at least one injury event exposure during the deployment that ended in the past year, and 13.9% reported symptoms of TBI while on this recent deployment. This overall prevalence is within the range of estimates from previous US studies, which have observed from 12% to almost 23%20–22,27,49–51. Unlike other studies which focused on a single branch, often the Army21,27,51, this study included active duty personnel from all branches, and TBI exposure varied greatly by branch. In this population-based study, TBI prevalence on the most recent deployment was over 24% of Army personnel, followed by the Marine Corps (18.9%) and Coast Guard (9.6%), with the lowest TBI prevalence in the Navy (4.8%) and Air Force (4.7%) (data not shown).
We cannot draw causal inferences from a cross-sectional design. As with most studies of combat-acquired TBI, we relied on self-report measures of TBI symptoms rather than a clinical determination of TBI immediately after an injury event. In addition, we did not know lifetime history of TBI from prior deployments, non-combat related exposures, or those who may have had multiple injury exposures29,52. The presence of prior TBIs may interfere with military personnel’s ability to process the combat exposure or deployment in general and indirectly influence frequent binge drinking behavior. Further, the survey did not ask precise questions about drinking behavior prior to deployment, so we did not know if drinking behavior changed for any respondents and if so for which groups. Furthermore, by including only two groups in our analyses, in which the “other” group included those with less frequent binge drinking, as well light drinkers and non-drinkers, the risks of less frequent binge drinking were not considered. To some degree, these unknowns would add to measurement error in our models, yet we found a significant relation between TBI and frequent binge drinking despite these possibilities.
Reflecting the HRB survey question wording on ‘experiences’, we did not know important details about the nature of blast or other injury events. Effects of a blast, for example, could vary widely based on distance, enclosure, surroundings, post-injury actions and other injuries in addition to the blast. We did not have any head injury severity measures. The HRB Survey instrument asked service members if they had “experienced” the events (blast/explosion etc.) but did not ask explicitly if they had been “injured” by these events.
As previously noted, the most severe response category was “a LOC of 20 minutes or greater” which did not allow us to isolate those with a moderate or severe TBI from those with a mild TBI. 26. Due to small sample size, we collapsed those with a LOC of 1–20 minutes and those with a LOC greater than 20 minutes into one response category. It is possible that those with moderate or severe TBI could skew the findings for TBI-LOC 1+. However that is not likely for several reasons. Most military personnel with moderate or severe head injury would be medically evacuated and some would not return to their permanent duty station. Within one year, some may still be in medical or rehabilitation facilities, medically separated from the military, or otherwise not eligible to participate in the survey. While the cutpoints for LOC did not follow traditional definitions, a sensitivity analysis conducted post hoc revealed minimal changes in the pattern of findings, and explanatory power showed a slight advantage for the groupings we used.
This is the first study to use a population-based assessment of the active duty component of the Armed Forces to assess the association of combat-acquired TBI and frequent binge drinking in those returning from a combat deployment in the past year. This study is comprehensive in that it is worldwide, covers all branches of the active military, and was administered with the same dual-mode administration method throughout. Unlike previous studies that used convenience samples21,22,27,38 and were restricted to one service branch4,21,27,51, this study has the unique ability to estimate prevalence for the Armed Forces as a whole. Our population estimates are that among 393,884 active duty military personnel with a past year combat deployment, 87,915 personnel engaged in frequent binge drinking. Further, 137,625 personnel were exposed to at least one injury event, and 41,727 reported symptoms consistent with a combat-acquired TBI, the majority with altered consciousness (23,286), and 18,441 service members with LOC. The finding that TBI-AC was associated with frequent binge drinking suggests that the Armed Forces and health providers should not ignore mild TBI when considering whether returning military personnel are at risk for post-deployment consequences.
This study had other methodological strengths. Although, the HRB Survey is cross-sectional in design, we chose respondents with a recent combat deployment. Thus, the outcome of interest, frequent binge drinking in the past 30 days, occurred after the deployment, but in close proximity to the injury and TBI event, strengthening our ability to draw conclusions. Limiting our sample to those with a deployment in the past year may also have reduced recall bias relating to injury events and TBI. Also, since the HRB Survey was administered anonymously, respondents had nothing to lose by disclosing sensitive behavioral health information, such as drinking behaviors and comorbidities53. Similarly, there were no incentives to over-report combat-related injuries or behavioral health conditions, such as TBI or PTSD, as no medical benefits or job performance assessments were linked to the anonymous survey.
We outline implications of this study for clinical practice, public health interventions, and future research directions. Our findings highlight the importance of routine post-deployment screening for both TBI and PTSD and suggest that the presence of either or both of these conditions could trigger targeted alcohol assessment and brief counseling for those with unhealthy drinking behaviors, other brief interventions for those with frequent binge drinking, and referral to treatment for those with alcohol use dependence. Conversely, among those currently experiencing alcohol use problems, these findings suggest careful assessment of underlying TBI and PTSD comorbidities to understand whether and how these might be contributing to alcohol behaviors. Screening and brief interventions, particularly those done in primary care settings, have been effective in identifying those with problem drinking and helping these individuals reduce drinking and change unhealthy drinking patterns54–59. Further, when deployed military personnel have been exposed to a potentially brain-injuring event such as a blast, the military could provide additional alcohol education and alcohol brief counseling designed to encourage them to rethink their drinking behaviors34. Current evidence suggests that these interventions may be most effective when offered by trained medical personnel in health care settings.
More research is needed that captures data on TBI-inducing combat events at the time of the injury. Surveys of injury events and TBI symptoms should be worded in ways that are consistent with clinical literature. Specifically, we recommend that future versions of the HRB Survey be strengthened by altering the response categories for severity of TBI to be able to isolate those with a mild TBI from those with moderate or severe injuries. In addition, respondents who report having been exposed to an “injury event” on a deployment could be prompted to report the types of injuries that resulted from the exposure event.
In sum, more research is needed to explore how TBI is related to post-deployment drinking behaviors. This study cannot answer the question whether TBI causes the increased likelihood of frequent binge drinking among active duty service members. It is unclear if the change in the dose-response relation between TBI and drinking that occurred when mental health covariates were accounted for was due to an interaction among the variables or instead was due to sample size, measurement error, or some other artifact. More studies are warranted to explore these relations.
This study suggests that experiencing a combat-acquired TBI, even mild TBI with altered consciousness only, is associated with frequent binge drinking after deployment. In addition to being contraindicated for TBI patients, this level of unhealthy drinking interferes with post-deployment reintegration and complicates healing from other combat-related injuries and conditions such as PTSD. The DOD may improve the health and wellbeing of military personnel by mounting evidence-based screening and brief interventions for unhealthy drinking in primary care and other medical settings for post-deployment military personnel with self-report of possible TBI events.
Ms. Adams acknowledges the support of dissertation committee members Drs. Grant Ritter and Robert M. Bray for their review of her research proposal as well as the programming support of Mr. Lee Panas.
1We define TBI based on self-report elicited by the HRB Survey method. It does not represent a clinical diagnosis or an observed event.
Funding Disclosure: Ms. Adams conducted this research with predoctoral fellowship dissertation support from a Ruth L. Kirschstein National Research Service Award from the National Institute on Alcohol Abuse and Alcoholism (NIAAA) (F31 AA021030) and an institutional training grant from NIAAA (T32 AA007567).
Credits, or Disclaimers: The Office of the Assistant Secretary of Defense for Health Affairs/TRICARE Management Activity (OASD HA/TMA) of the United States Department of Defense (DOD) provided access to these data. The opinions or assertions herein are those of the authors and do not necessarily reflect the views of the United States Department of Defense or of the National Institutes of Health. This research has been conducted in compliance with all applicable federal regulations governing the protection of human subjects.
Rachel Sayko Adams, Doctoral Candidate, The Heller School for Social Policy & Management, Brandeis University, Waltham, MA, USA.
Mary Jo Larson, Senior Scientist, The Heller School for Social Policy & Management, Brandeis University, Waltham, MA, USA.
John D. Corrigan, Professor, Department of Physical Medicine & Rehabilitation, The Ohio State University, Columbus, OH, USA.
Constance M. Horgan, Professor and Associate Dean for Research, The Heller School for Social Policy & Management, Brandeis University, Waltham, MA, USA.
Thomas V. Williams, Director, Long Term Studies for the Defense Health Cost Assessment and Program Evaluation, (DHCAPE), TRICARE Management Activity (TMA), Department of Defense (DOD), Falls Church, VA, USA.