Article Text
Abstract
Introduction Historically, diseases and non-battle injuries (DNBI) typically stand for 70%‒95% of all medical events during military missions. There is, however, no comprehensive compilation of medical statistics for Swedish soldiers during deployment.
Method During United Nations Multidimensional Integrated Stabilization Mission in Mali, climate data and medical outpatient health surveillance data were compiled for Swedish soldiers deployed to Timbuctoo, between 2015 and 2019. Correlations between climate data and medical outpatient health surveillance data were analysed.
Results Battle injuries accounted for 0.4% of the visits to healthcare, while diseases accounted for 53.6%, and non-battle injuries for 46%, the majority being musculoskeletal injuries. The combination of high temperature, humidity, sun radiation and good visibility, during summer rotation weeks, caused more events of injuries and heat stress than any other period.
Conclusion Musculoskeletal injuries were the major cause for visits to the Swedish camp hospital. Injuries and heat stress increased during periods of high temperature, humidity, sun radiation and good visibility. Lack of medical data, i.e. unknown number of unique patients seeking healthcare, cause codes not always connected to a primary diagnosis, and revisits not being connected to a diagnose, complicated interpretation of health risk factors.
- PRIMARY CARE
- STATISTICS & RESEARCH METHODS
- ACCIDENT & EMERGENCY MEDICINE
- HEALTH SERVICES ADMINISTRATION & MANAGEMENT
- Health informatics
- Information management
Data availability statement
Data are available upon reasonable request.
This is an open access article distributed in accordance with the Creative Commons Attribution Non Commercial (CC BY-NC 4.0) license, which permits others to distribute, remix, adapt, build upon this work non-commercially, and license their derivative works on different terms, provided the original work is properly cited, appropriate credit is given, any changes made indicated, and the use is non-commercial. See: http://creativecommons.org/licenses/by-nc/4.0/.
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- PRIMARY CARE
- STATISTICS & RESEARCH METHODS
- ACCIDENT & EMERGENCY MEDICINE
- HEALTH SERVICES ADMINISTRATION & MANAGEMENT
- Health informatics
- Information management
WHAT IS ALREADY KNOWN ON THIS TOPIC
Diseases and non-battle injury during deployments are much more common than battle injury (BI).
WHAT THIS STUDY ADDS
Documentation of outpatient care in a Swedish camp hospital during a deployment.
A foundation for better understanding of health conditions in outpatient settings.
HOW THIS STUDY MIGHT AFFECT RESEARCH, PRACTICE OR POLICY
Optimisation of medical surveillance and of training and educational programmes.
Background
In modern warfare, diseases and non-battle injuries (DNBI) accounts for 70%‒95% of the medical evacuations/hospitalisations among soldiers.1–6 This can be exemplified by data from the Korean War (1950‒1953) and Gulf War (1990‒1991), when medical evacuations due to DNBIs went from almost 600 per 1000 person-years to less than 100 per 1000 person-years. With an improved Deployment Health Surveillance Capability, evacuations/hospitalisation due to DNBI decreased further during the wars in Iraq and Afghanistan.7–11 Historically, musculoskeletal/orthopaedic diagnoses caused by pre-existing disorders or by overuse accounts for a large part of medical evacuations and lost duty days.12–16
The Swedish Armed Forces participated in United Nations Multidimensional Integrated Stabilization Mission in Mali (MINUSMA) established in April 2013. The harsh environmental conditions in Mali prompted a high awareness of health-related issues and earlier studies on Swedish personnel stationed in desert environments have highlighted the relationship between chronical respiratory symptoms and time spent in desert environment.17
The aim of this study is to present morbidity in the Swedish contingency in Mali during the period from May 2015 to November 2019 (223 weeks), together with correlates to climate data.
Methods
Population data
In total 2 500 persons rotated to Mali during the study period, with 250 militaries in each rotation, that is, ‘winter rotation’ during November/December and ‘summer rotation’ during May/June. Each rotation brought a medical capacity including physicians, nurses, psychologist, physiotherapist and unlicensed healthcare workers.
Medical record data
Visits to the Swedish contingency hospital care at Camp Nobel in Timbuctoo were compiled on a weekly basis, together with diagnose code categories according to International Classification of Diseases, 10th revision (ICD-10). Rates for compiled categories were expressed in events per 1000 person-years or 100 person months.
The term ‘NBI’ includes the categories injuries (S and T diagnostic codes) and musculoskeletal (M diagnostic codes).5 13 18 19 Revisits, hospitalisations, evacuations, cause codes and response codes could not be matched with their corresponding primary diagnosis in the data set. Apart from the cause code ‘war operation unspecified’ (Y 36.9) categorised as battle injuries (BI), cause codes and response codes were, therefore, excluded from the calculations.
Climate data
Climate data, including Wet Bulb Globe Temperature (WBGT), a measure of the exposure to environmental heat on humans that considers temperature, humidity, wind speed, sun angle and cloud cover,20 and hourly measured values for visibility (km) and relative humidity (%) was compiled together with medical record data. Data were either transformed into weekly minimums and maximums (visibility and relative humidity) or means (WBGT and temperature). For days that lacked data on WBGT, mean values were estimated based on the days before.
Data preparation
Scale variables
Medical data were summarised into 13 categories based on the ICD-10 diagnose categories (online supplemental file 1). For climate data, visibility, being a proxy for particulates in the air, was chosen as a scale variable due to its impact on the personnel’s ability to work, regardless of WBGT.
Supplemental material
Categorical variables
To calculate differences between measured WBGT values, WBGT was transformed into a normally distributed categorical variable (WBGT*), resulting in six temperature categories: 19.33‒23.05, 23.06‒27.00, 27.01‒30.95, 30.96‒33.20, 33.21‒34.43 and 34.44‒36.26 (C°). The variable "rotation", which differentiates between summer and winter rotation, was added to the data set to incorporate more contextual information into the statistical analysis. Each week was categorised as either 0 (normal week), 1 (winter rotation week) or 2 (summer rotation week).
Data analysis
WBGT* was analysed for skewness and kurtosis. Post hoc test was used to analyse differences between WBGT* groups. Bivariate correlation analysis was conducted on the 13 ICD-10 diagnose categories and WBGT*. Three separate one-way ANOVA (Analysis of Variance) calculations was conducted: WBGT* and Heat stress, Rotation and Heat stress and WBGT* and Respiratory, respectively. A univariate analysis was conducted on heat stress and (WBGT*×Rotation) with visibility as a WLS-weight (weighted least squares). F-values was used to calculate the between group variation and within group variation. A large F-value is interpreted as a statistically significant difference between groups. IBM SPSS, V.29.0.1.0 was used in all calculations.
Results
Morbidity
The study period, corresponding to 1 250 person-years, generated 5 852 diagnostic codes. Given that only 62 patients were hospitalised and seven medically evacuated out of the 5774 clinical visits, this was primary and outpatient study. DNBI was found to be 39.0 events per 100 person months, while NBI and BI generated 18.1 and 0.2 events per 100-person month, respectively (table 1).
The four leading diagnostic categories were ‘musculoskeletal’ (26%), ‘injuries’ (20%), ‘skin’ (13%) and ‘respiratory’ (11%), accounting for 70% of the total reported diagnosis (figure 1). The top two diagnoses in the NBI category were ‘myalgia’ (15%) and ‘low back pain’ (13%), contributing to more than 25% of all NBI. According to physiotherapists at site during 2019, commonly exposed body parts were neck/cervical spine (26%), lumbar spine/pelvis (17%), shoulder/arm (15%) and lower leg/foot (15%).
Four types of cause codes were reported, including 12 reports of ‘person injured in unspecified vehicle accident’ (V89.9), 107 reports of ‘striking against or struck by sports equipment’ (W21), 18 reports of ‘exposure to noise’ (W42) and 17 reports of ‘war operations unspecified’ (Y36.9). Three types of response codes were reported, including 23 reports of ‘issue of medical certificate’ (Z02.7), 5 reports of ‘need for immunisation against unspecified infectious diseases’ (Z26.9) and 137 reports of ‘observation for disease’ (Z03.9).
Correlation of medical record and climate data
The categorial variable WBGT* produced acceptable values for skewness (−0.03) and kurtosis (−0.98). The bivariate correlations between the category groups, Heat stress and WBGT* produced several small correlations below 0.36. The variables heat stress (0.18) and respiratory (0.31) produced small but statistically significant correlations with WBGT*. There was a statistically significant correlation between visibility and injuries (−0.20), indicating more events of injuries when visibility is good.
ANOVA test between WBGT* and heat stress (table 2) was statistically significant and the post hoc analysis produced several significant differences between the category 33.21–34.43 (a) and the categories in the range 19.33–33.20 (b). Events of heat stress recorded in the category 33.21–34.43 (a) were significantly higher than in any other category. ANOVA test between WBGT* and respiratory was statistically significant. Post hoc analysis produced several significant differences between the category 34.44–36.26 (a) and the categories in the range 19.33–30.95 (b), and between the category 33.21–34.43 (c) and the categories in the range 19.33–30.95 (d). Events of respiratory diagnoses recorded in the highest WBGT category 34.44–36.26 (a) was significantly lower than in the other WBGT categories.
ANOVA test between rotation and heat stress (table 3) was statistically significant. Post hoc analysis produced two significant differences between the categories summer rotation (a) and no rotation and winter rotation (b). Events of heat stress during summer rotation were significantly higher.
The univariate analysis between heat stress and (WBGT*×Rotation) was not statistically significant. However, by adding visibility to the univariate analysis as a WLS-weight, the analysis became statistically significant (table 4).
Figure 2 illustrates the correlation of climate data with events of heat stress (n=22). The univariate analysis shows that high WBGT* during summer rotation weeks when the visibility is good, generated more events of heat stress than high WBGT* values do during any other weeks.
Discussion
This study adds important documentation of outpatient care during a deployment. We found 39 events of DNBI per 100 person months, which is in line with earlier studies using outpatient health surveillance data.17 21 22 Of these, 18 events per 100 person months are due to NBI, ie, 2–4 times higher than reported in earlier studies.1 5 6 8–10 21 Many serious injuries are treated on an outpatient basis, as well as conditions considered to be of moderate severity, such as back pain, knee pain and myalgia, despite their potential of being severely debilitating and disabling.
Historically, physiotherapy treatment accounts for a large part of the visits,19 due to symptoms from lower back and shoulder, knee and neck and lumbar spine.23 Poor ergonomic conditions and over-use from sport activities contribute to these injuries. Especially sport activities have been reported to be a major cause for hospitalisation5 22 24 and in the present study, more than 100 cause codes for ‘sport-activity’ were reported. Injury-related musculoskeletal conditions are usually due to repetitive or cumulative microtrauma, which suggests that conditions such as myalgia, low back pain, joint pain, and enthesopathies can be prevented by intervening in the repetitive cycle.
Dermatological disorders typically account for 10% to 15% of the outpatient visits,18 22 whereas in studies based on hospitalisation and evacuation data, only 1%–1.5% are due to skin disorders.6 24 A probable reason for this is that skin disorders generally are not critical.12
Eleven per cent of all visits were due to respiratory diseases, of which acute upper respiratory infection was pronounced during rotation. In McKee et al, ‘respiratory’ was the second largest category, in which ‘acute upper respiratory infection’ dominated.19 Cox et al found a higher frequency of gastroenteritis during rotation.22 In the present study, 8% of all diagnoses were due to infections, but the reported cases did not increase during rotation.
An increase of heat stress and a decrease in respiratory symptoms was found with increasing WBGT*. In addition, there was a statistically significant correlation between visibility and injuries, in that more injuries were reported during episodes of good visibility. These results indicate that visibility do constrain military activity, and from an activity theoretical perspective,25 visibility can be seen as an implicit rule influencing and constraining26 how military personal solve military problems. Finally, the combination of high WBGT* and good visibility during summer rotation weeks, caused more events of injuries and heat stress than any other period.
Limitations
In the present study, medical data for 28 weeks were missing due to lack of routines for reporting. Problems related to imprecisely measured populations at risk are common in studies of disease frequency, so also in the present study, where the actual number of unique patients seeking healthcare was not available. Since revisits were not connected to a diagnose, one unique diagnosis could be counted more than once. Finally, treatment executed by a medical unit following a smaller troop on a task away from the camp might not have been compiled in the ICD-10 reports. The strengths of the present study are long duration time, diagnoses made by medical care providers, medical data tabulated using ICD-10 codes and the simultaneous collection of climate data.
Conclusions
NBI were the leading reason for deployed Swedish soldiers to seek medical care, partly because of poor ergonomic working environment and risky behaviour during exercise or sport activity. The combination of high WBGT* and good visibility during summer rotation weeks, caused more events of injuries and heat stress than any other period.
Low medical data quality complicated the interpretation of health risk factors for the Swedish contingency during MINUSMA. Future studies on outpatient settings could be significantly improved by a centralised surveillance, better documentation of denominators and by connecting cause codes, hospitalisations, evacuations and revisits to its specific ICD code.
The present study provides a foundation for better understanding of the most common health conditions affecting soldier health in outpatient settings and for setting priorities for prevention and treatment of the most common conditions affecting solider health. Tracking climate and seasonal data may help predict some health conditions, such as heat-related diseases.
Data availability statement
Data are available upon reasonable request.
Ethics statements
Patient consent for publication
Ethics approval
Not applicable.
References
Supplementary materials
Supplementary Data
This web only file has been produced by the BMJ Publishing Group from an electronic file supplied by the author(s) and has not been edited for content.
Supplementary Data
This web only file has been produced by the BMJ Publishing Group from an electronic file supplied by the author(s) and has not been edited for content.
Footnotes
Contributors MSa contributed to the design, planning, analysis, interpretation of data and writing and reviewing of the manuscript. LA contributed to the analysis, interpretation of data and reviewing of the manuscript. MSch contributed to the analysis, the interpretation of data and writing of the manuscript. FT contributed to the conception and design of the work, analysis, interpretation of data and writing, reviewing and drafting of the manuscript. FT acts as guarantor.
Funding The authors have not declared a specific grant for this research from any funding agency in the public, commercial or not-for-profit sectors.
Competing interests None declared.
Provenance and peer review Not commissioned; internally peer-reviewed.
Supplemental material This content has been supplied by the author(s). It has not been vetted by BMJ Publishing Group Limited (BMJ) and may not have been peer-reviewed. Any opinions or recommendations discussed are solely those of the author(s) and are not endorsed by BMJ. BMJ disclaims all liability and responsibility arising from any reliance placed on the content. Where the content includes any translated material, BMJ does not warrant the accuracy and reliability of the translations (including but not limited to local regulations, clinical guidelines, terminology, drug names and drug dosages), and is not responsible for any error and/or omissions arising from translation and adaptation or otherwise.