Survival and Predictors of Patient Mortality during Road Traffic Accidents in the Democratic Republic of Congo: Historical Cohort Study ()
1. Introduction
Road accidents are collisions occurring on the road network between a rolling machine and any other thing or person [1]. They can cause injury and loss of life, as well as material damage [2].
Many factors contribute to the risk of collision, to its severity, and beyond the collision itself, to the survival or otherwise of the victims [3] [4] [5]. While road transport has probably contributed significantly to the development of isolated or even industrialized areas in the past, road accidents now represent a serious public health problem at the global, regional and national levels. They were the 9th leading cause of death, all causes and all ages in 2011, with an estimated mortality of 1.261 million annual deaths (i.e. 18 deaths per 100,000 inhabitants). This figure represents 2.8% of total mortality and is increasing (it was 1.017 million in 2000) according to WHO estimates [6] [7] [8] [9]. Another 20 to 50 million people survive accidents that cause crippling trauma all over the world. These road accidents represent a significant cost for countries (estimated between 1% to 3% of GDP), but they are also often strongly linked to the economic activity to which road traffic contributes [10] [11] [12].
The groups most affected by road crashes are pedestrians and motorcyclists in very low and low income countries [11]. Mortality varies by age, but this age structure does not appear to be affected by the income level of countries. However, other confounding factors can disturb this relationship. The effects of income on road mortality must therefore be analyzed, all other things being equal, as demonstrated by road network experts. In our country the survival of patients during road traffic accidents is not known despite the number of road traffic accidents recorded in our cities. This is why this study aims to study survival and the socio-economic and clinical factors predicting mortality.
2. Patients and Methods
2.1. Study Setting and Design
Our study took place in 2 hospitals in the city of Kinshasa. These are the University Clinics and the Central Military Hospital of Kinshasa. These two hospitals receive a large number of accidents that occur in the city of Kinshasa. This was a historic cohort study that took place from 2011 to 2016 and focused on the files of patients who suffered road traffic accidents in the city of Kinshasa.
2.2. Study Population
The study population concerned all patients who suffered a road traffic accident in the city of Kinshasa. The outcome measure was the vital outcome of the patients. The sampling was convenient and exhaustive; the patients were admitted taking into account inclusion criteria. Were included in the study, the casualties having been received urgently in these two hospitals and who were followed for care. Accidents that died were excluded from the study.
2.3. Data Collection
The data was obtained from the records of patients admitted to these two hospitals in a recorded traffic accident in the city. Prior to analysis, these data were cleared by excluding variables for which there was a lot of missing data (missing data on records). All accident victims with a file containing the variables of interest for the study were included in the study. The sampling was of convenience which took into account inclusion criteria, the size of the sample collected during the study period was 878. The variable of interest studied was the occurrence of a fatal road traffic accident. The explanatory variables were:
? socio-demographic characteristics (gender, age, socioeconomic level);
? the clinical characteristics of the patients (location of lesions);
? environmental risk factors (accident depending on the month, accident depending on the year);
? the vital outcome (survivor or deceased).
Survival was defined in this study as the time between the date of admission to hospital and the date of death (for the deceased) and the date of discharge authorized by the nursing staff for the living.
2.4. Statistical Analysis
Analyzes were performed on SPSS 21.0. Descriptive statistics consisted of calculating the mean and standard deviation for quantitative data and proportions for categorical data. Pearson’s chi-square or Fisher’s exact test was used to compare the proportions, while Student’s t test compared the means. The Kaplan Meier method described survival from day 1 of hospitalization to death (full data) to study end (censored data). The Log-rank test was used to compare survival curves. Cox’s regression looked for independent predictors of mortality. The p-value < 0.05 was considered to be the threshold of statistical significance.
2.5. Ethical Considerations
The data was collected anonymously and confidentially. The privacy and personality of the respondents were safeguarded. The three fundamental principles of ethics were respected at the time of the study: the principle of respect for the person, that of beneficence and that of justice.
3. Results
Of all the patients who were admitted in emergency, there were 878 who had usable records during our investigation. These 878 were the data for this study.
3.1. Vital Outcome of Patients
Of the accident victims admitted to the two hospitals, 19.6% had died and 80.4% had survived (Figure 1).
3.2. Frequency of Death by Years
The annual incidence was 3.1% person-year with a survival time between admission and discharge of 18.6 days. With the progression of the years, we notice an increasing rate of deaths due to road traffic accidents with a high frequency in 2016 (32.6%) (Figure 2).
3.3. General Characteristics Depending on the Vital Outcome
The mean age of the accident victims was 33.4 ± 15.9 years, the majority were under 50 (81.2%), the men were slightly dominant with an M/F sex ratio of 1.13 (Table 1). The majority of accident victims had a low socioeconomic level (66.1%). These accident victims had more than one attack of two organs (56.5%), the heel and the head were the organs most affected. Compared to the survivors, the accidents had a significantly low socioeconomic level (p < 0.001), with damage to the head, neck, thorax and abdomen.
Figure 1. Vital outcome of accident victims.
Figure 2. Annual distribution of fatalities due to road traffic accidents.
Table 1. General characteristics according to the vital outcome.
3.4. Survival Study of Accident Victims
3.4.1. Overall Survival
The probability of survival of the children was 87.6% on the fourth day, 82.5 on the 7th day, 81.9% on the 14th day, 81.2 on the 21st day, 80.6% on the first month and 80.4% in the second month. The median survival time was 18 days (IEQ: 7 - 8) (Figure 3).
3.4.2. Survival by Socioeconomic Level
The median follow-up survival was 4 (2 - 8) days for those with low socioeconomic level, 15 (7 - 28) days for those with medium socioeconomic level and 21 (11 - 29) for those with low socioeconomic level. high socioeconomic. Indicating a better survival of accident victims with a high socioeconomic level compared to those with an average and low socioeconomic level with a statistically significant difference (p < 0.001) (Figure 4).
Figure 3. Probability of survival of accident victims admitted to hospitalization.
Figure 4. Survival of accident victims by socioeconomic level.
3.4.3. Survival According to the Number of Organs Affected
Survival is better in accident victims with a single organ damage compared to those with two, three and four organ damage with a statistically significant difference (p < 0.001) (Figure 5).
3.4.4. Mortality Predictors
Legend: Curve 1: one organ affected; Curve 2: Two organ affected; Curve 3: three organs affected and curve 4: four organs affected
In univariate analysis of the cox regression, low and medium socioeconomic level, damage to the head, neck, thorax and abdomen were the factors predicting accident mortality. After adjustment in multivariate analysis, the low and average socioeconomic level conferred a risk of death on accident victims respectively 4 times (aHR: 3.64; 95% CI: 2.00 - 5.01, p < 0.001) and 6 times (aHR: 6.04; 95% CI: 3.60 - 10.13, p < 0.001), damage to the head and the abdomen respectively conferred a risk of death multiplied by 2, on the other hand the damage of the thorax multiplied the risk of death by 3 (Table 2).
4. Discussion
In the Democratic Republic of Congo, all vehicles can be used for public transport, sometimes without the approval documents. Also since 2008, motorcycles are introduced as a means of public transport. Mototaxis drivers, often young, are unfamiliar with the rules of the road, overload and speed to make the most of their working day. They are thus exposed to four-wheeled vehicles and more particularly to their direct competitors, taxis with whom they compete for customers. This reality justifies the multiple bodily injuries recorded in this study. Also the absence of a public transport system serving the interior of the country
Figure 5. Survival of accident victims according to the number of organs affected.
Table 2. Predictors of mortality among accident victims in the city of Kinshasa.
forces users to use goods transport vehicles, which in the event of an accident are buried by goods causing multiple and serious injuries.
More than three quarters of accident victims are polytraumatized. This rate is higher than those observed in the series of Abdou Raouf et al. [13] and Hoekman et al. [14] which are respectively 12.41% and 12.8%. This could show that road traffic accidents would be more serious here. The majority of cases of trauma were located in the limbs followed by thoraco-abdominal and cranio-encephalic trauma. These two parts of the body are the most exposed, especially in road traffic accidents involving motorcycles. Our rates are similar to those of Allode et al. [15] and Bousso et al. [16] who reported 51.61% and 53.65% respectively for limb lesions.
In this study, men and accident victims under the age of 50 were more frequently affected. Nevertheless, the literature shows that, in three out of four cases, the people who died in the road traffic accident were men and those of an economically productive age. The economic weight of road accidents is therefore not negligible [17].
Hospital mortality is very high in our series (19.6%). It is justified by the fact that accidents involving goods transport vehicles leave victims buried, but also by speeding which leads to violent shocks responsible for serious injuries. Also the victim support services are not equipped to take care of seriously injured people. In addition, the country does not have health insurance. Victims pay for medical costs and consumables, expenses unforeseeable in an accident.
The annual mortality incidence in our study was 3.1 person-years. The incidence of road traffic fatalities per person year is lower than 17.3; 8.8; 7.9; 33.2 and 7.2 person-years from Ethiopia, Rwanda, Senegal, Sierra Leone and Uganda respectively. Our incidence of death per 100,000 inhabitants is comparable to that reported in Syria in the Middle East, Morocco and Tunisia in the Maghreb Mediterranean which is in the order cited 4.5; 3.3 and 2.6 [18].
Among the predictors of this mortality, the low and average socioeconomic level, emerged as a major predictor of the mortality of accident victims. This risk persisted after adjusting for risk factors alongside organ damage such as head, thorax and abdomen. It has already been shown, however, that individuals with the lowest incomes had a risk of mortality compared to those with higher incomes [19]. The factors correlated with the socio-economic status which could explain the death are numerous, poverty having reduced the hospital care service, insufficient medication intake and lack of access to paraclinical explorations. As for lesions of the head, thorax and abdomen as predictors of mortality, it is appropriate to indicate that serious lesions of these organs could lead to death by haemorrhages, especially the hollow organs of the abdomen and thorax. or subarachnoid hemorrhages due to rupture of internal vessels in the brain.
However, this study has limitations that should be noted. The first relates to methodology, with the inclusion of only 2 hospitals out of the large number of health structures that receive casualties in the city. Interesting data must have escaped during data collection. Moreover, this study has the merit of finding the risk factors for accident mortality, on which particular attention should be drawn.
5. Conclusion
The frequency of deaths during road traffic accidents is high and the predictors of mortality are the low and average socioeconomic level on the one hand and the location of the lesions in the head, thorax and chest abdomen.
Acknowledgements
We thank all who participated in the study.
Authors’ Contributions
JMN and ANN designed and analyzed the statistical data for the study. MLN, DMK, LMB, GN, AKK, DMB and LMB supervised the study. All authors have read and approved the final and revised version of the manuscript.