Burns are a serious public health problem worldwide accounting for an estimated 265,000 deaths annually from fires alone. The vast majority (96%) of deaths from fire-related burns occur in low- and middle-income countries and burns are one of the leading causes of disability-adjusted life-years (DALYs) in the developing world. Most burn centres are situated in large cities and are inadequate for the high incidence of injuries. An 8 year review of 440 patients in the Douala General Hospital, showed that the majority of patients burned were males (n = 281, 68.9%), the mean age was 25.2 ± 17.77 years with an admission rate of 69.5% (306 patients). The modal and median age were 31.0 years and 25.0 years respectively, interquartile range (0.4–82). Majority of burns (n = 237, 53.9%) had burn surface area ≥ 10%, most burns were 2nd degree (n = 215, 48.9) and the commonest burn agents were flames (n = 170, 37.3%), electricity (n = 119, 26.3%) and water (n = 114, 25.2%). The paucity of data on burn mortality in Cameroon motivated this study and is aimed at determining the mortality rate, causes and factors associated with death of burnt patients in the burn unit of the Douala General Hospital (DGH).
Methods
It was a retrospective observational study carried out from the 1st of January 2008 to the 31st of December 2015 in the Burn Unit of the Douala General Hospital. An adapted questionnaire was used to collect demographic data, burn agents, burn depth; diagnostic delay, burn surface area, complications, comorbidity, mortality and its causes. Data was transferred to Microsoft Excel 2015 and the Statistical Package for Social Sciences (SPSS) version 20.0 for data analysis.
Results
During this 8 year period, 440 patients were studied and the mortality rate was 23.4% (103 patients). The fatal burn agents were, flames (n = 69, 67.0%), electricity (n = 15, 14.6%), water (n = 12, 11.6%), contact (n = 4, 3.9%), Oil (n = 2, 1.9%) and chemicals (n = 1, 1.0%). The causes of death were shock (n = 36, 35.0%), sepsis (n = 25, 24.3%), acute respiratory distress (n = 25, 24.3%), acute renal failure (n = 6, 5.8%), severe anaemia (n = 4, 3.9%) and unrecorded causes (n = 7, 6.7%).
Conclusion
A quarter of all patients died mostly from flame burns and to a lesser extent, electricity and scalds. Increase in burn depth and burn surface area worsened the prognosis. Shock (the commonest cause of death), sepsis, acute respiratory distress, acute renal failure and wound infection were significantly associated with mortality.
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Abkürzungen
ARD
Acute Respiratory Distress
Background
Burns are a serious public health problem worldwide accounting for an estimated 265,000 deaths annually from fires alone [1]. Burns are the leading causes of disability-adjusted life-years (DALYs) lost in low- and middle-income countries [1]. In 2004, about 11 million people worldwide suffered from burns, severe enough to require medical attention [2].
The vast majority (over 95%) of fire-related burns occur in low- and middle-income countries, particularly in Africa and little attention is paid to paediatric injuries [3, 4]. Burn injuries are a major cause of prolonged hospital stays, disfigurement, disability, and death in Africa [3].
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Most of the advances in prevention and care have been incompletely applied in low- and middle-income countries. Increased efforts to do so would probably lead to significant reductions in rates of burn-related death and disability [1]. In order to address this public health problem, the World Health Organization (WHO) has launched A WHO plan for burn prevention and care. WHO would like to promote in terms of: advocacy, policy, data and measurement, research, prevention, health-care services for victims and capacity building. It includes activities that WHO itself commits to undertake in the near future as well what the entire field of burn prevention and control should be accomplishing in the coming decade [5].
Most burn centres are situated in large cities and are inadequate for the high incidence of injuries. Resuscitation is often delayed as patients have to travel long distances and transport facilities are poor. Many burn centres are also plagued with lack of resources, lack of operating time, and shortage of blood [6].
In 2014, the mortality outcome predictions in high income countries were lower than those in the DGH using the Abbreviated Burn Severity Index (ABSI) in patients admitted at the Douala General Hospital [7]. Burns and scalds are common presentations in Cameroonian health institutions but many of these patients however end with severe morbidity or even death or thrown into further poverty [5, 8]. Fire is the 20th leading condition responsible for Years of Life Lost (YLLs) in Cameroon, 107 (1%) in 2013 [9].
The paucity of data on burn mortality in Cameroon motivated this study and is aimed at determining the mortality rate, causes and factors associated with death of burnt patients in the burn unit of the Douala General Hospital (DGH).
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Methods
Study design and setting
This study was a retrospective observational study of files in the Burn Unit of the Douala General Hospital (Cameroon) from January 1st 2008 to December 31st 2015.
This hospital is a referral hospital in the Cameroonian health system and has the only burn centre in the public sector. There are 3 hospitalisation units attributed for mild, moderate and severe burns admitted based on the American Burn Association (ABA) classification, 2 water therapy rooms and 1 operating theatre. The Unit is headed by an Anaesthetist specialised burn management assisted by a team of surgeons, anaesthesiologists, general practitioners, nurses, nutritionists, psychiatrists, nursing aids and support staff. All burn patients arriving at the DGH are ushered at the Burn Unit for immediate management. Demographic data is collected by a receptionist, history, physical examination and management prescribed by the physicians. Treatment protocol is patient dependent and the fluid management protocols usually follow Parkland Hospital’s formula, Carvajal’s Rule and Evan’s Formula. Medical treatment was through the variable use of antibiotics, analgesics, high protein and carbohydrate diet, blood transfusions, iron supplementation, stress ulcer prophylaxis etc. Surgical treatment comprised of wound debridement, skin grafting, amputations, fasciotomy, and wound care with trolamine, petroleum gel and antiseptic solutions.
Study population
The study population was made up of burn patients treated in the burn centre between the 1st of January 2008 and the 31st of December 2015.
Inclusion criteria
All burned patients attended-to during the study period.
Exclusion criteria
All inadequate or incomplete files such as absence of age, sex, diagnosis, outcome, burn depth, burn surface area, management plan and destroyed files.
Patients treated for Lyell’s Syndrome.
Data collection & statistical analysis
The variables of each patient were extracted from the hospitalisation files (such as age, sex, time of arrival after injury, burn circumstance, burn surface area, burn depth, complications and outcome) then filled in the questionnaire. This information was transferred from the questionnaire into Microsoft Office Excel Worksheet 2015 and then coded into the Statistical Package for the Social Sciences (SPSS) version 20.0.The Pearson Chi-square was used to determine associations between categorical variables and mortality with the level of significance set at 0.05 (95% confidence interval).
Unavailability of explicit information on the presence of inhalational injuries from the case files.
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Results
During this 8 year period, 440 patients were studied, most being males (n = 281, 68.9%) and the admission rate was 69.5% (306 patients) [10]. The modal and median ages were 31.0 years and 25.0 years respectively, interquartile range (0.4–82). Majority of burns (n = 237, 53.9%) had burn surface area ≥ 10%, almost half (n = 215, 48.9) of all burns were 2nd degree and the commonest burn agents were flames (n = 170, 37.3%), electricity (n = 119, 26.3%) and water (n = 114, 25.2%) [10].
The mortality rate of this study was 23.4% (103 patients).
From this study, sex and age didn’t influence mortality. (See Tables 1 and 2).
Table 1
Sex distribution of patients who died
Sex
Survival (%)
Death (%)
Total (%)
p-value
Male
214 (63.7)
67 (65.1)
281 (63.9)
Female
122 (36.3)
36 (34.9)
159 (36.1)
0.467
Total
337 (76.6)
103 (23.4)
440 (100.0)
Table 2
Age distribution of patients who died
Age
Survival (%)
Death (%)
Total (%)
p-value
0–10
97 (28.8)
23 (22.3)
120 (27.3)
11–20
50 (14.8)
13 (12.6)
63 (14.3)
21–30
64 (19.0)
21 (20.4)
85 (19.3)
31–40
72 (21.4)
23 (22.3)
95 (21.6)
41–50
29 (8.6)
12 (11.7)
41 (9.3)
51–60
15 (4.6)
6 (5.9)
22 (5.0)
0.541
61–70
6 (1.8)
2 (1.9)
8 (1.8)
71–80
3 (1.0)
2 (1.9)
5 (1.2)
> 80
0 (0.0)
1 (1.0)
1 (0.2)
Total (%)
377 (76.6)
103 (23.4)
440 (100.0)
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Of the 166 patients burned by flames, many (n = 69, 41.6%) died and generally, flame burns accounted for the majority of deaths (n = 69, 66.3%) in this study (See Fig. 1):
Fig. 1
Distribution of patients who died according to burn agent
×
Flames, water and electricity were significantly associated with mortality as shown below (See Table 3):
Table 3
Burn agents and mortality
Burn Agent
Survival (%)
Death (%)
Total (%)
p-value
Water
94 (27.9)
12 (11.7)
106 (24.1)
0.001
Oil
22 (6.5)
2 (1.9)
24 (5.5)
0.031
Flame
97 (28.7)
69 (67.0)
166 (37.7)
0.001
Chemical
7 (2.1)
1 (0.9)
8 (1.8)
0.496
Electrical
102 (30.3)
15 (14.6)
117 (26.4)
0.001
Contact
15 (4.5)
4 (3.9)
19 (4.5)
0.033
Total
337 (76.6)
103 (23.4)
440 (100.0)
–
Burn depth influenced mortality as all the forms were statistically associated to mortality (p = 0.001). Nonetheless, it was demonstrated that having a 1st degree burn had a negative correlation with death but an increase in burn depth from 2nd to 3rd degree increased the propensity to a fatal outcome. (See Table 4).
Table 4
Distribution of patients who died according to burn depth
Burn deptht
Survival (%)
Death (%)
Total (%)
p-value
R
First degree
123 (36.5)
8 (7.8)
131 (29.8)
0.001
−0.310
Second degree
147 (43.6)
68 (66.0)
215 (48.9)
0.001
+ 0.268
Third degree
66 (19.9)
27 (26.2)
93 (21.3)
0.001
+ 0.364
Total
337 (76.6)
103 (23.4)
440 (100.0)
–
–
The total body surface area burnt was also statistically associated to mortality. (See Table 5).
Table 5
Mortality according to burn surface area
% Burn surface area
Survival (%)
Death (%)
Total (%)
p-value
0–9
199 (59.0)
2 (1.9)
201 (45.6)
10–19
63 (18.7)
4 (2.9)
67 (15.2)
20–39
55 (16.3)
24 (23.3)
79 (18.0)
40–59
17 (5.1)
25 (24.3)
42 (9.6)
> 0.001
≥60
3 (0.9)
48 (46.6)
51 (11.6)
Total
337 (76.6)
103 (23.4)
440 (100.0)
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The time of arrival after injury was statistically significant with respect to mortality for those who came to the burn unit between 25 to 48 h after injury (See Table 6).
Table 6
Mortality according to time of arrival after injury
Time
Survival (%)
Death (%)
Total (%)
p-value
0–1 h
150 (44.5)
33 (32.0)
183 (40.4)
0.005
2–8 h
92 (27.2)
29 (28.1)
121 (26.7)
0.040
9–24 h
28 (8.3)
22 (21.4)
54 (11.9)
0.758
25–48 h
26 (7.7)
7 (6.9)
33 (7.5)
0.001
> 48 h
40 (11.9)
12 (11.6)
52 (13.5)
0.733
Total
337 (76.6)
103 (23.4)
440 (100.0)
0.005
Many patients experienced complications during this 8 year time frame. The table below shows which of the complications were statistically significant with mortality (See Table 7). The presence of comorbidities didn’t influence mortality in this study (p = 0.658) (See Table 8).
Table 7
Mortality with respect to complications faced
Complications
Survival (%)
Death (%)
Total (%)
p-value
Shock
12 (8.3)
85
97 (223)
0.001
Sepsis
34 (23.4)
28
62 (14.3)
0.001
Acute respiratory distress
6 (4.1)
51
57 (13.1)
0.001
Anaemia
34 (23.4)
19
53 (12.2)
0.017
Acute renal failure
1 (0.7)
14
15 (3.4)
0.001
Wound infection
12 (8.4)
85
97 (22.3)
0.001
Gangrene
46 (31.7)
8
54 (12.4)
0.086
145 (33.3)
290
435 (100)
Table 8
Mortality and presence of comorbidity
Presence
Survival (%)
Death (%)
Total (%)
p-value
Yes
6 (1.80
1 (1.0)
7 (1.6)
Comorbidity
0.658
No
33 (98.2)
102 (99.0)
444 (98.0)
Total
337 (76.6)
103 (23.4)
440 (100.0
The main causes of death were shock (n = 36, 35.0%) followed by sepsis (n = 25, 24.3%), acute respiratory distress (n = 25, 24.3%) and others. (See Fig. 2).
Fig. 2
Distribution of burn mortality causes
×
Discussion
This paper presents an 8 year review of burn mortality in the Burn Centre of the Douala General Hospital in Cameroon. The mortality rate of this study was 23.4%. For studies which had a higher mortality rate than that of this study; according to Amengle et.al, the mortality was 41.2% due to the high incidence of severe burns in these children [11]. Kalayi in Zaria, Nigeria had a mortality rate of 35% was because 52% of admissions were children below the age of 5 years with severe burns [12]. Nguema et.al, in Gabon had a death rate of 54.8%. This was because this study was conducted in an intensive care unit [13]. Soltani et.al, in Tehran, Iran had a mortality rate of 59.48% because patients with below 40% of burned surface constituted 52.5% of injuries so more cases of severe burns [14].
This was similar to other studies in Cameroon, Nigeria and Morocco [15‐19] which can be a reflection of the health care system in low and middle-income countries as the aforementioned countries are generally at the same stage of economic development. This study’s mortality rate was lower than other studies in Cameroon, Nigeria, Ghana and Iran [11‐14] as the later compared involved more of severe burns. On the other hand, mortality rate of this study was higher than that of other studies in Nigeria, Singapore and China [20‐22]. The disparity in mortality rates between the burn centre in Cameroon and others in China or Singapore; calls for urgent reforms in the Cameroonian health system via health promotion in schools, work place and improvement of fire protection systems in public places.
For studies which had a lower mortality rate than that of this study; Dongo et.al, conducted a study in Irrua, Nigeria in 2007 revealed a revealing a 9.72% mortality rate [21]. Song & Chua in Singapore had a mortality rate of 4.61%. This was because patients with burn size 10% TBSA and less made up the majority of admissions at 70.7% while patients with burn size 30% TBSA and more made up 8.2% [22]. Jie & Baoren in China had an overall mortality rate of 0.86%. The high survival rate, may relate primarily to the low percentages of older patients and of patients with severe burns [23].
Mortality in males 64.4% was higher than that in females 35.6%. This is similar to a study conducted by Olaitan & Jiburum in Nigeria [16]. In our study, it was found that sex and mortality were not statistically significant (p = 0.467). The highest mortality rate was the 0–10 and the 31–40 years age group (22.1%) followed by the 21–30 years age group (20.1%) and the lowest being those aged above 80 years; this is similar to results obtained Olaitan and Jiburum, where age and mortality were not statistically significant with p = 0.541. It is no secret, males are usually more active, adventurous and hence, exposed to higher risks.
From this study, the percentage survival drops as the burn surface area increases. This is because the more the surface area burned, the more fluids lost, more liability to infection and multiple organ failure. This was statistically significant in this study with p < 0.001.
In this study, shock (34%) was the most common cause of death, sepsis (24%), acute respiratory distress (24%), severe anaemia (4%), and acute renal failure (6%) and in 8% no specific cause of death was indicated. This is unlike a study conducted by Olaitan & Jiburum in Nigeria where acute renal failure (24 cases, 42.1%) was the commonest cause of death, septicaemia (18 cases, 31.6%), acute respiratory syndrome (5 cases, 8.7%), shock (4 cases, 7.0%), and upper gastrointestinal bleeding due to peptic ulcer and severe anaemia (1 case each, 1.8%) and in four cases (7.0%) no specific cause of death was indicated [16]. Martina & Wardhana in Indonesia, found out that death was caused by septicaemia (42.1%), multiple organ failure (31.6%), systemic inflammatory response syndrome (17,6%), and acute respiratory distress syndrome (8.7%) [23].
In this study mortality with respect to complications was statistically significant with shock, sepsis, acute respiratory distress, and acute renal failure and wound infection (all with p < 0.001) and should remain alert signs for physicians so as improve clinical care and reduce mortality.
Most patients (31.7%) who died came in within 0 to 1 h. This is because severe burns are generally rapidly rushed to the hospital, in this case, the Douala Burn Centre. This is could be due to delayed referral from primary hospital care, ignorance and poverty. Generally, referrals are a herculean task in Cameroon due to the unavailability of ambulances, lack of knowledge on availability of certain services by the patients and lack of intercommunication between health facilities and a food for thought for the ministry of public health. In this study, mortality was statistically significant with those who came 25–48 h after burn (p<0.001) this is probably because many patients were referred still unstable.
Study strengths
This was a comprehensive 8 year overview of burn mortality in a major burn centre in Cameroon with suggestions to improve the healthcare system.
This study comes to add scientific information in a country with little data available on burn mortality.
Study limitation
This study entailed going into hospital files, some data were not present such as the presence or not of inhalational injury and follow-up notes following discharge; relying on these, made assessment of complications and outcome following discharge not feasible.
Conclusion
Mortality in burn patients in our setting is high as a quarter of all patients died (mostly from flame, electricity and water burns); which calls for improvements in the health care delivery sector and general sensitisation. A prospective study is also needed for an improved assessment of the effects of the different variables on burn mortality. Increase in burn depth and burn surface area reduced survival rates. Shock (the commonest cause of death), sepsis, acute respiratory distress, acute renal failure and wound infection are alert signs which physicians need to continue paying attention to in burned patients.
Acknowledgements
The authors have nothing to acknowledge.
Ethics approval and consent to participate
Ethical clearance was issued by the Institutional Ethics Committee for Research on Human Health of the University of Douala (IEC-UD), Cameroon. Reference number: IEC-UD/452/02/2016/T on the 25th of February 2016 in Douala, Cameroon. The need for consent from patients was waived by the aforementioned IRB.
Consent for publication
Not applicable in this section.
Competing interests
The authors declare that they have no competing interests.
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