Objective Hypothermia is believed to affect more than half of Ethiopian neonates. The goal of this study is to determine risk factors for newborn hypothermia in neonates admitted to public hospitals in the east Wollega zone of western Ethiopia’s neonatal intensive care unit.
Design Unmatched case–control study using neonates admitted to the intensive care unit.
Setting Neonatal intensive care units at public hospitals in western Ethiopia.
Patients Neonates admitted to intensive care units.
Main outcomes The cases were all neonates with hypothermia (less than 36.5°C) and the controls were all neonates with a body temperature of greater or equal to 36.5°C when admitted to the neonatal intensive care unit for other reasons.
Results The study involved the participation of 73 cases and 146 controls. The study found that delayed breastfeeding initiation after 1 hour (adjusted OR (AOR)=3.72; 95% CI: 1.39 to 10.00), admission weight less than 2500 g (AOR=3.43; 95% CI: 1.18 to 9.97), cardiopulmonary resuscitation at birth (AOR=3.42; 95% CI: 1.16 to 10.10.08), lack of immediate skin-to-skin contact with their mother (AOR=4.54; 95% CI: 1.75 to 11.81), night-time delivery (AOR=6.63; 95% CI: 2.23 to 19.77) and not wearing a cap (AOR=2.98; 95% CI: 1.09 to 8.15) were all associated with newborn hypothermia.
Conclusions Neonatal hypothermia was associated with obstetric, neonatal and healthcare provider factors. As a result, special consideration should be given to the thermal care of low birthweight neonates and the implementation of warm-chain principles with low-cost thermal protection in Ethiopian public health facilities.
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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What is known about the subject?
Within the first 10–20 min of birth, neonates can lose up to 2°C of their body temperature if sufficient thermal care is not provided.
In resource-constrained countries, hypothermia increases newborn mortality by five times during the first 7 days of life.
Neonatal mortality in Ethiopia was disproportionately high, ranging from 22.1 to 62.5 per 1000 live births.
What this study adds?
Neonatal hypothermia is associated with lack of skin-to-skin contact soon after birth or a delay in starting breast feeding.
Low birth weight, not wearing a cap, cardiopulmonary resuscitation, getting delivered at night and being preterm were all associated with newborn hypothermia in the study.
Neonatal hypothermia is the decrease of an axillary body temperature of the newborn below 36.5°C (97.7°F). It is classified as mild (cold stress) with body temperature between 36.0°C and 36.4°C (96.8°F–97.5°F), moderate between 32.0°C and 35.9°C (89.6°F–96.6°F) and below 32°C (<89.6°F) as severe hypothermia.1
Hypothermia occurs when the body’s physiological systems, such as vasoconstriction, shivering, muscle contraction and non-shivering thermogenesis, are no longer able to maintain a normal core temperature. Because of their higher surface area per unit body weight, large head in comparison with body and lack of subcutaneous fat (low birth weight), newborns are more likely to suffer hypothermia.1 2
If adequate heat care is not provided soon after birth, newborns can lose heat by conduction, convection, evaporation and radiation, resulting in a drop in body temperature of up to 2°C within the first 10–20 min.3 Neonates’ deep body and skin temperatures can also drop at a pace of 0.1°C and 0.3°C per minute, respectively.4 5
Neonatal mortality is more common in resource-constrained nations, where hypothermia is the leading cause of death.6 7 According to a research, every 1°C drop in body temperature increases mortality by 80%.8 Hypothermia has been identified as a substantial contributor to the worldwide burden of newborn fatalities in sub-Saharan African nations, according to the literature.9–18
Between 1990 and 2015, the under-5 mortality rate in African countries fell considerably.8 19 The rate of newborn mortality in Ethiopia has decreased from 37 to 29 fatalities per 1000 live births, according to the Ethiopian Demographic Health Survey (EDHS) 2016 report. This rate varies by area, with Addis Ababa having the lowest rate at 18 fatalities per 1000 live births and Amhara having the highest rate at 47 deaths per 1000 live births.20 However, according to the mini-EDHS 2019, the newborn mortality rate increased marginally from 29 to 30 fatalities per 1000 live births from 2016 to 2019.21
Several factors have been linked to the occurrence of hypothermia in newborns, according to research. These factors were correlated to maternal and neonatal features, as well as environmental and healthcare system characteristics.7 11 The results of previous Ethiopian studies on this topic have been equivocal.22–27
Despite the fact that predisposing factors for hypothermia are easily preventable, and several activities and intervention techniques have been devised to reduce the risk of hypothermia, the problem remains unsolved, and it is extremely common in Ethiopia (53%).11 28 As a result, the goal of this study was to determine the risk factors for newborn hypothermia in neonates born in hospitals in the east Wollega zone of western Ethiopia.
Patients and methods
Study area and subjects
The research was conducted at public hospitals in east Wollega zone, Oromia Region, western Ethiopia, which has a population of 1 598 809 people, 795 618 men and 803 191 women, and covers an area of 12 579.77 km2.29 Nekemte Specialized Hospital, Wollega University Referral Hospital, Arjo Hospital, Gida Ayana and Sire Hospital are the five public hospitals in the province. The neonatal intensive care unit (NICU) is one of the units in these hospitals where all neonates under the age of 28 days were admitted. It includes newborns referred from the labour ward and other surrounding health facilities.
A hospital-based unmatched case–control study design was conducted from 30 February to 30 April 2020. All neonates and their mothers/caregivers admitted to public hospitals in the east Wollega zone of western Ethiopia served as the study’s source population.
Cases were neonates with an axillary body temperature of less than 36.5°C at admission to the NICU during the study period at public hospitals in the east Wollega zone.1
Controls were neonates admitted to the NICU during the study period who did not have hypothermia or an axillary body temperature of greater or equal to 36.5°C.1
All neonates admitted to NICUs in public hospitals in east Wollega zone within 28 days of delivery, regardless of where they were born, were included in the study, while newborns with serious congenital malformations were omitted.
Sample size and sampling procedures
Using Epi Info V.188.8.131.52 software, the sample size for an unmatched case–control study was estimated using assumptions of a double population proportion formula. Low birth weight 2500 g, preterm (37 weeks), APGAR score at 5 min and commencement of breast feeding within 1 hour were deemed decisive variables to attain the maximal sample size in earlier studies.25 Finally, the primary exposure variable was the proportion of controls who started breast feeding within 1 hour. As a result, the final sample size was 219 neonates and their mothers/caregivers (73 cases and 146 controls), which was the largest sample size estimated.
The study subjects were chosen using a consecutive selection procedure from five public hospitals during the course of the study period until the predetermined sample size was reached. Cases and controls were chosen from the same health facility on consecutive days. Based on cases received from the NICU registration book in the previous 2 months of the study, the sample was proportionally allocated to each study site. During the study period, we did not encounter a mother with two or more babies for this particular study.
Data collection tools and data collectors
The data collection questionnaire was written in English and subsequently translated into Afaan Oromo, the regional working language. Using structured questionnaires presented by an interviewer, data were obtained from mothers, newborns and charts of neonates admitted to the NICU (online supplemental appendix). Two Bachelor of Science nurses and three midwives who have previous experience of data collection and can fluently speak Afaan Oromo were recruited from maternal and child health department to collect the data. Three supervisors were on hand during the data collection period to provide continuous follow-up and supervision. To distinguish cases from controls, a digital thermometer was used, which measured the surface temperature at the axilla location in accordance with WHO recommendations.
Prior to data collection, a pretest was performed on 5% of neonates admitted to the NICU at Shambu Hospital. The tool’s reliability was tested, yielding a Cronbach’s alpha of 0.73. Data collectors and supervisors received 2 days of training on how to collect data. The measurement was then double-checked with reference thermometers every day to avoid any misleading readings caused by thermometer deterioration. Following data collection, supervisors and the principal investigator reviewed and checked the questionnaires for completeness on a regular basis. To limit the possibility of data-entering errors, EpiData V.3.1 was employed. Each and every questionnaire was cross-checked with the entered data and all observed errors were corrected.
Dependent variable: neonatal hypothermia.
Independent variables: maternal sociodemographic/economic determinants, neonatal-related determinants, neonatal caring practices, obstetric determinants.
Statistical analysis and processing
Data were entered into EpiData V.3.1, cleaned and double-checked for completeness and consistency, and exported to SPSS Windows V.25.0 for analysis. A bivariable analysis was performed to identify candidate variables associated with neonatal hypothermia, and variables with p values less than 0.25 were transferred for multivariable logistic regression to determine hypothermia risk factors (online supplemental tables 1 and 2). The model’s goodness of fit was evaluated using the Hosmer-Lemeshow test, which yielded a p value of ≥0.05. Variance inflation factors were used to test the variables’ multicollinearity. The analysis was adjusted for mother’s age. Crude and adjusted ORs with a 95% CI and a p value of <0.05 were considered statistically significant.
Patient and public involvement
Neither patients nor the public were involved in the design, analysis and interpretation of this study and will not be involved in the dissemination of the results.
Sociodemographic/economic characteristics of mothers
In this study, 73 neonates who had hypothermia with their mothers (cases) and 146 neonates who did not have hypothermia with their mothers (controls) were included. The mean age of the mothers in cases was 24.88 years (SD 4.39), and the age of the mothers in controls was 25.62 years (SD 4.69). Thirty-six (49.3%) of case mothers and 76 (52.1%) of control mothers lived in rural areas (table 1).
Factors associated with neonatal hypothermia
According to this study, the odd of hypothermia was 3.43 times higher in those weighing less than 2500 g compared with those weighing more than 2500 g (adjusted OR (AOR)=3.43; 95% CI: 1.18 to 9.97). Birth resuscitation was also a significant risk factor for neonatal hypothermia. The odds of hypothermia were 3.42 times higher among those who were resuscitated at birth (cardiopulmonary resuscitation (CPR)) compared with those who did not (AOR=3.42; 95% CI: 1.16 to 10.08).
Furthermore, the odd of hypothermia was 3.72 times (AOR=3.72; 95% CI: 1.39 to 10.00) higher among neonates who were initiated breast feeding compared with those who were initiated before 1 hour after birth. Similarly, the odd of hypothermia was more than three times higher in those who do not wear cap than controls (AOR=2.98; 95% CI: 1.09 to 8.15).
Lack of skin-to-skin contact with mothers after delivery was another significant determinant of neonatal hypothermia. Those who do not have skin-to-skin contact with their mother after birth were 4.54 times higher to develop hypothermia compared with their counterparts (AOR=4.54; 95% CI: 1.75 to 11.81). Also, the odd of developing hypothermia was about seven times higher in those who were born during the night compared with those who were born during the day (AOR=6.63; 95% CI: 2.23 to 19.77) (table 2).
One of the risk factors for newborn hypothermia, according to this study, was delayed commencement of breast feeding. This finding is supported by research from Tigray, north Ethiopia, Zambia and southern Nepal.25 30 31 The association could be related to the fact that early breast feeding allows babies to have more skin-to-skin contact with their mothers, prevents the newborn from being exposed to the environment and increases mothers’ follow-up care for their babies, all of which help to prevent hypothermia.32 Another reason could be that breastfed newborns obtain enough calories from their mother’s milk, which produces heat for thermoregulation, so the more they are breast fed, the more glucose they get to meet their energy needs.33 Lack of skin-to-skin contact with their mother shortly after birth was another significant risk factor for newborn hypothermia in this study, which supports this finding. The findings are also supported by the literature.22 31 34 This is because newborns who do not have skin-to-skin contact with their mothers lose more heat through conduction, even when their mother’s external body temperature is nearly identical to their womb temperature.35 Furthermore, skin-to-skin contact is more successful than incubator care for rewarming the infant because the maternal chest and abdomen movement promotes the newborn to breathe more deeply, which improves heat generation via oxidative phosphorylation.1
This finding, however, contradicted other Ethiopian findings.23 This variance could be related to differences in delivery location, study context and study methodology. According to the study, all mothers delivered at health facilities, although 9.1% of the mothers delivered at home in this study.
Low birth weight at admission was found to be a risk factor for newborn hypothermia in this study. This finding is consistent with research done in Ethiopia’s Arba Minch, South Nations and Nationalities, and Gondar, Amhara area.24 26 This conclusion was also corroborated by research undertaken in Iran and Pakistan.36 37 This could be due to a variety of factors, including radiant heat loss (when bare skin is exposed to a cooler environment), evaporative heat loss (when neonates are wet with amniotic fluid shortly after birth), conductive heat loss (when neonates are placed in contact with a cool surface or object) and convective heat loss (when a flow of cooler ambient air carries heat loss, a flow of cooler ambient air carries heat away from the neonate).2
The timing of delivery was also revealed to be a risk factor for newborn hypothermia in this study. Those whose mothers gave birth at night had a greater chance of experiencing hypothermia than those whose mothers gave birth during the day. This is supported by research from Gondar, northwest Ethiopia, Tigray, north Ethiopia and Uganda.25 26 38 This could be owing to the fact that night-time room temperatures are lower than daytime temperatures, or it could be due to temperature differences between night and day.39 Additionally, work overload during the night could be a factor, as the number of staff working in the labour room at night is not equivalent to the number of staff working during the day.
Furthermore, neonatal hypothermia was associated with children who received CPR at birth. This result is consistent with research from Addis Ababa, Ethiopia, Iran and Bangladesh.22 34 40 This is because neonates who require resuscitation have undergone birth asphyxia; there is insufficient oxygen for mitochondrial oxidation in brown adipose tissue, which is required for heat production.2 In addition, temperature regulation during resuscitation at birth may not be effectively addressed; in an emergency, resuscitation may be performed without wrapping the newborn and on a cold surface. This result, however, is contradicted by a research conducted in Arba Minch, southwest Ethiopia.24 This discrepancy could be attributable to differences in thermal care during resuscitation, warm resuscitation, resuscitation period and study methodology.
Neonates who did not have their heads covered after delivery had a higher risk of developing hypothermia than those who did. This conclusion was similar to that of a research conducted in Harar, Ethiopia’s eastern region.23 This could be owing to their huge skull, which has open fontanels and sutures, and contributes to nearly 25% of neonatal heat loss if not covered by a cap.3
Even though the study was conducted in different hospitals, it was only done for a short period or in one season, therefore considerations such as climatic changes or seasonal variations were not taken into account. Another drawback of this study was that hospital-related characteristics like the abilities and qualifications of healthcare personnel working in delivery rooms and NICUs, which may have been linked to hypothermia, were not taken into consideration. There could also be an effect of recall bias.
The study found that delayed breastfeeding initiation, neonatal weight less than 2500 g on admission, lack of skin-to-skin contact with mothers at birth, cardiopulmonary situations at birth, being born at night and not wearing a cap immediately after birth were all significantly associated with neonatal hypothermia on admission to NICUs.
Data availability statement
Data are available upon reasonable request.
Patient consent for publication
The study was approved by the Institutional Review Boards of Wollega University (ref no. DPH/362/2012). Written informed consent was obtained from the study participants.
We want to extend our gratitude to Wollega University, the data collectors and study participants.
Contributors BG, BET, TTB and BRF conceptualised and designed the study, collected the data and wrote the results. BRF wrote the manuscript draft. BG, BET and TTB reviewed the manuscript. All authors read and approved the final manuscript.
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; externally peer reviewed.
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