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Health Services Insights
Volume 17: 1–7
© The Author(s) 2024
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sagepub.com/journals-permissions
DOI: 10.1177/11786329241258836

Introduction
Children in sub-Saharan Africa (SSA) have an increased 
chance of dying in their first month of birth, according to the 
World Health Organization (WHO).1 Roughly 4 million 
deaths of children under 5 years of age are believed to have 
occurred in low- and middle-income nations. This figure rep-
resents approximately 99% of these deaths, with approximately 
60% of this number related to neonatal death. Ghana did not 
meet any of the two Millennium Development Goals (MDGs) 
four or five due to the slow development rate in reducing the 
death rate of children under 5 years of age. Sixty-eight percent 

of neonatal deaths and 48% of deaths in children under 5 years 
of age are attributed to neonatal mortality.1 Ghana’s neonatal 
death rate was predicted to be 25 per 1000 live births in the 
WHO Ghana Annual Report 2019. Despite this, Ghana has 
made impressive strides in the fight against neonatal and 
under-5 mortalities.2

Nwokoro et al.3 revealed that children dying below 5 years 
are an important indicator of health and an indispensable 
development measure for countries. Globally, under-5 and 
neonatal mortality rates have drastically decreased to 39 deaths 
per 1000 live births from 93 deaths per 1000 live births from 

Assessment of Neonatal Mortality and Associated 
Hospital-Related Factors in Healthcare Facilities  
Within Sunyani and Sunyani West Municipal  
Assemblies in Bono Region, Ghana

Kassim Tawiah1,2 , Killian Asampana Asosega1,2, Samuel Iddi3,  
Alex Akwasi Opoku1, Iddrisu Wahab Abdul4, Richard Kwame Ansah1,5 , 
Francis Kwame Bukari1,2, Eric Okyere1 and Atinuke Olusola Adebanji2
1Department of Mathematics and Statistics, University of Energy and Natural Resources, Sunyani, 
Ghana. 2Department of Statistics and Actuarial Science, Kwame Nkrumah University of Science 
and Technology, Kumasi, Ghana. 3Department of Statistics and Actuarial Science, University of 
Ghana, Accra, Ghana. 4Department of Mathematics and Statistics, Ghana Communication 
Technology University, Accra, Ghana. 5Department of Mathematics, Kwame Nkrumah University 
of Science and Technology, Kumasi, Ghana. Samuel Iddi is also affiliated to African Population 
and Health Research Center, Data Synergy and Evaluation Unit, Nairobi, Kenya.

ABSTRACT

OBjeCTiveS: Ghana’s quest to reduce neonatal mortality, in hospital facilities and communities, continues to be a nightmare. The pursuit of 
achieving healthy lives and well-being for neonates as enshrined in Sustainable Development Goal three lingered in challenging hospital facili-
ties and communities. Notwithstanding that, there have been increasing efforts in that direction. This study examines the contributing factors that 
hinder the fight against neonatal mortality in all hospital facilities in the Sunyani and Sunyani West Municipal Assemblies in Bono Region, Ghana.

MeTHOdS: The study utilized neonatal mortality data consisting of neonatal deaths, structural facility related variables, medical human 
resources, types of hospital facilities and natal care. The data was collected longitudinally from 2014 to 2019. These variables were analysed 
using the negative binomial hurdle regression (NBH) model to determine factors that contribute to this menace at the facility level. Cause-
specific deaths were obtained to determine the leading causes of neonatal deaths within health facilities in the two municipal assemblies.

ReSulTS: The study established that the leading causes of neonatal mortality in these districts are birth asphyxia (46%), premature birth 
(33%), neonatal sepsis (11%) and neonatal jaundice (7%). The NBH showed that neonatal mortality in hospital facilities depend on the num-
ber of incubators, monitoring equipment, hand washing facilities, CPAPb machines, radiant warmers, physiotherapy machines, midwives, 
paediatric doctors and paediatric nurses in the hospital facility.

CONCluSiONS: Early management of neonatal sepsis, birth asphyxia, premature birth and neonatal infections is required to reduce neo-
natal deaths. The government and all stakeholders in the health sector should provide all hospital facilities with the essential equipment and 
the medical human resources necessary to eradicate the menace. This will make the realization of Sustainable Development Goal three, 
which calls for healthy lives and well-being for all, a reality.

KeyWORdS: Sustainable Development Goal three, hospital records, neonatal mortality, mixture models, infections, hospital facilities, gov-
ernment, health

ReCeived: August 17, 2023. ACCePTed: May 16, 2024.

TyPe: Original Research

FuNdiNG: The author(s) received no financial support for the research, authorship and/or 
publication of this article.

deClARATiON OF CONFliCTiNG iNTeReSTS: The author(s) declared no potential 
conflicts of interest with respect to the research, authorship and/or publication of this article.

CORReSPONdiNG AuTHOR: Kassim Tawiah, Department of Mathematics and Statistics, 
University of Energy and Natural Resources, P.O. Box 214, Sunyani GH, Ghana.  Email: 
kassim.tawiah@uenr.edu.gh

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research-article2024

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2 Health Services Insights 

1990 to 2018.1 These feats were not observed in all countries 
due to disparities in child survival rates from birth to 59 months 
compared to resource inequalities among countries.4,5 The 
SSA region is associated with sky-high rates of under-5 and 
neonatal mortality rates across the world.6,7 Intrinsically, the 
SSA region recorded 1 death for every 13 live births compared 
to 1 death for every 199 live births in developed countries.1

In most cases, significant causes of deaths related to under-
5 years have been shown throughout the world. Most neonatal 
deaths have been attributed to pneumonia, diarrhea, pregnancy 
complications and malaria, as well as neonatal sepsis.8,9 Several 
studies have further linked death of children under-5 years in 
SSA to preventable intermediaries such as maternal age at 
birth, where delivery occurred, place of residence, weight of 
child at birth, count of antenatal care attendance and access to 
assistance during delivery.9,10

Bogdewic et al.11 revealed that systematically strengthening 
hospital facilities with essential human resources and medical 
equipment can potentially reduce neonatal mortality. Again, 
Owen et al.12 identified critical gap in postnatal care education 
that must be addressed seriously. They stressed that these iden-
tifiable problems can be diagnosed by well-resourced health 
facilities and serious complications can be prevented. Owen et 
al.12 were of the view that pre-discharge counselling must be 
improved in Ghana so that neonates will have better survival 
chances in critical periods.

The Ghana Health Service (GHS) launched the Make 
Every Baby Count Initiative (MEBCI) in 2013 on a 5-year 
basis. This initiative was based on a curriculum from the 
American Academy of Paediatrics Helping Babies Breathe 
and Essential Care for Every Baby programme with the 
inclusion of prevention of infections. The programme 
trained 3688 health workers from the Brong Ahafo Region 
(now Bono, Bono East and Ahafo Regions), Volta Region 
(now Volta and Oti Regions), Eastern Region and Ashanti 
Region on resuscitation, essential neonates care and infec-
tion treatment.13 Though this programme made a great 
impact, there are still bottlenecks in this fight for the sur-
vival of neonates.

There is a higher risk of neonates dying in their early 
stages.14 Abdul-Mumin et al.15 observed that the majority of 
neonatal deaths in these early stages are from preventable 
causes. Moreover, Aheto16 indicated that the Northern Region 
(now Northern, North East and Savanna Regions), the Upper 
East Region, the Upper West Region and the Brong Ahafo 
Region (now Bono, Bono East and Ahafo Regions) have the 
highest mortality for children under 5 years of age among all 
regions in Ghana. This is not surprising because there exist 
great disparities and inequalities in access and distribution of 
maternal and child care services in rural-urban communities.17 
Forestalling deaths by asphyxia and infections should be 
focused, while essential post-delivery care and wellbeing of 
neonates prioritized.18

Existing studies conducted in Ghana on neonatal mortality 
and its related dynamics are mainly exploratory.14,19-21 These 
studies did not include structural facility-related variables, 
medical human resources, hospital facility types and natal care 
at the same time. Addressing neonatal mortality requires 
proper maternal and child health care services.22,23 This is lack-
ing in most Ghanaian hospital facilities, especially in the Bono 
Region of Ghana. Ghana continues to fight against neonatal 
mortality in hospital facilities and communities throughout the 
country. However, efforts by the government and its stakehold-
ers have not yielded the needed results. It is against this back-
drop that this study is carried out in two municipal assemblies 
to identify areas where the government and its stakeholders can 
channel their efforts to achieve the Sustainable Development 
Goal three (SDG 3) which aims to ensure the end of avoidable 
deaths of neonates and children under-5 years of age.

This paper seeks to assess the impact of structural facility-
related variables, medical human resources, types of hospital 
facility and natal care on neonatal mortality in the Bono region 
of Ghana. The study used data from health facilities within the 
Sunyani and Sunyani West municipal assemblies. This assess-
ment will help the government and its stakeholders provide the 
necessary intervention to ensure the survival of all neonates. 
The hurdle model was applied to the neonatal mortality data 
due to the excessive number of zeros in the facility-level data.24-28 
Cause-specific neonatal deaths as documented by medical pro-
fessionals were also ascertained and reported.

Materials and Methods
Data

We used Sunyani and Sunyani West Municipal Assemblies in 
the Bono Region of Ghana as our study area, since most of the 
prominent hospital facilities in the Bono Region are located in 
these assemblies. Furthermore, the two districts account for 
most of the health facilities in the entire region.

Retrospective neonatal mortality data was collected longitu-
dinally from hospital records and reports in all hospital facili-
ties in the two municipalities. For the study, factors associated 
with healthcare facilities and cause-specific deaths were used 
with the official permission of health facility heads and admin-
istrators, as well as regional and district health directorates. The 
Human Research and Ethics Committee of the University of 
Energy and Natural Resources provided ethical approval for 
the study and waived all consent.

The dependent variable in the data is the number of neona-
tal deaths per year in all health facilities in the two assemblies. 
The independent variables included can be classified into four 
main parts: structural facility-related variables, medical human 
resources, hospital facility types and natal care. Structural facil-
ity-related variables included the existence of a neonatal inten-
sive care unit (NICU), the number of hand washing facilities 
(HW), the existence of emergency obstetric care (EOC), the 



Tawiah et al 3

existence of a planned parental clinic/family planning center 
(PPC / FPC), the number of radiant warmers (RM), the num-
ber of monitoring equipment (ME), the number of blood gases 
(BG), the number of incubators (I), the number of bassinets 
(COTS), the number of haematocrit equipment (HE), the 
number of ventilators (V), the number of CPAPb machines 
and the number of phototherapy machines (PM). The medical 
human resources included the number of paediatric nurses 
(PN), the total number of midwives (MW) and the total num-
ber of paediatric doctors (PD) in the health facility. The types 
of hospital facilities included hospitals and clinics. Health cen-
tres, community health planning service compound (CHPS), 
maternity homes and similar health facilities were classified as 
clinics. In total, four hospitals and nineteen clinics participated 
in the study. The 23 health facilities included in the study were 
the major health facilities in the 2 municipal assemblies. Natal 
care involved the number of antenatal visits exceeding 4 and 
the number of postnatal visits exceeding 4.

The data was thoroughly cleaned before further analysis was 
performed. Stepwise deletion in R was used to remove all inde-
pendent variables that do not greatly influence neonatal deaths 
during data cleaning and preliminary analysis. As a result, few 
variables related to structural facilities (HW, I, PH, HW, ME, 
PM, COTS, RM and CPAPb) and all medical human resources 
were included. The type of health facilities and natal care were 
excluded from further analysis. Data on cause-specific deaths 
verified by doctors were obtained to determine the leading 
cause of neonatal deaths in the facilities.

The summary statistics of the number of Poisson counts of 
neonatal death are presented in Table 1. Clearly, overdispersion is 
observed in the data (variance [254.53] > mean [3.40]). This is an 
indication that NB is preferable to P. Figure 1 indicates that zeros 
account for a greater proportion (about 86.96%) of the data. This 
signifies that the data have excessive zeros, an indication of the 
need to consider analytical methods that handle data inflated 
with zeros.24-26 As such, extensions to the traditional NB that 
simultaneously capture overdispersion and zero-inflation as well 
as other sources of heterogeneity was considered.29,30

Table 1. Descriptive statistics of the number of neonatal deaths.

STATISTIc VAlUE

Minimum 0

Maximum 122

First quartile 0

Median 0

Third quartile 0

Mean 3.40

Variance 254.53

Skewness 5.49

Kurtosis 34.06

No. of observations 138

Figure 1. Histogram of neonatal death counts in all hospital facilities.



4 Health Services Insights 

Methods
The main finding of the study is the number of neonatal deaths 
in health facilities. Such count data are often modelled using 
the Poisson regression. Let Yi  represent the dependent varia-
ble. Since Yi  is count, we assume Y Poissoni i~ ( )λ  and 
E Y var Yi i i( ) = ( ) = λ . The frequent relationship among inde-
pendent and dependent variables is λi i iX= ( )exp .Φ  Where 
Xi  is a matrix with covariates and Φi represents a vector of 

coefficients that are estimable.
The strict mean-variance relationship of the Poisson regres-

sion model (P) is usually violated due to unobserved heteroge-
neity or clustering.29,30 This unobserved heterogeneity or 
clustering results from repeated measurements that lead to 
overdispersion (variance greater than the mean in a Poisson 
regression model).29,30 In such a situation, the negative bino-
mial regression model (NB) becomes more appropriate. 
Assume Y NegativeBinomiali ~ (µi) with E Yi i( ) = µ  and 
var Y ki i i i( ) = +( ) >µ µ µ1 .28 The interrelation among the 
independent and dependent variables is µ ϕi i iW= ( )exp . 
Where Wi  is a matrix of independent variables, ϕi  is a vector 
of estimable coefficients and k is the dispersion parameter.

In essence, neonates at risk at a particular health facility 
are transported to others due to adequate infrastructure, 
equipment and human resources. This leads to a higher num-
ber of zeros being recorded in the clinics. The presence of 
structural zeros and overdispersion in the data required the 
use of the negative binomial hurdle regression (NBH) model 
to determine the related factors within the facilities.29,30 The 
use of the NBH requires a 1 step at a time procedure.24-26 The 
NBH assumes the zeros come from a single source.27,28 The 
detailed model estimation procedure has been included as a 
Supplemental file.

Statistical analysis

The fitting of the model was done using the MASS, pscl, sand-
wich and nonnest2 packages in R. The suitability of NBH was 
based on the Akaike Information Criterion (AIC), the Bayesian 
Information Criterion (BIC) and the Vuong test.31-35 The 
AIC, BIC and Vuong tests are presented in Tables 2 and 3, 
respectively. The results of the NBH is presented in Table 4. 
The proportion of cause-specific neonatal death is presented in 
Figure 2.

Results
The proportion of cause-specific neonatal death in Figure 2 
shows that the majority of neonates in the two municipal 
assemblies died of asphyxia (46%), premature birth (33%), neo-
natal sepsis (11%) and neonatal jaundice (7%). Furthermore, 
birth asphyxia and birth immaturity account for nearly 80% of 
all neonatal deaths in the study area. The estimated rate of neo-
natal mortality is 9.24 per 1000 live births.

Table 4 presents the estimates of the parameters and their 
standard errors for the NBH. From the table, the dispersion 
parameter is statistically significant at a 0.05 level of signifi-
cance. Considering the count model coefficient, the intercept 
had a significant estimate of 0.840 (P-value < .05). This sug-
gests an estimated expected number of neonatal deaths count 
of 2.32 per year when there is a constant number of midwives, 
incubators, paediatric doctors, bassinets, phototherapy 
machines, paediatric nurses, radiant warmers and CPAPb 
machines in a hospital facility. Therefore, the expected number 
of neonatal deaths will be extremely high in health facilities 
due to the lack of essential medical human resources and equip-
ment to care for neonates in critical conditions.

Regarding the variable of the structural facility, the number 
of bassinets was not significant. However, it had a decreasing 
effect on the number of neonates who died in health facilities. 
The number of phototherapy machines, incubators, radiant 
warmers, monitoring equipment, CPAPb machines and hand-
washing facilities were statistically significant (P-value < 0.05). 
A unit increase in the number of phototherapy machines in a 
health facility reduces the expected neonatal mortality per year 
by 38% when all other variables remain constant. Additionally, 

Table 2. AIc and BIc of models fitted.

MODEl AIc BIc

P 462.9293 498.0563

NB 415.1600 456.1464

ZINB 251.1800 268.7400

NBH 132.7200 168.4700

Table 3. Results of the Vuong non-nested test statistic. 

TEST ITEM VUONG Z-STATISTIc P-VAlUE

Raw 4.91 <.0001

AIc-corrected 3.97 <.0001

BIc-corrected 4.53 <.0001

46%

33%

11%

7% 3% Birth Asphyxia

Premature birth

Neonatal Sepsis

Neonatal Jaundice

Others

Figure 2. Major causes of neonatal deaths.



Tawiah et al 5

a unit increase in the number of incubators reduces the number 
of neonates who die per year by 22%. Increasing the number of 
radiant warmers results in a reduction in neonatal deaths by 
61%. CPAPb machines and hand washing facilities in the 
labour ward reduce neonatal deaths by 88% and 41%, respec-
tively, for each additional added. The number of monitoring 
equipment in health facilities results in an increase in recorded 
neonatal deaths. This requires further interrogation. Most clin-
ics lack these essential facilities.

For medical human resources, the number of midwives was 
not significant. However, it had a decreasing effect on neonatal 
mortality in the hospital. The number of paediatric doctors and 
paediatric nurses was statistically significant (P-value < .05). 
The estimate of the number of paediatric doctors indicate that 
increasing the number of paediatric doctors per unit results in 
decreasing the expected number of neonatal deaths per year by 
approximately 50% when all other factors remain constant. An 

increase in the number of paediatric nurses in health facilities 
results in an increase in recorded neonatal deaths. Hospitals 
have doctors, physician assistants, nurses and midwives, while 
clinics have physician assistants, nurses and midwives. This in 
relation to the lack of EOC in most clinics is responsible for 
the transfer of all complicated neonatal cases from clinics to 
hospitals.

The zero-hurdle model had an intercept of −8.841 
(P-value < .05) which translates into a reduction of 99.99% in 
the expected odds of neonatal death per year when there is a 
constant number of midwives, incubators, paediatric doctors, 
bassinets and phototherapy machines in the health facility. 
Here, the number of bassinets was not statistically significant 
(P-value > .05). The number of phototherapy machines 
increases the expected odds of neonatal mortality by 0.02%, 
while the number of incubators reduces the expected odds of 
neonates dying by 60.47%. Again, the number of midwives and 
paediatric doctors were significant (P-value < .05). When a 
midwife is added to the number of midwives in a health facility, 
the expected odds of neonatal death will decrease by 8.00% 
when all other factors remain constant. For every paediatric 
doctor added to the number of paediatric doctors in a health 
facility, the expected odds of neonatal death will decrease by 
48.11% in the facility. This points to the fact that the increase 
of medical human resources with inexperienced ones greatly 
influence neonatal deaths in these facilities. As much as the 
medical human resource is unlikely to remain the same over 
years, the experienced must be maintained while the inexperi-
enced ones are added.

Discussion
A significant number of neonates dying in middle- and low-
income countries (MLIC), including Ghana, are attributed to 
inadequate prenatal, intrapartum and postpartum medical 
care.15,36-38 Neonatal mortality rates have decreased signifi-
cantly over the years. It is imperative to continuously assess the 
progress achieved, as well as the areas that need improvement, 
to further reduce all forms of neonatal deaths, particularly in 
low-resource countries. Thus, this study scrutinized and evalu-
ated elements at the health facility level that have the potential 
to influence neonatal deaths in Sunyani and Sunyani West 
municipalities, Bono Region, Ghana.

The main and common causes of neonatal death in the cur-
rent study were birth asphyxia (46 %), preterm (33%), sepsis 
(11%) and neonatal jaundice (7%). This finding is consistent 
with the findings observed in Abdul-Mumin et al.15 in which 
preterm complications and birth asphyxia accounted for the 
majority of neonatal deaths in the NICU of the Tamale 
Teaching Hospital (TTH). Similarly, the findings align with 
studies in Ethiopia where sepsis, preterm and asphyxia were 
reported to be the leading causes of neonatal death.36-38

Regarding the results of the NBH model, the lack of ade-
quate numbers of midwives, incubators, paediatric nurses and 

Table 4. Parameter estimates and standard errors (S.E.) for the HBH 
model.

NBH

cOEFFIcIENTS ESTIMATE (S.E.) PR (>| Z |)

count model

Intercept 0.840 (0.281) 0.0028

Midwives −0.011(0.020) 0.5752

Paediatric doctors −0.686 (0.105) <0.0001

Incubators −0.254 (0.243) 0.0044

Bassinets −0.216 (0.115) 0.0604

Phototherapy machines −0.470 (0.199) 0.0175

Radiant warmers −0.944 (0.134) <0.0001

Paediatric nurses 0.123 (0.098) <0.0001

Monitoring equipment 0.257 (0.130) 0.0485

cPAPb −2.113 (0.456) <0.0001

Handwashing facilities −0.542 (0.159) <0.0001

Zero hurdle model

Intercept −8.841 (1.023) 0.0035

Midwives −0.083 (0.319) 0.0093

Paediatric doctors −0.656 (0.212) 0.0083

Incubators −0.928 (0.396) 0.0192

Bassinets 0.457 (0.203) 0.1996

Phototherapy machines 0.002 (0.001) 0.0070

Dispersion parameter

logk 3.970 (1.213) 0.0011



6 Health Services Insights 

doctors, radiant warmers and CPAP machines at the health 
facility level contributed significantly to the high risk of neona-
tal death. This is because neonates in critical condition could 
be denied essential human resources and equipment related to 
structural facilities to enhance their survival. In addition, a suf-
ficient number of skilled nurses and midwives is essential to 
reduce neonatal, infant and perinatal mortality. Findings from 
Amiri et al.39 alludes to the significant impact skilled nurses 
have had on minimizing infant, neonatal and perinatal deaths 
in some countries within the Organization for Economic 
Cooperation and Development (OECD), particularly in Japan, 
Sweden, Iceland, Slovenia and Finland. Also, Nove et al.40 pre-
sented evidence of the possible impact that adequate and 
skilled midwives have on reducing and preventing more than 
2.2 million neonatal and maternal deaths per year by 2035 in 
MLIC. Nove et al.40 recommended the need for midwives to 
be equipped with skills and competencies that align with those 
of the International Conference of Midwives to provide quality 
healthcare to neonates and mothers.

The study findings also highlight the important role that 
well-equipped and resourced neonatal intensive care units 
(NICUs), in addition to obstetric departments in MLICs, play 
in reducing and preventing neonatal mortality. According to 
Cavicchiolo et al.,41 well-resourced NICU significantly reduced 
neonatal deaths in Mozambique. This was possible due to an 
improvement in the quality of interventions for neonates 
admitted for asphyxia, sepsis and prematurity. The findings of 
this study support those in which quality and effective inter-
ventions within well-resourced neonatal intensive care units 
reduce neonatal deaths by 30%.42,43

When the study’s recommendations are put into practice, 
neonatal survival rates in the two municipal assemblies and 
throughout Ghana will significantly increase. Notwithstanding 
this, the study had some limitations. Since the study covered all 
of the main healthcare facilities, no power analysis for sample 
size was conducted. The study did not include traditional birth 
attendants’ homes. Despite the fact that hospitals get more 
neonates than clinics and have access to more medical person-
nel and resources, weighting for the variables were not factored 
in our model. The current assessment was carried out between 
2020 and 2021 using data from 2014 to 2019.

Conclusion
This study evaluated the link between neonatal death cases and 
factors at the health facility level in the Sunyani and Sunyani 
West municipal assemblies in the Bono Region, Ghana. Early 
management of neonatal sepsis, birth asphyxia, premature birth 
and neonatal infections should be prioritized to improve neona-
tal survival. Furthermore, the government and all stakeholders in 
the health sector should collaborate to provide cost-efficient, 
reliable and proven structural facility equipment and medical 
human resources to improve healthcare services for neonates in 
all health facilities in the two municipal assemblies. The findings 

of the study have significant implications on public health, par-
ticularly efforts to ensure quality health for all, including neo-
nates. This will contribute to the achievement of Sustainable 
Development Goal three, which calls for an end to avoidable 
deaths of neonates and children under 5 years of age by 2030.

Acknowledgements
We thank the Bono Regional Health Directorate and all the 
Municipal Health Directorates for their cooperation. Our sin-
cere gratitude goes to all the managers and heads of the infor-
mation departments of all health facilities in the 2 municipalities 
for their assistance. The authors thank the Human Research 
and Ethics Committee of the University of Energy and Natural 
Resources for providing ethical approval (CHRE/AP/05/023) 
for the study and waive all consent.

Author Contributions
KT, KAA, SI, AAO, IWA, RKA and FKB planned the study. 
KT and SI suggested the methodology. KT, KAA, RKA and 
FKB collected the data. KT, SI and KAA performed the statis-
tical analysis and drafted the manuscript. IWA, RKA, FKB, 
AOA, AAO and EO reviewed the manuscript. All authors read 
and approved the final manuscript.

Ethical Approval
Ethical approval was provided by the Human Research and 
Ethics Committee of the University of Energy and Natural 
Resources with approval number CHRE/AP/05/023.

Guarantor
Kassim Tawiah.

ORCID iDs
Kassim Tawiah  https://orcid.org/0000-0003-0195-225X
Richard Kwame Ansah  https://orcid.org/0000-0002-6551 
-4817

Data Availability
The data used in the study is available upon reasonable request from 
the corresponding author.

SupplEMEntAl MAtERIAl
Supplemental material for this article is available online.

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