Skip to main content
  • Research article
  • Open access
  • Published:

Assessing factors militating against the acceptance and successful implementation of a cloud based health center from the healthcare professionals’ perspective: a survey of hospitals in Benue state, northcentral Nigeria

Abstract

Background

Cloud based health platforms (CBHP) have tremendous capacity to meet patient’s health needs. The benefits inherent in CBHP position it to be relevant for efficient healthcare delivery. Nonetheless, studies have shown that the adoption of new technologies is sometimes a challenge especially in developing nations. This study, therefore, aim to examine, identify and evaluate the factors affecting healthcare professionals’ intention to accept the cloud-based health center (CBHC) in developing countries. The research study focuses on hospitals in North-central of Nigeria.

Methods

Using questionnaire adopted from related studies, a cross-sectional study was carried out of 300 healthcare professionals selected from medical health institutions in Benue State Nigeria. The study adopted the Unified Theory of Acceptance and use of Technology Extended (UTAUT2). Data analysis was carried out using SPSS (V20.0) and LISREL (V9.30) generally employed in Structural Equation Modeling to examine components and path model. The Socio technical design method was used to develop the CBHC.

Results

Findings portrays performance expectancy, cloud based health knowledge, IT infrastructure and social influence to have significant effects on the intentions of healthcare professionals to accept and use the CBHC. These findings, agrees with prior related studies.

Conclusions

Our findings impacts the body of knowledge in that it identifies important areas the studies can be useful, especially, to managers and healthcare policy makers in the planning/implementation of health cloud. Research findings from the theoretical acceptance model identifies the factors and barriers towards sustainable cloud based health center solutions to meet the healthcare needs of people in remote communities.

Peer Review reports

Background

It is an important strategy both for the government and healthcare industry to provide efficient healthcare delivery while planning to utilize the latest technologies. Global human population has shown an enormous increase in the recent years and diseases are becoming more complex. As a result, new advancements in technology have exploited in order to provide more effective diagnoses and treatment techniques while reducing the operations costs [1]. One of the ways this can be achieved and the health care system made robust is through the adoption of cloud computing into the health care system. Cloud computing has evolved over the years from basic storage platforms to encompass more comprehensive solutions for on demand delivery over the Internet, such as handling big data [2].

In the healthcare domain, healthcare service providers are integrating cloud based health platforms (CBHP) to reduce cost of operation, loss of data, prompt/remote access to data, etc. thereby, bringing efficiency both to the system and patients healthcare delivery. Using CBHP ensures that patient’s data are readily available, lost data can be recovered, transfer of patients clinical records is made possible and all clinical data are integrated into a central location for easy access for authorized persons [3]. It capabilities also includes, prompt/easy access to data and information [4] and IT resource sharing [5, 6]. Cloud computing proffers the resource sharing option for healthcare service providers with the other stakeholders such as other hospitals, government agencies etc. While sharing could improve the quality of service for the patients, it should also have strict regulations for privacy and data security. The benefits inherent in CBHP position it to be adequate for efficient healthcare service delivery most especially, for developing countries who, according to studies, are yet to meet up with twenty first century health care delivery needs. Studies have shown that CBHP present a good ground for coordination between all healthcare workers [7], connections [8] more importantly, aid the transfer of clinical health records [9]. It was revealed from the previous studies that IT literacy and experience of healthcare service providers have a significant influence on their perception, attitude and intention for the use of a new technology such as e-health technology applications [10, 11]. In accordance, Cloud based health knowledge (CBHK) of CBHP by users, is considered necessary for the sustainability of cloud-based healthcare solutions. It would be easier for the healthcare service providers to use cloud based health care systems if they have a prior knowledge of the systems’ working environment [11].

The World Health Organization (WHO) noted that, a robust healthcare system is one which provide adequate healthcare services to meet the health needs of people in a certain geographical location whenever needed [12]. With this understanding, the term cloud based health system refers to all computing mechanisms such as infrastructure, software and hardware used by healthcare service providers to deliver healthcare services like Software as a Service (SaaS), Infrastructure as a Service (IaaS) and Platform as a Service (PaaS) [13]. The factors mentioned above has been considered in the design of cloud based computing systems for the care of elderly and patients with anxiety disorders [14], patients with chronic diseases [15] and monitoring of patients with artificial hearts [16].

Health institutions in Nigeria remain under developed not mainly because of inadequate government funds, but also due to inadequate utilization of the available funds in the areas of appropriate focus on urban/rural health information and communication technologies (ICTs) [17]. In order to curtail this, developing countries such as Nigeria need to harness the potentials of cloud computing in their health care system by using cloud solutions such as: (1) SaaS: the mechanism in which software applications are provided over the internet by service providers, (2) PaaS: the mechanism in which computing solutions stacks and platforms are accessed by IT managers, developers or users over the internet without having to download any software and (3) IaaS: the sharing of computing resources through a virtualized environment) to bring about reducing cost, service speed and the elimination of inadequate health care workers [13, 18].

Currently, the national health care system in Nigeria is divided into three tiers which are: the primary health care (PHC), the secondary health care (SHC) and the tertiary health care (THC). All operating on decentralized systems and burdened with the tasks of providing effective health care services/programs to the citizens. The federal government specifies the health care polices and ensures that these policies are safeguarded by the PHC, SHC and THC [19]. While the THC is well equipped with adequate internet facility along with good source of energy supply and other infrastructures, the PHC and the SHC have limited or no access to the internet, and energy supply is even not providing the necessary quality of service. However, the increased use of internet enabled mobile devices and other means of energy supply (e.g. power generator) have motivated people not to depend on the public electrical and internet service authorities, since they can subscribe privately from private service providers (e.g. Glo-mobile network, MTN, Etisalat, Airtel etc.). Recently in November 2017, the Nigerian Communication Commission (NCC), revealed that 98.3 million Nigerians are internet users. Similarly, the International Telecommunication Union (ITU) 2017 report of Nigeria, identified a 75.9% mobile-cellular subscription users per 100 populations. Signifying a surge in the use of mobile–cellular subscription as against 33% in 2013 [20].

The introduction of new technologies is a very important development; more important is its application in the field of healthcare. These technologies enhance the efficiency both for healthcare professionals and patients with quicker and better access to healthcare services; but also facilitates proper and accurate decision making for stakeholders [21]. Despite the potentials inherent in the use of the CBHS to bring about effective and efficient healthcare service delivery to remote/rural communities in developing countries, research studies [22] have shown that its acceptance and usage is still a challenge, especially among healthcare professionals in some developing countries. Resulting in a gap between implementing a technology and adopting that technology. There is, therefore, need for healthcare professionals to accept the use of these technologies as their acceptance is pivotal and highly relevant to the success and sustainability of the systems [23].

It has been revealed from the studies [24] that before some of these technologies are accepted and utilized, they are required to meet up with some expectations of users’ requirements. Hence, different theoretical models have proposed to realize the factors and perceptions of technology acceptance. Popular among them are: (1) Theory of Reason Action (TRA): this theory explains the connection between behavior and attitudes in the context of human action. Its objective is to predict the intention why a behavior is performed by leveraging on each person’s attitude and beliefs [25]. (2) Technology Acceptance Model (TAM 1 and TAM 2): TAM is one of the well-known information systems theory. It models the factors that influence the users’ decision when introduced to a new technology and their subsequent usage. Over the years, new variables such as integrating barriers and network effects as external factors were added to the TAM model so as to derive a better understanding for users’ intention to utilize a specific technology, resulting in TAM 2 [26, 27]. (3) Unified Theory of Acceptance and use of Technology (UTAUT and UTAUT2): is a model employed to assess the level of new technology acceptance by users. Due to some limitations relating to generalization in the original UTAUT, UTAUT2 was developed and tailored to suit the consumer context [28]. While TRA is a model which is good at the prediction of human behavior [29], TAM is designed to provide a theoretical framework for the factors that influences user’s actions to the usage of information systems [30] and UTAUT is modelled towards user’s motivation to use an information system as well as their future behavior [31].

Developing countries such as Nigeria with a very large population are faced with a lot of challenges in their health care system: prevalent among these challenges are inadequate availability of healthcare professionals and medical health facilities among others as noted by [32]. As a result of this, we have people traveling long distances from remote rural villages to urban cities for their medical needs. This further result in excessive pressure on the part of healthcare professionals. Despite these challenges, studies have indicated that healthcare professionals in Nigeria are yet to adopt cloud-based health platforms, which could eliminate the issues enumerated [23].

To this end, the primary research objective of this study is to assess the factors which have a significant effect on the adoption of cloud based health systems by healthcare professionals in Nigeria. In addition, a Cloud Based Health Center is proposed for remote care and prompt access to health care needs for the future use. Findings from the theoretical acceptance framework could enhance sustainable and successful implementation of a Cloud Based Health Center. This could provide remote service delivery to meet the healthcare needs of people in remote/rural communities in Nigeria. Hence, the main questions of the research are:

  • What is the level of cloud based health knowledge (CBHK) of healthcare professionals in Nigeria?

  • What are the factors that can militate against the acceptance and use of Cloud Based Health Systems (CBHS) in Nigeria?

  • How can Nigeria adopt and use the CBHS?

Our research contribution could be seen in terms of the acceptance determination of healthcare professionals in using the cloud based health systems in Nigeria by using the guideline of [10] in verifying the use of the Unified Theory of Acceptance and use of Technology Extended (UTAUT2) in healthcare. Also, proposing the CBHC which can aid remote care to people in rural and remote communities. In addition, it is a crucial research objective to realize the effect of cloud based health knowledge (CBHK) as a major influence on the adoption and usage of cloud based health systems (CBHS) by the healthcare professionals. Our study investigated issues that mitigate either the acceptance or rejection of CBHS among healthcare professionals in Nigeria. Different factors are considered in the proposed model which influences behavioral intention to use CBHS. Our proposed system could be replicated and made to suit any organization which intend to adopt any cloud based systems.

Cloud based health technologies and acceptance models

Cloud based health platforms (CBHP) have tremendous capacity to meet patient’s health needs if its potential are fully utilized. The cloud makes possible a lot of things since it is open to all making data access, storage, retrieval and computations easy and readily available since it has no physical localization [33]. The term cloud based used here refers to some set of centralized components and tools accessible from remote locations via the use of web browsers [34]. CBHP can handle big data as well as pictures and text, thereby presenting a comprehensive and up to date health database. As a result of this, healthcare professionals have prompt and remote access to clinical data/information which in turn enables them to take adequate medical decisions. The functions performed by the CBHP include, but not limited to the enhancement of health care services, disease identification, monitoring and treatment, self-management of diseases and so on [35].

Health institutions were using the manual information processing and filing cabinet storages before the use of information technologies in healthcare delivery which leads to loss of patients’ data and even unnecessary waste of time in looking for a patient record [36]. It should also be noted that since the hospitals are not on the same platforms or using information sharing, referral is found to be very difficult once a patient is asked to go to another health institution. Hence, the use of cloud computing in healthcare could resolve all these issues such that access to patients’ records is not hindered by geographical location [37].

There are several studies in the literature in which the acceptance and intention to use a cloud based healthcare technology solutions have been investigated [38,39,40]. On the other hand, medical doctors’ intention to use a clinical decision support system is studied in [41] while performance expectancy (PE), social influence (SI) and self-efficacy (SE) were realized as significant factors. PE can be defined as “the degree to which the user expects that using the system will help him or her to attain gains in job performance” [31]. On the other hand, SI can be defined as “the degree to which an individual perceives that important others believe he or she should use the new system” while SE can be defined as “the degree to which an individual skills are required to use the new system” [31]. Integrated TAM and UTAUT based research study in conducted in [42] in order to determine the level of e-health applications among German healthcare professionals. It was revealed from the study that both perceived usefulness (PU) and perceived ease of use (PEOU) have a positive influence on their intention to use the technology. PU is defined as the conviction and opinion of an individual that the use of a certain technology will increase their performance with better productivity. On the other hand, PEOU is defined as an individual belief that the use of a certain technology would free of effort [42]. Studies have shown that healthcare professionals’ acceptance of cloud based technologies differs when compared to healthcare consumers in the sense that their acceptance is dependent on the perceived usefulness of the technology rather than its ease of use [43].

Some studies have investigated the attitude of doctors, nurses, lab technicians and other stakeholders as regard the acceptance of cloud based technologies (CBT) using either TAM or UTAUT. For instance, TAM is used in [44] to determine the factors which aid the acceptance of healthcare cloud computing technologies by healthcare professionals in Klang Valleys, Malaysia. On the other hand, Slade et al. [45] employed the UTAUT2 to investigate the motivating factors of user’s intention to use mobile technologies in the healthcare domain. In another study [46], factors were studied that predict the adoption and usage of Electronic Medical Records (EMRs) among family physicians using the UTAUT. It was found that SI and PEOU does not have a strong correlation as compared with PU, facilitating condition (FC) and general satisfaction (GS). The summary of cloud based technology acceptance can be found in Table 1.

Table 1 Summary of cloud computing acceptance

Unified theory of acceptance and use of technology (UTAUT)

The unified theory of acceptance and use of technology (UTAUT) is developed after reviewing several acceptance models and theories [22]. This model incorporates four basic construct which are: performance expectancy, effort expectancy, social influence and facilitating conditions. It is believed that while the first three constructs greatly influence behavioral intent, facilitating conditions and behavioral intention determine the actual use of a technology. This model also has some moderating variables such as gender, age, experience and voluntariness which show the relationships between the variables [46]. UTAUT2 theoretical framework is developed in time, as shown in Fig. 1, due to some limitations of UTAUT [10, 47]. New relationships in UTAUT2 model are shown in green color.

Fig. 1
figure 1

UTAUT2 theoretical framework (Source: authors)

Three new constructs were added to the earlier four constructs, namely hedonic motivation, price value and habit in order to relate the model to consumer perspective. In accordance, UTAUT2 includes: performance expectancy, effort expectancy, social influence, facilitating conditions, hedonic motivation (seen as the enjoyment one derived from using a particular product), price efficacy (referred to as the cost a user incurred in order to use a particular service), and finally habit (seen as the extent of behavioral characteristics) [48]. It should be noted that voluntariness, which is a moderator in UTAUT, was dropped in UTAUT2 and facilitating condition is hypothesized to influence both behavioral intention and user behavior directly due to the factor’s critical role in an organization environment [10].

Cloud based health center

Using a socio-technical design approach suggested by [49] in the design and development of health information technologies, Cloud Based Health Center (CBHC) is developed, as can be seen in Fig. 2. The CBHC is a web based application that enhance the provision of distant health care delivery for both healthcare professionals and healthcare consumers.

Fig. 2
figure 2

CBHC system architecture (source: Figure created using the demo version of ConceptDraw Diagram software which adheres to the terms and conditions of ConceptDraw)

The system has majorly three main actors: the doctor, the healthcare worker (HCW) and the patient. The functions of the doctor include diagnosis, drug prescription and access to patient records and vital signs. The HCW however, is responsible for registering a new patient, check/enter a patient vital signs (body temperature, blood pressure, weight, etc.) and serve as an intermediary between the doctor and the patient in cases where a patient has an appointment with a doctor. After registering to the system, username and temporary password are generated which can also be changed in the future. Users could have the chance to view their medical results, enter the symptoms of a disease they are feeling in order to get a diagnosis. They can also book an appointment with a doctor in cases where a patient feels that the inputted symptoms is not adequate enough for accurate system diagnosis. It should be noted that the patients cloud log-in to their accounts by using their internet enabled devices, such as mobile phones, tablets, computers etc.

However, patients who do not have access to a personal IT device could also use the CBHC through the HCW who is stationed at the community health center. The system is protected by a firewall so as to protect and secure patients’ data and managed by a system administrator whose major responsibility is to register new doctors and HCW to the system.

A login system is utilized to access the application for all class of users. Based on the type of users, the system automatically, directs them to their respective interfaces. The system is developed to facilitate and enhance the working efficiency of health care professionals so as to relieve them from undue pressure, which might arise as a result of the limited number of healthcare professionals. The system is also designed to facilitate remote healthcare delivery through Telepresence: in that way, healthcare professionals don’t have to be physically present in order to attend to the healthcare needs of patients. In addition to the firewalls, an APACHE web server is used as a security measure to monitor the activities in the system providing a secured, efficient and extensible server with HTTP services in synchronization with recent HTTP standards.

The Nigerian National Health Act (2014) [50], offers a legal framework that regulates the administration and expansion of the National Health System and also, set criteria for the adequate delivery of health care services in the country. Under this Act, health technologies and institutions are categorized based on their functions to the national health care system. The type or level of health services are categorized with respect to the offered service type as well as the need to structure healthcare service delivery in line with national framework standards.

Cloud Based Health Center is developed in order to provide solutions to the issues, such as shortage of healthcare professionals and facilities as well as excessive pressure on healthcare professional. The proposed model could be used in the future to be of benefıt to both healthcare professionals and consumers.

Research model and hypothesis

Sequel to the discussion of UTAUT, an extended UTAUT model is used in this research to identify the factors which negate health care professionals’ acceptance of CBHC. Our research framework proposes new constructs which include Cloud Based Health knowledge (CBHK), data security (DS), IT infrastructure (IT) and information sharing (IS). It was shown in the previous studies [51, 52] that UTAUT2 theoretical framework has high abilities in explaining the behavior intentions of healthcare professionals at using healthcare information systems. In addition, it justifies other UTAUT2 findings in related healthcare context which confirms the ability of UTAUT2 to be able to predict the underlying factors to the acceptance of CBHC by healthcare professionals. The proposed hypothesized research model is depicted in Fig. 3 as regard the relevance of adoption and use of cloud based health center (CBHC) by healthcare professionals in developing countries.

Fig. 3
figure 3

Hypothesized Research Model

Research constructs are explained as follows:

Performance expectancy

Performance expectancy is termed the extent in which the use of a particular technology yield positive impact to consumers in the performance of named activities [52]. Similarly, recent research has held up the relevance of performance expectancy in user’s intention to accept a technology [53,54,55]. Therefore, performance expectancy has been hypothesized as a direct determinant of behavioral intention and also information sharing for data exchange support.

H1a: Performance expectancy is positively related to information sharing.

H1b: Performance expectancy is positively related to healthcare professional behavioral intention to accept and use the health cloud.

Cloud based health knowledge

Knowledge of cloud based health platforms which is a motivating factor for the construct effort expectancy is seen to be a very essential requirement for using any cloud based systems as stated by [56]. The awareness and technological skills possessed by a healthcare service provider position them in an advantageous position to gain the maximum benefits attainable. It was revealed from the previous studies [44] that the awareness of cloud based applications in healthcare is lower in developing countries which could have an effect on the use of health cloud. Therefore,

H2: Cloud based health knowledge is positively related to health care professionals’ behavioral intention to use the health cloud.

Self-efficacy

The usage of the cloud based health center means that a user should have necessary skills which will enable the use of the proposed platform. Self-efficacy is considered as one of the facilitating conditions in which the necessary technical support is crucial for the use of a certain technology in system operation [29]. If the facilitating conditions are available, such as demos, CDs and online tutorials, on how to use cloud based health platforms, then health care professionals will have the intention to use the platform. Hence,

H3: Self-efficacy is positively related to healthcare professionals’ behavioral intention to use the health cloud.

Data security

Data security here refers to the measures applied to protect personal data and information from unauthorized access. The data security is a major issue in cloud based systems since unauthorized access can result in serious damage; hence the need for adequate regulations and preventive measures is imperative. It was revealed from previous studies that a robust association exists between data security and health care professionals’ intention to use cloud based health technologies [57]. Therefore,

H4: Data security is positively related to health care professionals’ behavioral intention to use the health cloud.

IT infrastructure

The availability of required ICTs (hardware and software) is quite essential for the sustainable operation of cloud based systems and also beneficial to intended users. Hence,

H5: IT infrastructure is positively related to health care professionals’ behavioral intention to use the health cloud.

Social influence

Social influence is considered as a construct which a user is being influenced by others to use a specific technology. Previous studies [15] revealed that social influence does not have a significant effect on healthcare service providers’ intention to use the health cloud particularly when UTAUT is used. Therefore,

H6: Social influence is positively related to health care professionals’ behavioral intention to use the health cloud.

Information sharing

Cloud based health platforms provide remote accessibility to the required data and information of patients. In accordance, information sharing, which can occur either internally or externally is a very important construct to be considered. The free flow of information, within cloud based health platforms, inherits efficient use of resources both to service providers and stakeholders [58]. Use of the shared information enhances the behavior of some users since healthcare professionals could have the chance to proffer the right solutions with regard to the patients’ particular condition [59]. Hence,

H7: Information sharing is negatively related to health care professionals’ behavioral intention to use the health cloud.

For the purpose of achieving our aim in this research, questionnaire based approach was employed in order to identify the factors which affects health care professionals’ intention to accept and use the cloud based health center. The questionnaire approach is a well-known method to address a large number of issues simultaneously with high response rate. In addition, since answers to questions are scaled and analyzed, it is possible to predict an event that is likely to occur or relationships that exist between variables to have a sustainable plan for the future. The questionnaire shows the demographic data of respondent as well as the kind of health facility the research is carried out. The results will help in explaining the predictors of health care professionals’ adoption of cloud based health center.

Methods

Questionnaire design

The study adopted a quantitative research approach to collect data by using a close-ended questionnaire with a seven-point Likert-scale measurement. While in the questionnaire the demographic information of participants were collected, as could be seen in Table 4, the questionnaire was also designed in accordance to extended UTAUT2 constructs. The study presented a modified framework particular to health care information technology acceptance and specific to the circumstances by the research scope; while considering the statement by Venkatesh et al., [10] that, it is important to extend UTAUT2 model by considering different factors and relations specific to the field. The key variables used in the research model is summarized in Table 2.

Table 2 Measures of key constructs used

Sample and data collection

The targeted participants for this research were healthcare professionals from selected healthcare institutions in Benue State Nigeria. Since it is very necessary to get the behavioral intentions of healthcare professionals in the rural communities, the health institutions were grouped into the following categories: Federal Medical Centers (FMC), Teaching Hospitals (TH), General Hospitals (GH), Private Hospitals (PH) and Primary Healthcare Centers (PHC). The institutions were selected from three different locations: Markurdi, Aliade and Otukpo for the sampling. Data was collected from nine hospitals in general. A total of 420 questionnaires were distributed by hand to healthcare professionals in these health institutions and 350 questionnaires were returned which signifies a response rate of 83.33%. However, after careful assessment 50 questionnaires were found to be incomplete as a result of improper filling of the questionnaire or not filling at all and so were discarded. At the end, only 300 questionnaires were found to be available and useful for the analysis. Table 3 presents the health institutions where research was carried.

Table 3 Characteristics of surveyed health institutions

Before giving out the questionnaire to the participants, the authors introduced the objectives of the survey and some concepts, such as Cloud Based Health Platform (CBHP), Cloud Based Health Knowledge (CBHK) and Cloud Based Health Center (CBHC), were explained to them. The rationale behind this, was to make sure that participants clearly understand the concepts used in the survey and also, to ensure participants have a prior knowledge of CBHP as the otherwise of this is an exemption.

As could be seen from the Table 3, healthcare professionals who responded to the questionnaire included doctors, nurses, administrative staffs, pharmacists and laboratory technologists. It was also realized that most of the responded participants are female which is contrary of any developing country according to [68]. An ethical approval with the reference no MOH/STA/204/VOL 1/28 was given by the Research Ethics Committee of Nigeria.

Data analysis

SPSS (V20.0) was employed to carry out the statistical analysis, such as construct reliability, convergent validity, discriminant validity and the intraclass correlation coefficient by Fleiss while LISREL (9.30) software was used for the Structural Equation Modeling (SEM) to test the model. Our reason for using this method stem from the fact that SEM is employed to designate the enormous number of models used to assess the validity of basic theories with experimental data. The choice of the LISREL software is as a result of its flexibility in carrying out both structural and measurement components simultaneously. It also presents information referred to as modification indices which aids in the identification of equality constraints. In LISREL, the scales of the observed data is automatically regulated by limiting the loading to one in which there is no need to draw unique factors representing measurement error for each of the observed data. It is believed that the appropriate use of this software will not only provide a statistical basis using a chi-square test for multiple group comparison but can accurately produce good estimates [69]. Composite Reliability (CR), Convergent Validity (Average Variance Extracted - AVE) and correlation coefficient (Fornell-Larcker-Criterion and Intra-class coefficients) analyses were used for the measurement of reliability indices. In addition, path coefficient (β) and associated t- value was used for the analysis of the structural model. Finally, Chi Square value was utilized for the general assessment of the model fit. Prior to testing the structural model, the measurement model was evaluated in order to measure the convergent validity, discriminant validity and correlation coefficient analysis.

Results

Demographic analysis

The demographic data of the respondent which shows information such as gender, occupation and years of experience of the respondents are shown in Table 4. The result portrays majority of the respondent to be female (55.0%), while the male respondents sum-up to (45.0%). This is contrary to previous studies [70] in developing countries which has shown marginalization of women in employment. This finding, however, did not affect the research.

Table 4 Demographic data of respondent (n = 300)

One of the other objective of the research is to identify the level of cloud based health knowledge of the healthcare professionals. In accordance, the descriptive analysis for the level of CBHK is depicted in Fig. 4.

Fig. 4
figure 4

Level of cloud based health knowledge of respondents

It was revealed from Fig. 4 that large number of the respondents (70.1%) agree that they have a good knowledge of cloud based health center. In the same way, just 17% disagree with having a good knowledge of cloud based health center and 13% of the respondent were indecisive. This finding indicates that healthcare professionals have a vibrant knowledge of basic cloud based systems and this finding is a very important step in the acceptance, implementation and usage of the cloud based health center.

Reliability analysis

Validity and reliability tests of the proposed model’s constructs are first checked by carrying out a general sample test in order to get a meaningful performance measurements before testing the hypothesis. By engaging the average variance extracted (AVE) and composite reliability (CR), the convergent validity was tested [71]. Table 5 lists the constructs, item, factor loading, CR and AVE. In order to examine, construct reliability, either the Cronbach Alpha or the composite reliability coefficient (CR) is used. Our testing, as seen on the Table 5, shows composite reliability (CR) value of each of the constructs to be above 0.7 and average variance extracted (AVE) to be above 0.5 respectively. This is the required acceptable threshold value for CR and AVE [72] which indicates a good internal consistency. However, social influence item was removed as the AVE indices (0.4296) are less than the recommended threshold. Table 5 presents the factor loading which is above 0.5 for items associated factors. Indicating adequate reliability according to [73]. The construct reliability of all items is evaluated based on each item reliability. Each item reliability is analyzed by observing the construct loadings [74].

Table 5 Composite reliability of dependent and independent variables

Correlation coefficient analysis

In order to ascertain the level of relationship existing between the independent and dependent variables of the model, correlation coefficient analysis was carried out. Table 6 depicts the square root of AVE and the discriminant validity with respect to the correlation between the constructs at an average range of (0.005 < r < 0.572). Indicating that independent variable can linearly predict dependent variables from the extended UTAUT model with a substantial amount of precision. According to [23], 0.3 and 0.9 are the required threshold value to specify substantial correlation between variables. Indicators illustrates that items load more with individual constructs than with any other construct. Additionally, square root of AVE for each construct is seen to be to be greater than correlations among constructs, indicating discriminant validity for all constructs. This satisfies the Fornell-Larcker-Criterion and is a pointer to the discriminant and convergent validity of the items.

Table 6 Discriminant characteristics of constructs

In addition, another approach was also considered using intraclass correlation coefficients (ICC) to measure the level of agreement between constructs. In this analysis, ICC estimates and associated 95% confident interval were calculated using a single-rating, absolute-agreement, 2-way-mixed- effects model. Table 7 shows the measurement indices for this analysis. ICC for each single measure was seen to be .195 (p < .001). Whereas, average measures for all constructs was seen to be .659 (p < .001), which, according to the recommended values (0.41–0.60) is considered a moderate agreement [74]. Also, the confidence interval for the ICC measure was found to be 95%, ranging between .589 and .719, indicating that, there is a 95% chance the true ICC value is at any point between .589 and .719. Therefore, based on the studies of [75], it could be concluded that substantial agreement do exist among the constructs with moderate reliability.

Table 7 Results of ICC evaluation showing Single-Rating and Absolute-Agreement using 2-Way-Mixed effects Model

Structural model - hypothesis testing and validation of model

Proposed hypothesis were tested via analysis of the path coefficient between variables and their respective t – values which identifies the significance of the final model. From this analysis, it could be stated that the path coefficients are an indicator for the associated strength of the effect of independent constructs (e.g. performance expectancy, self-efficacy, social influence etc.) on the dependent construct (e.g. behavioral intention). Figure 5 shows the findings of the structural model.

Fig. 5
figure 5

Structural Model

The effect of performance expectancy on information sharing (H1a) and performance expectancy on behavioral intention (H1b) was positive at (β = 0.68; t = 8.08) and (β = 0.23; t = 2.25) as well as the effect of cloud based health knowledge (H2) on behavioral intention (β = 0.27; t = 5.53) respectively going by the recommended criterion given by [66]. Similarly, IT infrastructure (H5) and social influence (H6) both indicate significant effects on behavioral intention (β = 0.11; t = 2.72) (β = 0.11; t = 2.10) respectively. However, self-efficacy (H3), data security (H4) and information sharing (H7) indicated a negative effect and hence, not supported (β = 0.07; t = 1.52), (β = 0.00; t = 0.07) and (β = 0.02; t = 0.46) as they all seem to have a negative effect on behavioral intention. Hence, they were rejected. Summarized results of hypothesis testing is shown in Table 8.

Table 8 Summarized results for hypothesis examination

The overall model fit was analyzed with LISREL using the values of chi square 10.41. Model fit is derived from dividing chi square by the degree of freedom (DF) (i.e. 10.41/5 = 2.0). Therefore, the model fit was found to be 2.0 and is an acceptable value according to [76] in which chi square should be < = 2 or < = 3. For the fit measure, the Root Mean Square Error of Approximation (RMSEA) was found to be 0.06 which is also within the range of acceptable RMSEA (RMSEA < = .05, RMSEA > = .08), suggesting that the model is supported by statistical testing.

The adequacy seen in the structural model gave room for the evaluation of the explanatory and estimated predictive power. Explanatory power was evaluated by observing the R2 value of the dependent variable which defines the number of variance variable explained. R2 value for the dependent variable BI (R2 = 0.33) was seen to be moderate, elucidating 33.0% variance of the variable. Indicating that, the proposed model reveals 33.0% of behavioral intention.

Discussion

The objective of this study is to ascertain the issues hindering the adoption of Cloud Based Health Center by healthcare professionals in Nigeria, and at the same time, propose/develop the cloud based health center. Eight variables were used in the study. Four were adopted from the study of Vankatesh et al. 2012 [10] and another four variables (cloud based health knowledge, data security, IT infrastructure and information sharing) integrated from our study area. In line with previous studies on UTAUT2 [10, 31], findings from this study (Fig. 5) reveals that five of the variables have a significant impact on the behavioral intention of healthcare professionals. Performance expectancy (PE) which was our first findings was seen to have a significant effect on information sharing and behavioral intention [10]. This means that information sharing is pivotal and well accepted among healthcare professionals and as such, influences the behavior of healthcare professionals towards the acceptance and use of cloud based health center. Our second finding is the impact of “cloud based health knowledge (CBHK)” on “behavioral intention” while this variable was derived from our study area (Nigeria), it was seen to have a positive impact on the intention of healthcare professionals in Nigeria as they already have a good understanding of cloud based systems (CBS); as such, are willing to accept and use the cloud based health center. Hence, CBHK could be considered as a major driver for creating awareness in CBS for health. Our third finding “self-efficacy” was seen to have a negative impact on behavioral intention. This portrays that a lot of healthcare professionals in Nigeria cannot adequately use CBS on their own and if they are to accept and use cloud based health center, then serious focus should be on training on how to efficiently use CBS independently.

Data security which is our fourth findings was also seen to negatively impact health care professional’s behavioral intention. This seems to be a major barrier to the acceptance and use of cloud based health center among healthcare professionals in Nigeria as security of data is paramount to the survival of any CBS [77]. Our fifth and sixth findings “IT infrastructure” and “social influence” all shows positive impacts on the behavioral intention of healthcare professionals. Our last finding “information sharing” however, shows a negative impact on BI. This means that if health care professionals in Nigeria are to accept and use a cloud based health center, then focus should be on providing a mechanism for adequate information sharing within and outside the various departments of health care institutions.

The result of our findings in general portrays CBHK and IT infrastructure to have the highest impact on BI: as such, considered to have significant influence in the acceptance and use of CBHC among healthcare professionals in Nigeria. Our findings, therefore, confirms other UTAUT2 studies in cloud based health systems [78]. Our theoretical research model, explain 33% predictive power of healthcare professionals intention to accept the cloud based health center. It could be stated that the model has a significant effect on health care professional’s intention.

Moreover, the study was undertaken to respond to three basic questions:

  1. 1.

    What is the level of cloud-based health knowledge (CBHK) of healthcare professionals in Nigeria?

Findings from our research portrays that healthcare professionals have a fair understanding of how a cloud based systems functions confirming the studies of [79, 80] who affirms that health professional’s knowledge of cloud computing platforms indeed have an impact on their attitude and perception towards its adoption and usage.

  1. 2.

    What are the factors that can militate against the acceptance and use of cloud-based health center (CBHC) in Nigeria?

Based on related studies of [81] on the adoption of cloud based health systems and also findings from our research, principal factors which militate the acceptance of cloud based health center in Nigeria were recognized and categorized into four which include (1) performance expectancy related to the work efficiency of healthcare professionals, remote access monitoring and increased productivity; (2) cloud based health knowledge related to awareness, technological know-how of healthcare professionals and their knowledge, experience; (3) IT infrastructure related to technical support, software/hardware and favorable work environment; (4) social influence related to quality of service and the necessity of the platform.

  1. 3.

    How can Nigeria adopt and use the CBHC?

Our research findings indicate that healthcare professionals are ready and willing to adopt CBHC however, there is a low availability of required IT infrastructure for the sustainability of CBHC. Therefore, more emphasis should be placed on the provision of needed ICT tools and technology. This finding corresponds to the study of [82] who identified information communication as a bedrock to the implementation of any cloud based systems. In addition, more awareness/sensitivity needs to be created as regard the relevance of CBHC in the Nigerian health care system as indicated from the research findings.

Factors and dynamics are identified which signify positive impact on healthcare service providers’ behavioral intention to accept the CBHC in Nigeria. Having identified these factors enhance successful and sustainable CBHC implementations in the near future which could benefit healthcare professionals from excessive work related stress and offers distant access to health care delivery services.

The limitations of this study are as follows: It is possible for selection bias to take place since all the respondents are health workers; their knowledge and awareness of cloud based health systems could be more versatile than that of a non-health worker. The choice of constructs used here is based on our observation of our selected study site; it is therefore possible that other constructs of cloud health usage may exist. In addition, this study cannot be generalized since it targets only health care workers. Future work could be conducted to determine health care consumers adoption of cloud based health center utilizing constructs that really focus on patients’ needs. Finally, some limitations could arise from the use of CBHC, one of which is the inability of rural dwellers to independently use the system. However, this limitation could be minimized since there is the HCW to educate and guide them on how the system functions. Secondly, the password could easily be stolen since most of the users are likely to use their mobile phones. In addition, internet access might not be readily available to the public, except users subscribe to individual internet service from service providers who are well represented in the communities.

Conclusion

The main focus of this research study is to identify dynamics for the adoption and the implementation of cloud based systems in the Nigerian health care system and the necessity of CBHC. Fundamental factors were primarily identified which affect the adoption of cloud based health center from the perspective of healthcare professionals in Nigerian hospitals. Our research findings is of managerial importance to policy makers in that our model explain 33% of the factors which hinders the successful implementation of a cloud based health system in Nigeria and contributes to the sustainability and growth of the Nigerian health care system.

Abbreviations

AVE:

Average Variance Extracted

BI:

Behavioral intention

CBHC:

Cloud Based Health Center

CBHK:

Cloud based health knowledge

CBHP:

Cloud based health platform

CBHS:

Cloud based health system

CBT:

Cloud based technologies

CDs:

Compact Disc

CR:

Composite Reliability

DS:

Data security

FMC:

Federal Medical Center

GH:

General Hospital

GS:

General satisfaction

HCW:

Healthcare worker

ICC:

Intraclass Coefficient

ICT:

Information Communication Technology

IS:

Information sharing

IT:

Information technology

ITU:

International Telecommunication Union

NCC:

Nigerian Communication Commission

PE:

Performance expectancy

PEOU:

Perceived ease of use

PH:

Private Hospital

PHC:

Primary Healthcare Center

PU:

Perceive Usefulness

SE:

Self-efficacy

SEM:

Structural Equation Model

SHC:

Secondary health care

SI:

Social influence

TAM:

Technology Acceptance Model

TH:

Teaching Hospital

THC:

Tertiary health care

UTAUT:

Unified Theory of Acceptance and Use of Technology

UTAUT2:

Unified Theory of Acceptance and Use of Technology Two

β:

Beta

References

  1. Naylor KT, Kudlow P, Li F, Yuen K. Improving healthcare with information technology. Univ West Ont Med J. 2011;80:1.

    Google Scholar 

  2. Chiagunye T, Igbajar A, Ilo S. Cloud based health care information system for rural clinics in Nigeria. Int J Elect Elect Comput Sci Eng. 2015;2:6.

    Google Scholar 

  3. Nematzadeh A, Camp LJ. Threat analysis of online health information system. In: 3rd international conference on pervasive technologies related to assistive environments (PETRA); 2010. Accessed 8 Mar 2017.

    Google Scholar 

  4. Chen T-S, Liu C-H, Chen T-L, Chen C-S, Bau J-G, Lin T-C. Secure dynamic access control scheme of PHR in cloud computing. J Med Syst. 2012a;36(6):4005–20.

    Article  PubMed  Google Scholar 

  5. Fernández-Cardeñosa G, de la Torre-Díez I, López-Coronado M, Rodrigues JJPC. Analysis of cloud-based solutions on EHRs systems in different scenarios. J Med Syst. 2012;36(6):3777–82.

    Article  PubMed  Google Scholar 

  6. Karthikeyan N, Sukanesh R. Cloud based emergency health care information service in India. J Med Syst. 2012;36(6):4031–6.

    Article  CAS  PubMed  Google Scholar 

  7. Shini SG, Thomas T, Chithraranjan K. Cloud-based medical image exchange security challenges. Procedia Eng. 2012;38:3454–61.

    Article  Google Scholar 

  8. Ratnam KA, Dominic PD. Cloud services-Enhancing the Malaysian healthcare sector. In Computer & Information Science (ICCIS), 2012 International Conference on 2012 Jun 12 (Vol. 2, pp. 604–608). Kuala Lumpur: IEEE. (ICCIS) 2012. Accessed 6 Oct 2017.

  9. Basu S, Karp A, Li J, Pruyne J, Rolia J, Singhal S, Suermondt J, Swaminathan R. Fusion Managing healthcare records at cloud scale. Computer. 2012;45(11):42–9 Accessed 2 Aug 2017.

    Article  Google Scholar 

  10. Venkatesh V, Thong JY, Xu X. Consumer acceptance and use of information technology: extending the unified theory of acceptance and use of technology. MIS Q. 2012;1:157–78.

    Article  Google Scholar 

  11. Kabashiki IR, Moneke NI. The impact of the use of health information and communication technology on health care delivery in Manitoba, Canada. J Hosp Admin. 2014;3(6):8.

    Google Scholar 

  12. World Health Organization. Health Systems. http://www.who.int/topics/health_systems/en/. Accessed 25 Sept 2018.

  13. Goyal S. Software as a service, platform as a service, infrastructure as a service− a review. Int J Comput Sci Netw Solut. 2013;1:53–65.

    Google Scholar 

  14. Berndt R-D, Takenga MC, Kuehn S, Preik P, Sommer G, Berndt S. SaaS-platform for mobile health application. In: 9th IEEE international multi-conference on systems, signals and devices (IEEE SSD); 2012. Accessed 11 June 2017.

    Google Scholar 

  15. Deng M, Nalin M, Petković M, Baroni I, Marco A. Towards trustworthy health platform cloud. In: Workshop on secure data management. Berlin: Springer; 2012. p. 162–75.

    Chapter  Google Scholar 

  16. Choi J, Park JW, Chung J, Min BG. An intelligent remote monitoring system for artificial heart. IEEE Trans Inf Technol Biomed. 2005;9(4):564–73 Accessed 19 Nov 2017.

    Article  PubMed  Google Scholar 

  17. Ukeje C, Oni OA. The adoption of a national cloud framework for healthcare delivery in Nigeria. Int J Eng Res Appl. 2015;5(3):61–8.

    Google Scholar 

  18. Analytics, H. I. M. S. S. HIMSS Analytics Cloud Survey. https://electronichealthreporter.com/himss-cloud-survey-80-percent-of-healthcare-organizations-embrace-the-cloud/. Accessed 15 Sept 2018.

  19. Ajuwon GA. Use of the Internet for health information by physicians for patient care in a teaching hospital in Ibadan, Nigeria. Biomed Digit Libr. 2006;3(1):12.

    Article  PubMed  PubMed Central  Google Scholar 

  20. Internet users in Nigeria hit 98.3 million. https://www.ncc.gov.ng/thecommunicator/index.php?option=com_content&view=category&layout=blog&id=19&Itemid=141. Accessed 13 Sept 2018.

  21. Thimbleby H. Technology and the future of healthcare. J Pub Health Res. 2013;2(3):e28.

    Article  Google Scholar 

  22. Simon SR, Kaushal R, Cleary PD, Jenter CA, Volk LA, Poon EG, Orav EJ, Lo HG, Williams DH, Bates DW. Correlates of electronic health record adoption in office practices: a statewide survey. J Am Med Inform Assoc. 2007;14(1):110–7.

    Article  PubMed  PubMed Central  Google Scholar 

  23. Zayyad MA, Toycan M. Factors affecting sustainable adoption of e-health technology in developing countries: an exploratory survey of Nigerian hospitals from the perspective of healthcare professionals. PeerJ. 2018;6:e4436.

    Article  PubMed  PubMed Central  Google Scholar 

  24. Dillon A, Morris MG. User acceptance of information technology: theories and models. Annu Rev Inf Sci Technol. 1996;31:3–2 Accessed 23 Jan 2018.

    Google Scholar 

  25. Southey G. The theories of reasoned action and planned behavior applied to business decisions: a selective annotated bibliography. J N Bus Ideas Trnds. 2011;9(1):43–51.

    Google Scholar 

  26. Holden RJ, Karsh BT. The technology acceptance model: its past and its future in health care. J Biomed Inform. 2010;43(1):159–72.

    Article  PubMed  Google Scholar 

  27. Yarbrough AK, Smith TB. Technology acceptance among physicians: a new take on TAM. Medicare Res Rev. 2007;64(6):650–72.

    Google Scholar 

  28. Ahlan AR, Ahmad BIE. An overview of patient acceptance of health information technology in developing countries: a review and conceptual model. Int J Inform Syst Proj Manag. 2015;3(1):29–48.

    Google Scholar 

  29. Fishbein M, Ajzen I. Belief, attitude, intention, and behavior: an introduction to theory and research; 1975.

    Google Scholar 

  30. Chen S-C, Li S-H, Li C-Y. Recent related research in technology acceptance model: a literature review. Aust J Bus Manag Res. 2011;1(9):124–7.

    Google Scholar 

  31. Venkatesh V, Morris MG, Davis GB, Davis FD. User acceptance of information technology: toward a unified view. MIS Q. 2003;27:425–78.

  32. Idoga PE. A literature review of eHealth sector and challenges in Nigeria. In: HONET-ICT. Nicosia: IEEE; 2016. p. 145–9.

  33. Mathew S. Cloud computing: a new foundation towards health care. Int J Innov Tech Exp Eng. 2013;3(2):118–21.

    Google Scholar 

  34. Fylaktopoulos G, Skolarikis M, Papadopoulos I, Goumas G, Sotiropoulos A, Maglogiannis I. A distributed modular platform for the development of cloud based applications. Future Gener Comput Syst. 2018;78(P1):127–41.

    Article  Google Scholar 

  35. Ku WT, Hsieh PJ. Acceptance of cloud-based healthcare services by elderly Taiwanese people. In: International conference on human aspects of IT for the aged population. Toronto: Springer International Publishing; 2016. p. 186–95.

  36. Palgon, G. The history of health Information Management – From Then to Now. Available from https://www.liaison.com/blog/2017/05/02/history-heath-information-management-now/. Accessed 14 Sept 2018.

  37. Bartos CE, Butler BS, Crowley RS. Ranked levels of influence model: selecting influence techniques to minimize IT resistance. J Biomed Inform. 2011;44(3):497–504.

    Article  PubMed  Google Scholar 

  38. Su CY, Chao CM, Sun KH, Tai CF, Liu CW. Willingness of E-care cloud system using-based on a long-term caring institution in southern Taiwan. In: Orange technologies (ICOT), 2015 international conference. Hong Kong: IEEE; 2015. p. 122–6. Accessed 16 Sept 2018.

  39. Chen MS, Chang SW, Lai YH. The intention to use the cloud sphygmomanometer-demonstrated by Taiwan medical center. In: Image and signal processing, BioMedical engineering and informatics (CISP-BMEI), international congress. Datong: IEEE; 2016. p. 1843–8. Accessed 16 Sept 2018.

  40. Hsieh PJ. An empirical investigation of patients’ acceptance and resistance toward the health cloud: the dual factor perspective. Comput Human Behav. 2016;63:959–69.

    Article  Google Scholar 

  41. Esmaeilzadeh P, Sambasivan M, Kumar N, Nezakati H. Adoption of clinical decision support systems in a developing country: antecedents and outcomes of physician's threat to perceived professional autonomy. Int J Med Inform. 2015;84(8):548–60.

    Article  PubMed  Google Scholar 

  42. Dünnebeil S, Sunyaev A, Blohm I, Leimeister JM, Krcmar H. Determinants of physicians’ technology acceptance for e-health in ambulatory care. Int J Med Inform. 2012;81(11):746–60.

    Article  PubMed  Google Scholar 

  43. Chau P, Hu P. Examining a model of information technology acceptance by individual professionals: an exploratory study. J Manag Inform Syst. 2002;18(4):191–229.

    Article  Google Scholar 

  44. Abdullah JL, Seng LC. Acceptance of cloud computing in Klang Valley's health care industry. Malaysia Int J Econ Comm Manag. 2015;3(6):392–415.

    Google Scholar 

  45. Sedem AA, Twum F, Panford JK. Cloud computing framework for e-health in Ghana: adoption issues and strategies: case study of Ghana health service. J Comput. 2015;118(17):13–7.

    Google Scholar 

  46. Heselmans A, Aertgeerts B, Donceel P, Geens S, Van de Velde S, Ramaekers D. Family physicians’ perceptions and use of electronic clinical decision support during the first year of implementation. J Med Syst. 2012;36(6):3677–84.

    Article  PubMed  Google Scholar 

  47. Yu CS. Factors affecting individuals to adopt mobile banking: empirical evidence from the UTAUT model. J Elec Comm Res. 2012;13(2):104.

    Google Scholar 

  48. Negahban A, Chung CH. Discovering determinants of user’s perception of mobile device functionality fit. Comput Human Behav. 2014;35:75–84.

    Article  Google Scholar 

  49. Payton FC, Pare G, Le Rouge CM, Reddy M. Health care IT: process, people, patients and interdisciplinary considerations. J Assoc Inform Syst. 2011;12(2):4.

    Google Scholar 

  50. National Health Act, 2014. Available from https://nass.gov.ng/document/download/7990. Accessed 17 Sept 2018.

  51. Vanneste D, Vermeulen B, Declercq A. Healthcare professionals’ acceptance of BelRAI, a web-based system enabling person-centred recording and data sharing across care settings with interRAI instruments: a UTAUT analysis. BMC Med Inform Decis Mak. 2013;13(1):129.

    Article  PubMed  PubMed Central  Google Scholar 

  52. Tavares J, Oliveira T. Electronic health record portal adoption: a cross country analysis. BMC Med Inform Decis Mak. 2017;17(1):97.

    Article  PubMed  PubMed Central  Google Scholar 

  53. Park N, Roman R, Lee S, Chung JE. User acceptance of a digital library system in developing countries: an application of the technology acceptance model. Int J Inform Manag. 2009;29(3):196–209.

    Article  Google Scholar 

  54. Ahlan AR, Ahmad BIE. User acceptance of health information technology (HIT) in developing countries: a conceptual model. Procedia Tech. 2014;16:1287–96.

    Article  Google Scholar 

  55. Baptista G, Oliveira T. Understanding mobile banking: the unified theory of acceptance and use of technology combined with cultural moderators. Comput Human Behav. 2015;50:418–30.

    Article  Google Scholar 

  56. Phichitchaisopa N, Naenna T. Factors affecting the adoption of healthcare information technology. EXCLI J. 2013;12:413.

    PubMed  PubMed Central  Google Scholar 

  57. Becker D. Acceptance of mobile mental health treatment applications. Procedia Comput Sci. 2016;98:220–7.

    Article  Google Scholar 

  58. Currie WL, Seddon JJ. A cross-national analysis of eHealth in the European Union: some policy and research directions. Inform Manag. 2014;51(6):783–97.

    Article  Google Scholar 

  59. Kim KK, Joseph JG, Ohno-Machado L. Comparison of consumers’ views on electronic data sharing for healthcare and research. J Am Med Inform Assoc. 2015;22(4):821–30.

    Article  PubMed  PubMed Central  Google Scholar 

  60. Abu-Dalbouh HM. A questionnaire approach based on the technology acceptance model for mobile tracking on patient progress applications. J Comput Sci. 2013;9(6):763–70.

    Article  Google Scholar 

  61. De Sena Abrahão R, Moriguchi SN, Andrade DF. Intention of adoption of mobile payment: an analysis in the light of the unified theory of acceptance and use of technology (UTAUT). RAI. 2016;13(3):221–30.

    Article  Google Scholar 

  62. Martins C, Oliveira T, Popovič A. Understanding the internet banking adoption: a unified theory of acceptance and use of technology and perceived risk application. Int J Inform Manag. 2014;34(1):1–13.

    Article  Google Scholar 

  63. Nikou SA, Economides AA. Mobile-based assessment: integrating acceptance and motivational factors into a combined model of self-determination theory and technology acceptance. Comput Human Behav. 2017;68:83–95.

    Article  Google Scholar 

  64. Lescevica M, Ginters E, Mazza R. Unified theory of acceptance and use of technology (UTAUT) for market analysis of FP7 CHOReOS products. Procedia Comput Sci. 2013;26:51–68.

    Article  Google Scholar 

  65. NHS Chelsea & Westminster Hospital “Patient Survey” Imperial College London. Available from http://www.chelwest.nhs.uk/about-us/organisation/foi/foi-disclosure-log/foi-log-2015/cancer-services/foi-2015-506-renal-cell-carcinoma-with-attachments.pdf. Accessed 27 Apr 2018.

  66. Halawi LA, McCarthy RV, Aronson JE. An empirical investigation of knowledge management systems’ success. J Comput Inform Syst. 2008;48(2):121–35.

    Google Scholar 

  67. Al-Somali SA, Gholami R, Clegg B. Internet banking acceptance in the context of developing countries: an extension of the technology acceptance model. In: European Conference on Management of Technology; 2008. Accessed 29 Jan 2018.

    Google Scholar 

  68. Fraser H, Biondich P, Moodley D, Choi S, Mamlin B, Szolovits P. Implementing electronic medical record systems in developing countries. J Innov Health Inform. 2005;13(2):83–95.

    Article  Google Scholar 

  69. Fornell C, Larcker DF. Evaluating structural equation models with unobservable variables and measurement error. J Mark Res. 1981;18:39–50.

  70. Dormekpor E. Poverty and gender inequality in developing countries. Dev Ctry Stud. 2015;5(10):76–102.

    Google Scholar 

  71. Bagozzi RP. Evaluating structural equation models with unobservable variables and measurement error: a comment. J Mark Res. 1981;18:375–81.

  72. Morse JM, Barrett M, Mayan M, Olson K, Spiers J. Verification strategies for establishing reliability and validity in qualitative research. Int J Qual Meth. 2002;1(2):13–22.

    Article  Google Scholar 

  73. Hair JR, Anderson RE, Tatham RL, Black WC. Multivariate data analysis with readings. New York: Macimillan; 1992.

    Google Scholar 

  74. Koo TK, Mae YL. A guideline of selecting and reporting intraclass correlation coefficients for reliability research. J Chiropr Med. 2016;15(2):155–63.

    Article  PubMed  PubMed Central  Google Scholar 

  75. Fleiss JL, Cohen J. The equivalence of weighted kappa and the intraclass correlation coefficient as measures of reliability. Edu Psychol Meas. 1973;33(3):613–9.

    Article  Google Scholar 

  76. Peter JP. Reliability: A review of psychometric basics and recent marketing practices. J Mark Res. 1979;16:6–17.

  77. Zissis D, Lekkas D. Addressing cloud computing security issues. Future Gener Comput Syst. 2012;28(3):583–92.

    Article  Google Scholar 

  78. Ravangard R, Kazemi Z, Abbasali SZ, Sharifian R, Monem H. Development of the UTAUT2 model to measure the acceptance of medical laboratory portals by patients in shiraz. Elect Phys. 2017;9(2):386.

    Google Scholar 

  79. Olok GT, Yagos WO, Ovuga E. Knowledge and attitudes of doctors towards e-health use in healthcare delivery in government and private hospitals in northern Uganda: a cross-sectional study. BMC Med Inform Decis Mak. 2015;15(1):87.

    Article  PubMed  PubMed Central  Google Scholar 

  80. Abodunrin O, Akande T. Knowledge and perception of e-health and telemedicine among health professionals in LAUTECH teaching hospital, Oshogbo, Nigeria. Int J Health Res. 2009;2(1);51–58.

  81. Jarosławski S, Saberwal G. In eHealth in India today, the nature of work, the challenges and the finances: an interview-based study. BMC Med Inform Decis Mak. 2014;14(1):1.

    Article  PubMed  PubMed Central  Google Scholar 

  82. Steininger K, Stiglbauer B. EHR acceptance among Austrian resident doctors. Health Policy Tech. 2015;4(2):121–30.

    Article  Google Scholar 

  83. Hsieh PJ. Healthcare professionals’ use of health clouds: Integrating technology acceptance and status quobias perspectives. Int J Med Inform. 2015;84(7):512–23.

Download references

Acknowledgements

Special thanks to the management and staffs of Benue state ministry of health for their assistance and corporation.

Funding

There was no funding for this research.

Availability of data and materials

The anonymous datasets from the present study are available from the corresponding author on reasonable request. No identifying/confidential patient data were collected.

Author information

Authors and Affiliations

Authors

Contributions

All authors contributed immensely to the success of the research. While PEI and MT were responsible for the acquisition, analysis and interpretation of data, HN and EC were responsible for the proposed model development, conceptual design and manuscript revision. The whole manuscript was read and approved by all the authors.

Corresponding author

Correspondence to Mehmet Toycan.

Ethics declarations

Authors’ information

Patience Ebekeyi Idoga

Patience E. Idoga is a PhD candidate in the department of Management information systems at Cyprus International University. Her research interest focuses majorly on the application and usage of modern health technologies as well as harnessing the advantages of cloud computing utilities in healthcare with specific emphasis on the usage of ICT to leverage the gap between urban and remote rural villages in developing countries.

Email: 20153744@student.ciu.edu.tr

Assoc. Prof. Dr. Mehmet Toycan

Assoc. Prof. Dr. Mehmet Toycan received the B.Sc. degree from the Department of Electric and Electronic Engineering, Eastern Mediterranean University, in 2004, and the M.Sc. degree in telecommunications and information systems and the Ph.D. degree in electronics from the University of Essex, Colchester, U.K., in 2005 and 2009, respectively. During the Ph.D. degree, he was a member of the Access Networks Laboratory, Department of Computer and Electronic Systems, University of Essex. He was also involved in the Network of Excellence Project and Building the Future Optical Network Project in Europe, where he was collaborating with groups from other universities to develop efficient and low-cost optical access network architectures. He is currently a full-time Lecturer and the Director of the Communication Technologies Research Center, Cyprus International University. His research interests are in the fields of cost and energy efficient scalable optical access networks for FTTH scenarios featuring wireless communication transmission and implant antenna designs for wireless health monitoring applications. In addition, his Information Systems Research Team is currently working on electronic health solutions for developing countries.

Email: mtoycan@ciu.edu.tr

Prof. Dr. Halil Nadiri

Prof. Dr. Halil Nadiri was born in Nicosia, Cyprus, in 1970. By following his undergraduate and graduate studies in business administration, he proceeded the Ph.D. studies in the areas of marketing and completed in 1998. He was an Assistant Professor in 1999, an Associate Professor in 2005, and a Professor of marketing in 2011. He was the Vice Rector with Eastern Mediterranean University from 2003 to 2007 and from 2009 to 2014. During his tenure with EMU, he was promoted to various positions, such as the Coordinator of research and education with the Rector’s Office and the Director of the School of Tourism and Hospitality Management. He was the President of the Administrative Board of Atatürk Teacher Training Academy from 2009 to 2013. He was promoted as the Rector of Cyprus International University in 2015. He is currently the President of Cyprus Universities Association. He has more than 50 manuscripts published in international and national journals. He was a member and the president of various administrative boards. He also has presentations done in international and national conferences. According to a study carried out by Webometrics, he has also been ranked among the top 2000 Turkish scholars. He is married and has one child. Email: hnadiri@ciu.edu.tr

Assoc. Prof. Dr. Erbug Celebi

Assoc. Prof. Dr. Erbug Celebi received the B.Sc. degree in computer science and applied mathematics from Ege University, Turkey, in 1996, and the M.Sc. and Ph.D. degrees in computer engineering from Dokuz Eylül University, İzmir, Turkey, in 1999 and 2006, respectively. He is currently a Professor with the Department of Management Information Systems, Cyprus International University. His interests include information retrieval, machine learning, and information systems. Email: ecelebi@ciu.edu.tr

Ethics approval and consent to participate

Prior to the distributions of questionnaires, a written ethical consent specifying that participation in the survey is voluntary and that information given in the survey would be treated as confidential was given to the participants and they all agreed to take part in the survey. Also, an ethical approval from the National Health Research Ethics Committee of the Federal Ministry of Health in Nigeria: A body mandated for the stipulation and enactment of rules and regulation governing the administration of all healthcare services in the Federal Republic of Nigeria was given with the reference number MOH/STA/204/Vol.1/28. The consent statement is shown below:

“Your participation is voluntary and you are free not to participate or refuse to answer any question. Are you willing to participate in this survey? Agreed [ ] Refused [ ]”.

Consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Rights and permissions

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Idoga, P.E., Toycan, M., Nadiri, H. et al. Assessing factors militating against the acceptance and successful implementation of a cloud based health center from the healthcare professionals’ perspective: a survey of hospitals in Benue state, northcentral Nigeria. BMC Med Inform Decis Mak 19, 34 (2019). https://doi.org/10.1186/s12911-019-0751-x

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://doi.org/10.1186/s12911-019-0751-x

Keywords