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Title
Strengthening health systems through eHealth: two mixed-methods case studies at 10 facilities in Malawi |
Full text
http://hdl.handle.net/1842/35566 |
Date
2018 |
Author(s)
Kawale, Paul |
Contributor(s)
Pagliari, Claudia; Grant, Liz; other |
Abstract
BACKGROUND:
International agencies such as the World Health Organisation have highlighted the
potential of digital information and communications technologies to strengthen health
systems, which are underpinned by the 'building blocks' of information, human resources,
finances, commodities, leadership and governance, and service delivery. In high income
countries, evidence of the positive impacts of 'eHealth' innovations on the cost-effectiveness
of healthcare is growing and many governments are now providing
incentives for their adoption. In contrast, the use of eHealth in developing countries has
remained low and efforts to introduce these new approaches have experienced high
failure rates. There is even scepticism regarding the feasibility of eHealth in low-resource
settings, which may be hindered by high costs, indeterminate returns on investment,
technical problems and socio-organisational barriers.
More research is needed to document both the value of eHealth for strengthening resource-limited
health systems and the challenges involved in their implementation and adoption,
so that insights from such research may be used to inform future initiatives. While many
studies of eHealth for patient care in low- and middle-income countries (LMIC) are taking
place, evidence of its role in improving administrative processes such as financial
management is lacking, despite the importance of 'good governance' (transparency and
accountability) for ensuring strong and resilient health systems.
The overall objective of this PhD was to elucidate the enablers, inhibitors and outcomes
characterising the implementation and adoption of a modular eHealth system in a group
of healthcare facilities in rural Malawi. The system included both clinical and billing
modules. The specific objectives were (i) to understand the socio-technical, organisational
and change management factors facilitating or hindering the implementation and
adoption of the eHealth system, (ii) to assess the quality of data captured by the eHealth
system compared with conventional paper-based records, and (iii) to understand how
information within the eHealth system was used for service delivery, reporting and
financial management. A further aim was to contribute to the corpus of mixed-methods
case studies exploring eHealth system implementation processes and outcomes (including
data quality) in LMIC. As described in the following chapters, the research also gave rise
to unanticipated and serendipitous findings, which led to new lines of enquiry and
influenced the theoretical perspectives from which the analysis drew.
METHODS:
Mixed-methods case study was used for the research, taking a 'soft-positivist' approach
to analysis, which encompasses both inductive and deductive forms of enquiry. Two case
studies were undertaken in rural Malawi: one at a 300-bed fee-for-service hospital, and
the other at nine primary care health centres that surround the hospital. At the outset of
the research, the 'logic model' underpinning the eHealth system implementation
programme was mapped, based on formative scoping to articulate the goals and
intentions of those commissioning and supplying the eHealth system, along with
literature-informed theory. This provided a framework against which to evaluate the
processes and outcomes of eHealth system implementation at the ten facilities.
For the hospital case study (Case Study 1), a retrospective single-case embedded design was
employed, with outpatient and inpatient departments being the two units of analysis.
Qualitative data included document review and in-depth key informant interviews, while
quantitative data was obtained from the web-based District Health Information System
(DHIS2), patient files and the hospital's finance records. For the study of primary health
centres (Case Study 2), a single-case embedded design was also used, with the rollout
project as the case and the three units of analysis being 3 Early Adopter Facilities, 4 Late
Majority facilities and 2 Laggard facilities. This case study used a prospective design, with
data being collected 7 months and 24 months after implementation of the eHealth system
due to a mismatch between the independent eHealth implementation project and the PhD
research. Data sources included documentation screened against the criteria listed in the
Performance of Routine Information System Management (PRISM) tools, information
extracted from the eHealth system, health indicators drawn from DHIS2 and qualitative
data from focus group discussions. In both case studies, framework analysis was used for
qualitative data, while quantitative data was analysed by calculating data completeness,
accuracy and agreement. Descriptive statistics and the Mann-Whitney U-test were used
for analysing finance data in Case Study 1. Content analysis was also used to gain insights
from Case Study 2.
RESULTS:
Based on the initial logic model, staff-, service delivery- and management-level outcomes
were moderated through the organisational change management and socio-technical
factors described below.
Key organisational and process factors influencing system implementation
Change management processes: Organisational strategies aimed at facilitating the
introduction of the eHealth system included training clinical and clerical staff in the
computer skills required to use it (see below) and adapting work processes to accommodate
and optimise adoption. At the three health facilities where the billing module was
implemented, the latter included introducing new procedures for providing electronic
receipts to clients and service providers. At Madalo Hospital this also involved the
creation of a new category of administrative staff with responsibility for managing the
appropriate capture, entry and exchange of data using the system. However, such data
clerks were only introduced within the inpatient department, whilst already overburdened
clinical staff in the outpatient department were expected to integrate the
eHealth system into their existing work routines. Outpatient departments at the health
centres resorted to task-shifting patient data entry roles from clinicians to lower-educated
allied staff such as janitors and security guards.
Infrastructure and security issues: Organisational enablers were infrastructural and policy
interventions aimed at securing equipment and patient data. These included installations
of locks and burglar-proof bars, enhanced engagement of security guards and frequent
backup of data. An organisational intervention undertaken at the health centres was the
introduction of backup batteries and solar power, aimed at providing a continuous
electricity supply. However, problems with battery depletion, frequent connectivity
interruptions between the client computers and the server and electricity fluctuations and
outages, affected both the efficiency of the batteries and the practical utility of the eHealth
system. Highly efficient nano-computing units were later introduced, to reduce electricity
demands and improve the consistency of available power for the purposes of using the
system.
Socio-technical issues arising during the implementation process
Technical/software problems: There were 24 problems identified with the eHealth system,
encompassing its design flaws, security protocols, and hardware and database limitations.
For instance, entry of patient data was in multiple windows needing to be minimised,
passwords expired with no one at the facilities with rights to issue new passwords, there
were frequent disconnections between the client computers and the server, and lists of
drugs and indicators for reporting in its database were limited. Although health centre
staff used the system for backup storage and retrieval of data, only Early Adopters
reported use of the eHealth system's search function.
Socio-technical issues: The technical problems outlined above resulted in a heavy reliance
on paper records by the health centres, although centres varied in their attitude towards
and persistence with eHealth system implementation, with Early Adopter sites
overcoming most challenges. At the hospital, the eHealth system was subjected to such
inappropriate use by staff that even establishing rules and an IT centre to regulate usage
were ineffective, leading to a system crash in 2012 due to viruses and other malware. Such
inappropriate use included staff depleting hospital server space by storing personal files
(videos, music, pictures, games), being on Facebook instead of attending to patients,
sharing of login credentials and not always logging off their account after use, and
removal of cables from the computers.
Leadership: At the hospital, there was strong management support for the eHealth system.
In contrast, there were strong opinions from staff at Late Majority and Laggard facilities
about the ineffective engagement of health facility 'in-charges'. Further, many system
champions were senior staff and thus busier and more mobile, most often leaving the
junior staff at the health centres, who were not formally trained, to be using the eHealth
system.
Training: Limitations in the scope and number of staff formally trained was perceived to
be a barrier to eHealth system adoption at the health centres, particularly lack of training
in basic troubleshooting and maintenance. Even peer training lacked follow-up formal
training. At the hospital, developing an appropriately skilled cadre of system users was
hindered by high staff turnover and departmental rotations, which required frequent
rounds of basic training. Staff at the hospital and health centres were nevertheless happy
about the computer knowledge they had gained as a result of the implementation
programme, although most expressed a lack of confidence in using the eHealth system.
Technical support: For reasons including those already outlined, staff requested support for
a range of hardware and software problems, not all of which it was possible to fulfil in a
timely way, due to lack of sufficient IT personnel. Lack of in-country technical support for
the software was also a considerable barrier to progress, particularly for the IT team based
at the hospital, requiring requests for changes to be passed to the parent company. In one
attempt to address this, the rights to a partial version of the software was passed to a local
foundation for onward management, however the software developers were unwilling to
release the source code so that further enhancements and customisation could be made.
Efforts to recruit more hospital IT workers and reorganising responsibilities were
frustrated by high staff turnover among the IT team. As a result, response to calls from
health centres for technical support by the IT team was said to be slow and ineffective
(except at Late Majority Facilities), and there was no transfer of basic troubleshooting and
minor repair skills from the IT team to the health facility staff.
PERCEIVED OUTCOMES:
Despite the challenges described above, some tracer outcomes of the
eHealth system were detectable from the qualitative and numerical results, relating to data
quality, service delivery, reporting and decision-making, and financial management.
Perceived and measured outcomes of eHealth system implementation
DOCUMENTATION AND ASSOCIATED WORKLOAD:
In both case studies, implementation of the eHealth
system illuminated the dysfunctional paper-based system, particularly loss of documents.
At the health centres (Case Study 2), only Early Adopters reported reduced administrative
and patient care workload following eHealth implementation, while the other adopter
groups reported increased workload due to dual use of paper and electronic systems, as
well as staff shortage and high patient load.
Data quality: Both case studies reported poor data quality in the eHealth system, mainly
due to the dual use of the paper-based and electronic systems, and staff defaulting to using
the paper-based system only. This was aggravated by infrastructure and leadership
problems at the health centres. Across the health centres, completeness of outpatient
registration data in the eHealth system was 82.4%, as compared to DHIS2 (100.0% for Early
Adopters, 73.9% for Late Majority), equivalent to an average monthly omission of 1,271
clients. When compared to DHIS2 data at Madalo Hospital, outpatient registration data in
the eHealth system was 76.0% complete, under-reporting by an average 577 clients per
month. Compared with the hospital's paper-based records, inpatient registration and
diagnosis data in the eHealth system, as entered by ward clerks, was 93.6% complete and
68.9% accurate.
Service delivery (efficiency and patient experience): At Madalo Hospital, the eHealth system
was reported to have made retrieval of patients' paper files faster, as the implementation
project had also led to changes in the hospital's filing system. This new filing system also
facilitated retrieval of data for patients with lost paper records, and allowed linking of
patients' outpatient and inpatient records. Reported service delivery improvements at the
health centres included enhanced ability for tracing patients, treatment continuity,
identifying the correct patient, ensuring patient confidentiality, keeping health workers
alert and available, following clinical protocols, identifying the need to change
prescription for (or refer) a recurrent patient, and reportedly showing the patient that the
provider was paying attention. Improvements in patient experience were perceived to be
through avoiding the need for patient details to be re-entered at subsequent visits, better
management of queues, and patients feeling more understood by the service provider and
having more confidence in the services. Perceived negative patient experiences were
associated with staff members' slow typing skills and unfamiliarity with the eHealth
system, dual entry of patient information into both the electronic and paper systems, extra
steps added to the patient journey through the care process, and disrupted patient-provider
interaction.
EFFICIENCY OF REPORTING:
After its implementation at the hospital site, the eHealth system had
become routinely used to generate data for measuring quality of care, and partly for
national reporting purposes (HMIS). Customised reports for the hospital were created and
used for decisions such as allocation of wards, advocacy and funding applications. In
contrast, all the primary healthcare facilities were still using paper registers to compile
HMIS reports, a few in combination with the eHealth system, because of lack of
knowledge of the reporting module, poor design of the system's reports, and disruptions
in electricity and network connections to the server.
MANAGEMENT OF FINANCES:
Financial management was reported to have improved at Madalo
Hospital due to better-quality data capture and tracking of service charges, separation of
billing and receiving roles by recruiting ward clerks, enhanced oversight by management,
and fraud prevention through greater transparency and accountability. Although median
monthly revenue was significantly higher after eHealth system implementation (P=0.024),
micro- and macro-contextual factors confounded this effect, and the descriptive and
qualitative data revealed that genuine improvement only came about after recruitment of
ward clerks towards the end of the study period. At the health centres, the eHealth system
reportedly helped staff in the accounts department with billing, the facility in-charges with
financial oversight, and clients with more trust in printed receipts.
CONCLUSION:
Converging the results of these two case studies illustrates the potential of eHealth to
strengthen LMIC health systems through developing human resource capacity (skills,
staff roles), facilitating service delivery, and improving financial management and
governance. However, realising such improvements is dependent upon understanding
the socio-technical interactions mediating the integration of new systems into
organisational processes and work practices, and implementing appropriate change
management interventions. The results of this study suggest that, for effective
implementation and adoption of eHealth systems, healthcare leaders should (1) recruit
data entry clerks to relieve clinical staff, improve workflow and avoid data fraud, (2)
facilitate appropriate data use among system users and an information culture at the
facilities, and (3) strengthen knowledge and skills transfer from eHealth system
developers to local implementers and system champions, to optimise responsiveness and
ensure sustainability. Further interdisciplinary research is needed to obtain additional
insights into factors affecting the quality of eHealth data and its use in the management of
LMIC health systems, including the role of social, professional and technological
influences on financial good-governance. |
Subject(s)
global health; eHealth; mixed methods; case study; Malawi |
Language
en |
Publisher
The University of Edinburgh |
Type of publication
Thesis or Dissertation; Doctoral; PhD Doctor of Philosophy |
Format
application/pdf |
Repository
Edinburgh - University of Edinburgh
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Added to C-A: 2023-03-20;12:07:44 |
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