Assessing the capacity of Malawi’s district and central hospitals to manage traumatic diaphyseal femoral fractures in adults

Kiran J. Agarwal-Harding; Linda Chokotho; Sven Young; Nyengo Mkandawire; Mabvuto Chawinga; Elena Losina; Jeffrey N. Katz

doi:10.1371/journal.pone.0225254

Abstract

Background

The burden of musculoskeletal trauma is growing worldwide, disproportionately affecting low-income countries like Malawi. However, resources required to manage musculoskeletal trauma remain inadequate. A detailed understanding of the current capacity of Malawian public hospitals to manage musculoskeletal trauma is unknown and necessary for effective trauma system development planning.

Methods

We developed a list of infrastructure, manpower, and material resources used during treatment of adult femoral shaft fractures–a representative injury managed non-operatively and operatively in Malawi. We identified, by consensus of at least 7 out of 10 experts, which items were essential at district and central hospitals. We surveyed orthopaedic providers in person at all 25 district and 4 central hospitals in Malawi on the presence, availability, and reasons for unavailability of essential resources. We validated survey responses by performing simultaneous independent on-site assessments of 25% of the hospitals.

Results

No district or central hospital in Malawi had available all the essential resources to adequately manage femoral fractures. On average, district hospitals had 71% (range 41–90%) of essential resources, with at least 15 of 25 reporting unavailability of inpatient ward nurses, x-ray, external fixators, gauze and bandages, and walking assistive devices. District hospitals offered only non-operative treatment, though 24/25 reported barriers to performing skeletal traction. Central hospitals reported an average of 76% (71–85%) of essential resources, with at least 2 of 4 hospitals reporting unavailability of full blood count, inpatient hospital beds, a procedure room, an operating room, casualty/A&E department clinicians, orthopaedic clinicians, a circulating nurse, inpatient ward nurses, electrocardiograms, x-ray, suture, and walking assistive devices. All four central hospitals reported barriers to performing skeletal traction. Operative treatment of femur fracture with a reliable supply of implants was available at 3/4 hospitals, though 2/3 were dependent entirely on foreign donations.

Conclusion

We identified critical deficiencies in infrastructure, manpower, and essential resources at district and central hospitals in Malawi. Our findings provide evidence-based guidance on how to improve the musculoskeletal trauma system in Malawi, by identifying where and why essential resources were unavailable when needed.

Citation: Agarwal-Harding KJ, Chokotho L, Young S, Mkandawire N, Chawinga M, Losina E, et al. (2019) Assessing the capacity of Malawi’s district and central hospitals to manage traumatic diaphyseal femoral fractures in adults. PLoS ONE 14(11): e0225254. https://doi.org/10.1371/journal.pone.0225254

Editor: Itamar Ashkenazi, Technion - Israel Institute of Technology, ISRAEL

Received: September 1, 2019; Accepted: October 26, 2019; Published: November 20, 2019

Copyright: © 2019 Agarwal-Harding et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

Data Availability: The raw data that underlie the findings of this manuscript are fully available without restriction here: Agarwal-Harding, Kiran, 2019, "Assessment of the capacity of Malawi’s district and central hospitals to manage traumatic diaphyseal femoral fractures in adults", https://doi.org/10.7910/DVN/QI3KYH, Harvard Dataverse, V1, UNF:6:FMfUrri638gHFa5Uhx4pqA== [fileUNF].

Funding: One author (K.J.A.H.) was supported by the Clinical Orthopedic and Musculoskeletal Education and Training Program at Brigham and Women’s Hospital (NIH AR-T32-055885), and a Global and Humanitarian Health Center of Excellence Travel Grant from Partners Healthcare. Two authors received funding from the National Institutes of Health (NIH) from grants AR-P30-0072577 (E.L. and J.N.K.) and AR-K24-057827 (E.L.). Two authors of this study (K.J.A.H. and L.C.) received grant support from the AO Alliance Foundation. Partners COE Travel Grant: https://www.partners.org/Graduate-Medical-Education/Centers-Of-Expertise/Global-And-Humanitarian-Health/Travel-Grant/Default.aspx. AO Alliance Foundation: https://ao-alliance.org/. All funders played no role in the study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Competing interests: The authors have declared that no competing interests exist.

Introduction

Trauma accounts for an increasing burden of death and disability worldwide, disproportionately affecting low- and middle-income countries (LMICs) [1–4]. Short- and long-term trauma-related disability can be especially crippling for the poorest patients who can enter a vicious cycle of poverty due to associated healthcare costs and decreased productivity [5, 6]. Due in large part to a rising number of road injuries, musculoskeletal impairment is increasingly common in LMICs [2, 3, 7–12]. Significant injury-related disability is preventable with quality trauma and surgical care, which unfortunately remains out of reach for many patients, especially in LMICs [8, 13–18].

Malawi is a low-income country in southeastern Africa of about 19 million people, 83% of whom live in rural areas [19, 20]. Traumatic injuries and musculoskeletal impairment are common, though the resources to manage musculoskeletal trauma remain inadequate [12, 21–26]. About 60% of total healthcare services in Malawi are provided by public hospitals, which are organized into three levels [27]. The primary level is a health center, providing basic medical and maternity care, and no surgical care. The secondary level is a district hospital staffed by general doctors and clinical officers, providing non-specialized surgical care. The tertiary level is a central hospital, which provides specialist care. Trauma care is offered at district and central hospitals, though the availability of essential resources to safely manage patients with musculoskeletal injuries is largely unknown [28, 29].

Diaphyseal femoral fracture is a common injury treated in Malawian hospitals [30]. We have previously found that every week in Malawi, approximately one adult patient with femoral shaft fracture presents to each district hospital and 4 present to each central hospital [31, 32]. They are largely treated non-operatively with skeletal traction, with operative treatment available only at the central hospitals [33]. For additional details regarding musculoskeletal trauma care and the burden of femoral shaft fracture in Malawi, see the supplementary appendix (S1 File). We sought to assess the musculoskeletal trauma care capacity of all public district and central hospitals in Malawi, under the jurisdiction of the Ministry of Health, by examining capacity in the context of non-operative and operative treatment of femoral shaft fracture as a representative injury.

Methods

Capacity survey tool

We developed a capacity assessment survey examining femoral shaft fracture management (S1 File). We adapted the methodology performed by Stewart et al in 2015 during their strategic assessment of trauma care capacity in Ghana [34]. We first identified items relevant to musculoskeletal trauma in the WHO Guidelines for Essential Trauma Care (GETC) [35], and used our own clinical experience in Malawi to create a list of 51 important items of infrastructure, manpower, and material resources (Table 1). We assessed three phases of care: 1) initial management, including resuscitation, treatment of open fracture, stabilization/immobilization, and admission; 2) definitive treatment, including non-operative and operative treatment; and 3) aftercare, including pain management, discharge planning, mobilization, and rehabilitation. In each hospital, we assessed whether each item was routinely present, and each item’s actual availability in the last 7 days. We solicited reasons for unavailability of infrastructure, key procedures, and material resources. Reasons for unavailability of staff were not solicited.

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Table 1. Infrastructure, manpower, and material resources for management of adult femoral shaft fractures in Malawi.

https://doi.org/10.1371/journal.pone.0225254.t001

Definition of essential resources

We assembled an expert panel of 10 clinicians with experience managing femur fracture in Malawi or a similar low-resource environment. Five panelists were practicing in Malawi, two in the UK, two in the US, and one in South Africa. Eight panelists were orthopaedic surgeons, and two were orthopaedic surgery residents. We sent each expert an electronic survey with the 51 items identified by study investigators as important in the management of femoral shaft fracture. Following the same format as the WHO GETC, panelists classified items as essential, desirable, possibly required, or irrelevant at the district and central hospital level. All items marked essential by at least 7 of the 10 panelists–representing a two-thirds majority consensus [36, 37]–were considered essential (i.e. a minimum requirement) for safe management of adult femoral shaft fractures.

Capacity survey administration

We collected capacity survey data from all 25 district and 4 central hospitals in Malawi (Fig 1, S1 Table). Between May 29 and June 15, 2018, capacity surveys were hand-delivered to each hospital’s orthopaedics department, and the first author (K.J.A.H.) performed in-person informed consent in writing of all survey respondents. An orthopaedic clinical officer (OCO)–a non-physician clinician–or an orthopaedic surgeon at each hospital completed the survey alone. To assess the validity of survey responses, we randomly selected 25% of the hospitals (6 district hospitals and 1 central hospital) by computer algorithm for additional “spot checks”. During these “spot checks”, the first author independently completed the capacity survey, personally inspecting the hospital facilities and resources, and speaking directly with hospital personnel in relevant clinical departments. “Spot checks” were performed simultaneously with the first author’s visit to each hospital, and with the assistance of staff members who had not completed the survey themselves. To minimize interruption of clinical workflow, we notified hospitals prior to the visit and if they had been selected for a “spot check”.

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Fig 1. Location of all government district and central hospitals in Malawi.

District hospitals are each represented by a yellow dot, central hospitals by a green dot. All hospitals are listed in S1 Table. Original maps were sourced from USGS National Map Viewer (http://viewer.nationalmap.gov/viewer/) and Maps at the CIA (https://www.cia.gov/library/publications/the-world-factbook/index.html). Figure is similar but not identical to the original images; for illustrative purposes only.

https://doi.org/10.1371/journal.pone.0225254.g001

Data analysis

Comparing survey respondents to the study investigators during “spot checks”, we determined inter-rater reliability by percent agreement and Cohen’s kappa statistics [38, 39]. We then examined the total number of district and central hospitals where each surveyed item was present and available in the last 7 days. For items where hospitals reported reasons for unavailability, we determined the most common reasons. Using the list of items identified as essential by our expert panel, we calculated the percentage of essential items present and available at each hospital. We examined average percentage of essential item availability by hospital level and geographic region, item type (infrastructure, manpower, material resource), and phase of care. Separately for district and central hospitals, we calculated the number of hospitals at which each item was unavailable and identified the most commonly missing essential items.

We performed all analyses using Microsoft Excel (Seattle, WA, USA) and SAS 9.4 (SAS Institute Inc., Cary, NC, USA). The College of Medicine Research Ethics Committee (COMREC P.02/18/2360) in Malawi and the Institutional Review Board at Brigham and Women’s Hospital, Boston, MA, USA provided ethical approval of the study.

Results

Capacity survey completion and reliability

The survey was completed by every government-run public district and central hospital in Malawi. Twenty-three district hospitals (92%) and all four central hospitals (100%) responded regarding the presence, availability, and reason for unavailability of each of the 51 surveyed items. Two district hospitals did not respond regarding post-anesthesia recovery room and low molecular weight heparin. One district hospital did not respond regarding walking assistive devices. Percent agreement of responses between survey respondents and study investigators during “spot checks” for all hospitals was 94% (range 85–99%), and Cohen’s kappa coefficient of inter-rater reliability was 0.88 (95% CI 0.84–0.91) showing substantial to near-perfect agreement (Table 2) [39].

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Table 2. Capacity survey inter-rater reliability.

https://doi.org/10.1371/journal.pone.0225254.t002

Essential resources

Essential items that would be a minimum requirement to safely manage adult femoral shaft fractures were identified by expert panel consensus. Essential items included 3 infrastructure, 5 manpower, and 21 material resources at the district hospital level; and 7 infrastructure, 9 manpower, and 25 material resources at the central hospital level (Table 1). At both the district and central hospital levels, essential items pertained primarily to monitoring of vital signs, fluid resuscitation, pain management, x-ray diagnosis of fracture, temporary fracture stabilization, non-operative fracture treatment, inpatient hospitalization, and rehabilitation. At the central hospital level, essential items additionally pertained to pre-operative evaluation and operative treatment of femoral shaft fractures.

Essential resource availability in district hospitals

Availability of each surveyed item is presented in Table 1. No district hospitals had all essential items to safely manage femoral shaft fractures. On average, district hospitals had 71% (range 41–90%) of all essential items, 72% (range 0–100%) of essential infrastructure, 80% (range 40–100%) of essential manpower, and 69% (range 29–90%) of essential material resources. A mean of 80% (range 66–86%) of essential items were available at district hospitals in the northern region, 69% (range 41–90%) in the central region, and 69% (range 52–86%) in the southern region.

Nine district hospitals (36%) had all essential infrastructure, including 4/5 district hospitals in the northern region, 2/9 in the central region, and 3/11 in the southern region. Northern region district hospitals had the highest average availability of essential infrastructure (93%, range 67–100%), followed by the southern region (70%, range 33–100%), then the central region (63%, range 0–100%). Six district hospitals (24%) reported availability of all essential manpower, including 1/5 in the northern region, 3/9 in the central region, and 2/11 in the southern region. District hospitals in all three geographic regions, had a mean of 80% of essential manpower (northern: 80%, range 60–100%; central: 82%, range 60–100%; southern: 78%, range 40–100%). No district hospitals had all essential material resources. Northern region district hospitals had a mean of 78% (range 67–86%) of essential material resources, compared to 67% (range 29–90%) in the central region, and 67% (range 38–90%) in the southern region (Fig 2A).

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Fig 2. Average percentage of essential resources available in district and central hospitals.

District hospitals are plotted by geographic region. Results are plotted by resource type (A) and by resource phase of care (B).

https://doi.org/10.1371/journal.pone.0225254.g002

District hospitals had an average of 71% (range 40–93%) of essential items for initial management and stabilization of injured patients, 73% (range 43–95%) of essential items for definite fracture treatment, and 55% (range 0–100%) of essential items for aftercare and rehabilitation. Northern region district hospitals had the highest mean availability of essential items for initial management of femoral shaft fractures (79%, range 53–93%), followed by the southern region (72%, range 53–93%), then the central region (65%, range 40–93%). Average availability of essential items for definitive treatment was 80% (range 62–90%) in the northern region, 71% (range 43–95%) in the central region, and 71% (range 48–95%) in the southern region. For aftercare and rehabilitation, northern region district hospitals had the highest average essential item availability (60%, range 33–83%), followed by the central region (56%, range 0–100%), then the southern region (52%, range 0–83%) (Fig 2B).

The following essential resources were unavailable in 10 or more of the district hospitals: full blood count, inpatient ward nurses, x-ray, pain medications, blood products, skeletal traction, external fixators, gauze and bandages, and walking assistive devices (Table 3). Almost all district hospitals (24, 96%) reported barriers to providing skeletal traction. Drills were unavailable, broken, or absent (9/24 district hospitals). OCOs reported using a mallet (2/24) or T-handle (2/24) to insert pins. Only hand drills were available (9/24), and they would jam (3/24), need grease (1/24), or would be rusted and unusable (1/24). No T-handle was available for pin insertion/removal (5/24). There were inadequate supplies of weights (11/24), forcing providers to improvise solutions like using stones or bricks (3/24). There were inadequate supplies of appropriate hospital beds, functioning traction frames, or pulleys (15/24); inadequate supplies of traction pins (12/24), with pins being reused and becoming dull (1/24), and plaster being used to attach weights to pins (1/24). Staff members were reportedly unavailable at night or on the weekend (3/24), were inadequately trained to perform skeletal traction (1/24) and were inadequately trained to care for patients in skeletal traction (2/24).

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Table 3. Unavailable essential resources in Malawian district hospitals (n = 25).

https://doi.org/10.1371/journal.pone.0225254.t003

At the time of survey completion, skin traction–a temporary measure using strapping/adhesive tape applied to the skin for traction–was unavailable within the last 7 days in 5 (20%) of the district hospitals, with 19 hospitals (76%) reporting barriers to providing this treatment. Barriers included inadequate supplies of tape (10/19 district hospitals), with one hospital reporting that patients often had to buy their own; poor quality of tape (10/19), with the zinc oxide tape reportedly causing rashes/blisters (2/19). Staff members were reportedly inadequately trained to care for patients in skin traction (3/19) and were also unavailable at night or on the weekend (2/19).

Essential resource availability in central hospitals

No central hospitals had all essential items to safely manage femoral shaft fractures. Central hospitals had an average of 76% (range 71–85%) of all essential items—61% (range 43–71%) of essential infrastructure, 69% (range 56–78%) of essential manpower, and 83% (range 76–92%) of essential material resources (Fig 2A). The average central hospital had 78% (range 72–83%) of essential items for initial management, 78% (range 71–93%) for definitive treatment, and 91% (range 88–100%) for aftercare (Fig 2B).

The following items were absent or unavailable from two or more of the four hospitals: full blood count, inpatient hospital beds, procedure room, operating room, casualty/accident and emergency (A&E) department clinicians, orthopaedic clinical officers, orthopaedic surgeon, circulating nurse, inpatient ward nurses, electrocardiograms, x-ray, suture, and walking assistive devices (Table 4). Though unavailable in the last 7 days at only one central hospital, all central hospitals reported barriers to providing skeletal traction. Drills were unavailable or absent (2/4 central hospitals); there was inadequate supply of traction pins (1/4), weights (1/4), and traction frames (2/4); and staff members were reportedly inadequately trained to perform skeletal traction or care for patients in skeletal traction (1/4).

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Table 4. Unavailable essential resources in Malawian central hospitals (n = 4).

https://doi.org/10.1371/journal.pone.0225254.t004

Operative management of femoral shaft fractures was available at 3 central hospitals; unavailable at one while the orthopaedic surgeon was on holiday at the time of survey completion. In all 3 central hospitals where operative treatment was available, IM nails and large fragment sets were present, available, and with reliable supply. Two hospitals reported relying entirely on donations by visiting surgeons.

Discussion

We found that no district or central hospital in Malawi had available the minimum required essential resources to safely manage adult femoral shaft fractures. On average, only 71% of these essential resources were available in district hospitals, and 76% in the central hospitals. Though non-operative treatment remains the first-line treatment in Malawi, 96% of district hospitals and all 4 central hospitals reported barriers to performing skeletal traction. Operative treatment with a reliable supply of implants was available at 3 of the 4 central hospitals, though most central hospitals were entirely dependent on foreign donations, further limiting availability of surgical care.

The WHO GETC state that, at the district hospital level, basic immobilization is essential, skin and skeletal traction are possibly required, closed reduction of fractures is possibly required, and open reduction of fractures is irrelevant [35]. Our expert panel felt that resources necessary for immobilization, skin and skeletal traction, and closed reduction of fractures were all essential for Malawian district hospitals. This seems reasonable as Malawian district hospitals manage most of the musculoskeletal trauma nationwide [40, 41]. Our expert panel agreed with the WHO GETC that all of these services are essential at tertiary care (central) hospitals [35].

In a web-based survey of 267 district and central hospitals throughout East, Central, and Southern Africa by Chokotho et al, only 31% reported formal emergency departments to manage traumatic injuries [26]. In Malawi, we found that 60% of district hospitals and 100% of central hospitals reported availability of a casualty/A&E department, although we did not assess their actual functionality or capacity to manage trauma patients in depth. Chokotho et al reported that C-arms and CT scanner were available in fewer than 5% of district hospitals and in about 25% of central hospitals in the region [26]. We similarly found that only one district hospital in Malawi (4%) reported having a working C-arm, no district hospitals reported CT scanners, and only one central hospital (25%) had a functioning CT. We found that 2/4 of central hospitals had working c-arms that produced adequate quality images. Chokotho et al reported that closed fracture care was available in 72% of surveyed hospitals, and the tools necessary to surgically treat fractures were available in only 20% of district and 49% of central hospitals [26]. We similarly found that skeletal traction to non-operatively treat adult femoral shaft fractures was available in 15/25 (60%) of district hospitals and 3/4 of central hospitals. However, almost all hospitals reported barriers to providing this treatment, with many reporting inadequate or absent drills, and insufficient supply of traction pins, weights, and traction frames. IM nails and large fragment sets for operative treatment were present only at the central hospitals, and available when needed in 3/4 of central hospitals. However, at the time of this survey only 32% of district and 50% of central hospitals had adequate availability of x-ray to diagnose fractures, which our expert panel regarded as essential in both non-operative and operative treatment of fracture. No district or central hospital in Malawi had available all the essential resources to adequately manage adult femoral shaft fractures, though one district hospital had 90% and one central hospital had 85%. Ten percent of central hospitals in the study by Chokotho et al reported a sustainable supply of implants [26]. We observed higher rates of reliable implant supply among Malawian central hospitals, though with a complete dependency on foreign donations.

Malawi, like many other sub-Saharan African nations, is rapidly urbanizing [19]. With a growing urban population, rising trauma burden due to road traffic injuries, and centralization of surgical care at central hospitals, there will be a growing demand on urban central hospitals to provide essential operative musculoskeletal trauma care. At the time of survey completion, central hospitals in Malawi lacked essential capacity, most notably having insufficient infrastructure and manpower. Only one central hospital reported having beds available for newly admitted patients with musculoskeletal injuries, while the other three central hospitals reported that there were more patients than beds available. In contrast, 80% of district hospitals had beds available for musculoskeletal trauma patients. This apparent “excess” bed capacity is in line with earlier surveys of Malawian district hospitals [42]. However, inpatient ward nurses were in short supply throughout Malawi, and hospitals reported that ward nurses were inadequately trained to care for patients in skin or skeletal traction. Infrastructure development and advanced skills training must be prioritized to improve the trauma system.

As of November 2018, with the assistance of external donor funding, construction began on the Lilongwe Institute of Orthopaedics and Neurosurgery (LION), which should greatly expand operative infrastructure at Kamuzu Central Hospital, and for the country as a whole [43]. With developments of this kind, patients presenting to district hospitals with injuries needing surgery could be transferred to a central hospital with a “short stay trauma service” for treatment, then returned to the district hospitals for surgical aftercare and rehabilitation, allowing faster scale up of services and better utilization of capacity at the district level. However, our study demonstrates that health system strengthening must occur simultaneously in the district and central hospitals, with interventions appropriate to the level of service delivery. We found that ambulances were widely available for patient transfer between the district and central hospitals. However, essential resources for aftercare and rehabilitation of femoral fracture patients were notably deficient in district hospitals. A rehabilitation and physical therapy space was available in only 40% of districts, most reporting insufficient stock of necessary equipment and/or an inadequate amount of dedicated space. Walking assistive devices were available in only 33% of hospitals, with hospitals relying on donations from a local NGO or having patients commission their own from private carpenters. Pain medications were available in only 60% of district hospitals. Gauze and bandages were available in only 40% of district hospitals, 80% of which reported a short supply.

With few specialist orthopaedic surgeons currently available in Malawi, centralization of operative capabilities remains critical to scale up surgical services, train further specialists, and serve the district hospitals more efficiently. However, the district hospitals will continue to play an important role in delivering trauma care for the majority rural population. Although operative treatment is the international gold standard for diaphyseal femoral fractures [44], non-operative treatment remains the standard of care in Malawi, and the only treatment available in district hospitals. There is an urgent need in the short term to improve the capacity to perform skeletal traction especially in district hospitals, otherwise the provision of a suboptimal treatment in the context of inadequate resources may result in catastrophic patient outcomes. In the intermediate term, centralized short stay trauma services can provide scaled up operative treatment also to the districts. Eventually, once enough trained specialists are available in central hospitals to sustainably run the clinical and training programs, operative capacity will need to be decentralized to the district hospitals as well, to meet the needs of a modernizing Malawi.

This study has several limitations. First, relying on a single individual at a hospital to provide an overview of adult femur fracture care may have provided a limited impression of a hospital’s capacity. This may be especially true at central hospitals, where larger teams of providers share responsibility in patient care. However, we found high inter-rater reliability between study participants and the study investigators during independent “spot-checks”, including at the central hospital. Second, as with many survey methodologies, there is potential for social desirability bias. Respondents may have felt pressured to either over-report capacity for fear of retaliation from their superiors, or under-report capacity under the assumption that the study investigators desired these kinds of responses. Respondents may have over-reported missing or unavailable items with the hope that this would expedite resource replenishment. All surveys were completed anonymously to protect participants’ identities, though the hospital where each respondent worked was recorded. The high reliability of survey respondents compared to the independent “spot checks” likely indicates that this bias played a minimal role in this study. Third, we used femoral shaft fracture as a representative injury to assess musculoskeletal trauma care capacity. As femur fractures in Malawi are generally admitted from the outpatient or A&E department to the inpatient ward, and then treated either non-operatively or operatively, we felt focusing on this injury allowed for assessment of resources throughout the orthopaedic departments and for all phases of care. While an injury like ankle fracture may better elucidate resource limitations for fractures that are routinely treated in the outpatient setting, our methodology still allowed for assessment of x-ray, plaster of Paris, pain medication, walking assistive devices, and gauze and bandages, all of which are broadly relevant. Fourth, we collected data during a three-week period in the dry season. Fluctuations in disease burden in Malawi have been reported [45], and may be associated with seasonal variations in resource availability. Though the reason remains unclear, fewer patients with acute fractures present to orthopaedic clinics during the dry season [46]. We may have therefore overestimated capacity, compared to during the rainy season when higher trauma burden may result in greater resource utilization. A repeat assessment of trauma capacity is warranted in the rainy season, and continuous monitoring of resource availability should be a goal for the future, to allow for better supply chain management and real-time adaptation to the country’s needs.

Using femoral shaft fracture as a representative injury, we have evaluated the musculoskeletal trauma care capacity of every district and central hospital in Malawi, and found significant deficiencies in infrastructure, manpower, and material resources. Our findings provide evidence to help guide the development of the musculoskeletal trauma system in Malawi to meet the needs of a growing population with an increasing burden of injuries. Evidence-based policy planning could take into consideration the unavailability of essential resources, as well as the specific reasons for unavailability, which we have gathered from each hospital in this study. The cost and feasibility of addressing each specific item’s availability should be examined in future studies. Strategic planning for trauma and orthopaedic system development in Malawi should take into consideration the role of centralizing and decentralizing certain capabilities, and preparing the system to adapt to future challenges.

Supporting information

S1 File. Supplemental appendix.

Includes additional study context regarding musculoskeletal trauma care and femoral shaft fractures in Malawi, and the capacity assessment survey tool.

https://doi.org/10.1371/journal.pone.0225254.s001

(DOCX)

S1 Table. List of government district and central hospitals in Malawi.

https://doi.org/10.1371/journal.pone.0225254.s002

(DOCX)

Acknowledgments

We would like to thank all the orthopaedic clinical officers and orthopaedic surgeons who completed our burden assessment. We also thank the orthopaedic departments and hospital directors at all district and central hospitals in Malawi for their transparency and assistance, especially during the independent assessments of burden and capacity. Special thanks to all our patients in Malawi.

Investigation performed at The Orthopaedic and Arthritis Center for Outcomes Research, Department of Orthopedic Surgery, Brigham and Women’s Hospital and the Department of Orthopedics, Kamuzu Central Hospital, Lilongwe, Malawi.

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Figures

Abstract

Background

Methods

Results

Conclusion

Introduction

Methods

Capacity survey tool

Definition of essential resources

Capacity survey administration

Data analysis

Results

Capacity survey completion and reliability

Essential resources

Essential resource availability in district hospitals

Essential resource availability in central hospitals

Discussion

Supporting information

S1 File. Supplemental appendix.

S1 Table. List of government district and central hospitals in Malawi.

Acknowledgments

References