A realist review protocol on communications for community engagement in maternal and newborn health programmes in low- and middle-income countries.

BACKGROUND: Community engagement (CE) has been increasingly implemented across health interventions, including for maternal and newborn health (MNH). This may take various forms, from participatory women's groups and community health committees to public advocacy days. While research suggests a positive influence of CE on MNH outcomes, such as mortality or care-seeking behaviour, there is a need for further evidence on the processes of CE in different settings in order to inform the future development and implementation of CE across programmes. Communication is an integral component of CE serving as a link between the programme and community. The aim of the realist review described in this protocol is to understand how, why, to what extent, and for whom CE contributes to intended and unintended outcomes in MNH programming, focusing on the communication components of CE. METHODS: Realist review methodology will be used to provide a causal understanding of what communication for CE interventions in MNH programming work, for whom, to what extent, why, and how. This will be done by developing and refining programme theories on communications for CE in MNH through a systematic review of the literature and engaging key experts for input and feedback. By extrapolating context-mechanism-outcome configurations, this review seeks to understand how certain contexts trigger or inhibit specific mechanisms and what outcomes this interaction generates when communication in CE interventions is used in MNH programming. DISCUSSION: A realist philosophy is well-suited to address the aims of this study because of the complex nature of CE. The review findings will be used to inform a realist evaluation case study of CE for an MNH programme in order to ascertain transferable findings that can inform and guide engagement activities in various settings. Findings will also be shared with stakeholders and experts involved in the consultative processes of the review (through workshops or policy briefs) in order to ensure the relevance of these findings to policy and practice. SYSTEMATIC REVIEW REGISTRATION: PROSPERO CRD42022293564.

Community level workers: awareness generation for improving children's health.

BACKGROUND: Routine immunisation and Vitamin A supplementation are two of many services offered by Government of India to reduce child mortality and morbidity. The three groups of community level workers (CLWs) i.e. Auxiliary Nurse Midwives from health department, Anganwadi Workers from women and child development department and Accredited Social Health Activists (ASHAs) are responsible for raising awareness and demand for these services. OBJECTIVES: The paper assesses the knowledge and participation of CLWs in generating awareness about the two services namely immunisation and Vitamin A supplementation among eligible mothers; and mother's knowledge on these two services. METHODS: The study was conducted in 16 villages of two administrative blocks of Udaipur district in Rajasthan. Multistage purposive sampling was used for study area selection. Data collection was done using mixed methods-1) observations of 16 Maternal and Child Health and Nutrition days; 2) questionnaire based survey of 46 CLWs; and 3) questionnaire based survey of 321 programme beneficiaries i.e. infant's mothers. RESULTS: Limited knowledge of CLWs and their participation in awareness generation activities for the two services was noticed, which was also reflected in the poor knowledge among mothers on the two services. CONCLUSION: The study results may partially explain the poor child immunization in Rajasthan. Initiatives to increase CLWs' knowledge of child immunization and Vitamin A supplementation; and increasing their participation in awareness generation activities need serious consideration by the healthcare system to improve immunization coverage.

Parameters that effect spine biomechanics following cervical disc replacement.

Total disc replacement (TDR) is expected to provide a more physiologic alternative to fusion. However, long-term clinical data proving the efficacy of the implants is lacking. Limited clinical data suggest somewhat of a disagreement between the in vitro biomechanical studies and in vivo assessments. This conceptual paper presents the potential biomechanical challenges affecting the TDR that should be addressed with a hope to improve the clinical outcomes and our understanding of the devices. Appropriate literature and our own research findings comparing the biomechanics of different disc designs are presented to highlight the need for additional investigations. The biomechanical effects of various surgical procedures are analyzed, reiterating the importance of parameters like preserving uncinate processes, disc placement and its orientation within the cervical spine. Moreover, the need for a 360° dynamic system for disc recipients who may experience whiplash injuries is explored. Probabilistic studies as performed already in the lumbar spine may explore high risk combinations of different parameters and explain the differences between "standard" biomechanical investigations and clinical studies. Development of a patient specific optimized finite element model that takes muscle forces into consideration may help resolve the discrepancies between biomechanics of TDR and the clinical studies. Factors affecting long-term performance such as bone remodeling, subsidence, and wear are elaborated. In vivo assessment of segmental spine motion has been, and continues to be, a challenge. In general, clinical studies while reporting the data have placed lesser emphasis on kinematics following intervertebral disc replacements. Evaluation of in vivo kinematics following TDR to analyze the quality and quantity of motion using stereoradiogrammetric technique may be needed.

Models that incorporate spinal structures predict better wear performance of cervical artificial discs.

BACKGROUND CONTEXT: Wear simulators and their corresponding wear predictive models provide limited information on wear characteristics of artificial discs. Analyses in previous studies that controlled loading profiles according to International Standards Organization (ISO)/American Society for Testing and Materials standards did not account for factors such as the influence of anatomic structures. Retrieval analyses reveal failure modes that are not observed in benchtop simulations and thus indicate deficiencies associated with existing approaches. PURPOSE: To understand the impact of the adjoining spinal structures of a ligamentous segment on the wear of an artificial cervical disc. STUDY DESIGN: Prediction of wear in artificial disc implants (total disc replacement [TDR]) in situ using finite element modeling. METHODS: A novel predictive finite element model was used to evaluate wear in a simulated functional spinal unit (FSU). A predictive finite element wear model of the disc alone (TDR Only) was developed, along the lines of that proposed in the literature. This model was then incorporated into a ligamentous C5-C6 finite element model (TDR+FSU). Both of these models were subjected to a motion profile (rotation about three axes) with varying preloads of 50 to150 N at 1 Hz, consistent with ISO 18192. A subroutine based on Archard law simulated abrasive wear on the polymeric core up to 10 million cycles. The TDR+FSU model was further modified to simulate facetectomy, sequential addition of ligaments, and compressive load; simulations were repeated for 10 million cycles. RESULTS: The predicted wear patterns in the isolated disc (TDR Only) and in TDR+FSU were completely inconsistent. The TDR+FSU model predicted localized wear in certain regions, in contrast to the uniformly distributed wear pattern of the TDR-only model. In addition, the cumulative volumetric wear for the TDR-only model was 10 times that of the TDR+FSU model. The TDR+FSU model also revealed a separation at the articulating interface during extension and lateral bending. After facetectomy, the wear pattern remained lopsided, but linear wear increased eightfold, whereas volumetric wear almost tripled. This was accompanied by a reduction in observed liftoff. The addition of anterior longitudinal ligament/posterior longitudinal ligament did not affect volumetric or linear wear. On the removal of all ligaments and facet forces, and replacement of follower load with a compressive load, the wear pattern returned to an approximation of the TDR-only test case, whereas the cumulative volumetric wear became nearly equivalent. In this case, the liftoff phenomenon was absent. CONCLUSIONS: Anatomic structures and follower load mitigate the wear of an artificial disc. The proposed model (TDR+FSU) would enable further study of the effects of clinical parameters (eg, surgical variables, different loading profiles, different disc designs, and bone quality) on wear in these implants.

Kinematic motion patterns of the cranial and caudal canine cervical spine.

OBJECTIVE: To define the kinematic motion patterns of the canine cervical spine, with a particular emphasis on identifying differences between the cranial (C(2)-C(4)) and caudal (C(5)-C(7)) segments, and to determine the significance of coupled motions (CM) in the canine cervical spine. STUDY DESIGN: Cadaveric biomechanical study. SAMPLE POPULATION: Cervical spines of 8 Foxhounds. METHODS: Spinal specimens were considered free of pathology based on radiographic, computed tomography, and magnetic resonance imaging examinations. All musculature was removed without damaging ligaments or joint capsules. Spines were mounted in a customized pure-moment spine testing jig, and data were collected using an optoelectronic motion capture system. Range of motion, neutral zone and CM in flexion/extension, left/right lateral bending and left/right axial rotation were established. Data were analyzed using mixed-effects maximum likelihood regression models. RESULTS: Total flexion/extension did not change across the 4 levels. There was no difference between flexion and extension, and no CM was identified. Lateral bending was not different across levels, but tended to be greater in the cranial spine. Axial rotation was ∼2.6 times greater in the caudal segments. Lateral bending and axial rotation were coupled. CONCLUSIONS: Kinematics of the cranial and caudal cervical spine differed markedly with greater mobility in the caudal cervical spine.

Gravimetric wear analysis and particulate characterization of bilateral facet-augmentation system--PercuDyn™.

Dynamic stabilization systems are emerging as an alternative to fusion instrumentation. However, cyclic loading and micro-motion at various interfaces may produce wear debris leading to adverse tissue reactions such as osteolysis. Ten million cycles of wear test was performed for PercuDyn™ in axial rotation and the wear profile and the wear rate was mapped. A validation study was undertaken to assess the efficiency of wear debris collection which accounted for experimental errors. The mean wear debris measured at the end of 10 million cycles was 4.01 mg, based on the worst-case recovery rate of 68.2%. Approximately 40% of the particulates were less than 5 µm; 92% less than 10 µm. About 43% of particulates were spherical in shape, 27% particulates were ellipsoidal and the remaining particles were of irregular shapes. The PercuDyn™ exhibited an average polymeric wear rate of 0.4 mg/million cycles; substantially less than the literature derived studies for other motion preservation devices like the Bryan disc and Charité disc. Wear debris size and shape were also similar to these devices.

Surface slide track mapping of implants for total disc arthroplasty.

Total disc arthroplasty has recently become a potential alternative to spinal arthrodesis. Until recently, there has been no standardized method for evaluating the wear of an artificial disc and myriad testing conditions have been used. The American Society for Testing and Materials (ASTM) and International Organization of Standardization (ISO) recently published guidance documents for the wear assessment of intervertebral spinal disc prostheses; however, various kinematic profiles are suggested, leading to different wear paths between the articulating surfaces of the implants. Since the wear between materials is influenced by the type of relative motion, it is important to select test conditions that lead to clinically realistic results. The purpose of this study was to characterize the slide tracks generated by 7 test conditions allowed for by the ISO and ASTM guidance documents and in Euler sequences consistent with 4 commercially available spine wear simulators. The analysis was performed for a ball-in-socket articulation under both lumbar and cervical motion test conditions. Results were generated analytically using a mathematical algorithm and then validated experimentally. Four tests resulted in elliptical sliding tracks of similar geometries for both the lumbar and cervical conditions. Curvilinear and ribbon-shaped wear paths were generated for 3 tests. With the data normalized for implant diameter, the sliding distance was similar between the lumbar and cervical conditions allowed for in the ASTM guidance. This distance differed compared with the results for the ISO guidance document where the lengths of cervical slide tracks were twice those for the lumbar conditions. Slide tracks were also found to be insensitive to the type of simulator under all testing conditions.