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1. Investigating the effect of anatomical variations in the response of the neonatal brachial plexus to applied force: Use of a two-dimensional finite element model

   https://doi.org/10.1371/journal.pone.0303511  

   Wright, Sarah J; Grimm, Michele J (May 2024, PLOS ONE)

   Chaudhary, Priti (Ed.)

   The brachial plexus is a set of nerves that innervate the upper extremity and may become injured during the birthing process through an injury known as Neonatal Brachial Plexus Palsy. Studying the mechanisms of these injuries on infant cadavers is challenging due to the justifiable sensitivity surrounding testing. Thus, these specimens are generally unavailable to be used to investigate variations in brachial plexus injury mechanisms. Finite Element Models are an alternative way to investigate the response of the neonatal brachial plexus to loading. Finite Element Models allow a virtual representation of the neonatal brachial plexus to be developed and analyzed with dimensions and mechanical properties determined from experimental studies. Using ABAQUS software, a two-dimensional brachial plexus model was created to analyze how stresses and strains develop within the brachial plexus. The main objectives of this study were (1) to develop a model of the brachial plexus and validate it against previous literature, and (2) to analyze the effect of stress on the nerve roots based on variations in the angles between the nerve roots and the spinal cord. The predicted stress for C5 and C6 was calculated as 0.246 MPa and 0.250 MPa, respectively. C5 and C6 nerve roots experience the highest stress and the largest displacement in comparison to the lower nerve roots, which correlates with clinical patterns of injury. Even small (+/- 3 and 6 degrees) variations in nerve root angle significantly impacted the stress at the proximal nerve root. This model is the first step towards developing a complete three-dimensional model of the neonatal brachial plexus to provide the opportunity to more accurately assess the effect of the birth process on the stretch within the brachial plexus and the impact of biological variations in structure and properties on the risk of Neonatal Brachial Plexus Palsy. 

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2. Effects of Prestretch on Neonatal Peripheral Nerve: An In Vitro Study

   https://doi.org/10.1055/s-0042-1743132  

   Singh, Anita; Majmudar, Tanmay; Magee, Rachel; Gonik, Bernard; Balasubramanian, Sriram (January 2022, Journal of Brachial Plexus and Peripheral Nerve Injury)

   Abstract Background Characterizing the biomechanical failure responses of neonatal peripheral nerves is critical in understanding stretch-related peripheral nerve injury mechanisms in neonates. Objective This in vitro study investigated the effects of prestretch magnitude and duration on the biomechanical failure behavior of neonatal piglet brachial plexus (BP) and tibial nerves. Methods BP and tibial nerves from 32 neonatal piglets were harvested and prestretched to 0, 10, or 20% strain for 90 or 300 seconds. These prestretched samples were then subjected to tensile loading until failure. Failure stress and strain were calculated from the obtained load-displacement data. Results Prestretch magnitude significantly affected failure stress but not the failure strain. BP nerves prestretched to 10 or 20% strain, exhibiting significantly lower failure stress than those prestretched to 0% strain for both prestretch durations (90 and 300 seconds). Likewise, tibial nerves prestretched to 10 or 20% strain for 300 seconds, exhibiting significantly lower failure stress than the 0% prestretch group. An effect of prestretch duration on failure stress was also observed in the BP nerves when subjected to 20% prestretch strain such that the failure stress was significantly lower for 300 seconds group than 90 seconds group. No significant differences in the failure strains were observed. When comparing BP and tibial nerve failure responses, significantly higher failure stress was reported in tibial nerve prestretched to 20% strain for 300 seconds than BP nerve. Conclusion These data suggest that neonatal peripheral nerves exhibit lower injury thresholds with increasing prestretch magnitude and duration while exhibiting regional differences. 

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3. An in vitro Study to Investigate Biomechanical Responses of Peripheral Nerves in Hypoxic Neonatal Piglets

   https://doi.org/10.1115/1.4051283  

   Singh, Anita; Magee, Rachel; Balasubramanian, Sriram (May 2021, Journal of Biomechanical Engineering)

   null (Ed.)

   Abstract Despite occurrence of neonatal hypoxia and peripheral nerve injuries in complicated birthing scenarios, the effect of hypoxia on the biomechanical responses of neonatal peripheral nerves is not studied. In this study, neonatal brachial plexus and tibial nerves, obtained from eight normal and eight hypoxic 3-5 days old piglets, were tested in uniaxial tension until failure at a rate of 0.01 mm/s or 10 mm/s. Failure load, stress, and modulus of elasticity were reported to be significantly lower in hypoxic neonatal brachial plexus (BP) and tibial nerves than respective normal tissue at both 0.01 and 10 mm/s rates. Failure strain was significantly lower in the hypoxic neonatal BP nerves only at 10 mm/s rate when compared to normal BP nerve. This is the first available data that indicates weaker mechanical behavior of hypoxic neonatal peripheral nerves as compared to normal tissue, and offers an understanding of the biomechanical responses of peripheral nerves of hypoxic neonatal piglets. 

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4. Available Computational and Physical Models to Understand the Mechanisms of Neonatal Brachial Plexus Injury During Shoulder Dystocia

   Singh, Anita (January 2019, Open access journal of neurology neurosurgery)

   Neonatal brachial plexus palsy is a devastating complication occurring during complicated birthing scenarios including shoulder dystocia. To understand the effects of maneuvers that reduce forces required for delivery following shoulder dystocia, tools that simulate the birthing scenarios are needed. Incorporation of brachial plexus responses is further required to help understand the mechanism of neonatal brachial plexus palsy and devise strategies that can help prevent them. Given the inability to measure forces and tissue strains during actual birthing process, computer and physical models serve as optimal tools with its known limitations. This mini-review highlights and summaries available computational and physical models that can help understand brachial plexus injury mechanisms in neonates following complicated delivery including shoulder dystocia. 

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5. Understanding Patterns of Neonatal Brachial Plexus Palsy Using a 3D Finite Element Model

   https://doi.org/10.5772/intechopen.1010022  

   J_Wright, Sarah; J_Grimm, Michele (May 2025, IntechOpen)

   Taiar, Redha (Ed.)

   Neonatal brachial plexus palsy is a birth process-related injury that affects 1–2/1000 infants, with about 10% of those having a permanent deficit that can affect the muscle strength, range of motion, and sensation of the upper extremity. While computational models make the most sense for investigation of injury mechanisms in the vulnerable infant population, the models remain very simplified – incorporating only a single indicator nerve that mimics the response of the C5 nerve root rather than taking into consideration the complex, 3D anatomy of the plexus. Two existing finite element models of the adult brachial plexus have been published – but neither attempts to model the complex anatomy of the plexus through the divisions, cords, and terminal nerves. This project involved the development of an anatomically appropriate 3D model of the infant brachial plexus. This is the first published finite element model of the full, complex anatomy of the brachial plexus and the first that includes an appropriate anatomy for an infant. The model was then used to better understand the pattern and progression of brachial plexus injury that has been observed clinically in neonates. The model was able to predict a stress distribution that aligns with the C5 nerve root being the location of initial injury. It also demonstrated how the stress in remaining, intact nerve roots will increase when rupture or avulsion of C5 and then C6 occurs – which matches the progression of the injury from the upper plexus (an Erb’s Palsy) to the middle and lower plexus. 

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