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Biomechanics

Extent of Vascular Damage at Varying Degrees of Stretch of Hypoxic Neonatal Brachial Plexus

(D-155) Extent of Vascular Damage at Varying Degrees of Stretch of Hypoxic Neonatal Brachial Plexus

Friday, October 13, 2023

3:30 PM – 4:30 PM PDT

Location: Exhibit Hall - Row D - Poster # 155

Presenting Author(s)

SS

Sanjna Srinivasan (she/her/hers)

Undergraduate Student
Drexel University, United States

Co-Author(s)

VO

Virginia Orozco, MS (she/her/hers)

PhD Candidate
Drexel University
Lansdowne, Pennsylvania, United States
MG

Megan Gorleski

PhD Student
Temple University, United States
SN

Smriti Nair

Undergraduate Student
Temple University, United States
MS

Mitali Sahni

Attending Neonatologist, MD
Pediatrix Medical Group, Sunrise Children's Hospital, Las Vegas, United States
SB

Sriram Balasubramanian

Associate Professor
Drexel University, United States

Primary Investigator(s)

AS

Anita Singh

Associate Professor
Temple University, United States

Introduction:: Neonatal brachial plexus palsy (NBPP) is defined as an injury to brachial plexus (BP) nerves due to over-stretching during complex birthing scenarios. Despite advancements in obstetric care, NBPP has an incidence of 1-4 cases per 1000 live births [1, 2]. Neonatal hypoxia can also occur as a result of obstetric complications, such as disrupted blood supply to the fetus due to umbilical cord compression, and can significantly impact the tissues and other organ functions [3]. Characterizing the extent of vascular damage of hypoxic neonatal BP at varying degrees of stretch can further the understanding of the injury thresholds of NBPP.

Materials and Methods:: All procedures were approved by Institutional Animal Care and Use Committee. Eight neonatal piglets (3-5 days old) were anesthetized and exposed to FiO2 of 7% for 1 hour to induce hypoxia and re-perfused to FiO2 of 21%. Using an axillary approach the BP was exposed and BP nerves were stretched at a rate of 500 mm/min to predetermined low- (< 15%) and high- ( >15%) strains. Post-stretch, BP nerves were harvested and OCT-embedded. Ten-µm-thick serial longitudinal sections were stained with Hematoxylin-Eosin (H&E). Using the Olympus BX53 motorized microscope, stained slides were imaged at 10x magnification along the nerve length. Each stitched image was split along its nerve length into regions of interest (ROIs) using a custom MATLAB script. An independent-blinded observer scored each ROI for vascular damage on a scale of 0-2 (0-no damage, 1-torn vessel, 2-scattered blood cells, Fig. 1).

Results, Conclusions, and Discussions::

Based on our modified scoring system, preliminary results show that vascular damage increased with increasing stretch injury (Fig. 2A), and similar degrees of damage was observed in the central and peripheral regions of the nerve (Fig. 2 B). This ongoing study is the first to characterize vascular damage of hypoxic neonatal BP nerves with respect to varying degrees of stretch. Determining the depth of vascular damage of the BP by analyzing the three regions presented in conjunction with the overall vascular damage will provide a more detailed characterization of the injury. Due to the anatomical similarities between neonatal piglets and neonatal human BP, this study will help further the understanding of injury thresholds of NBPP.

Acknowledgements (Optional): : This project was funded by the Eunice Kennedy Shriver National Institute of Child Health and Human Development of the National Institutes of Health R15HD093024; R01HD104910-01A1 and NSF CAREER grant Award #1752513.

References (Optional): :

[1] Abzug, J.M. Orthopedics 33: 430-435 (2010). [2] Johnson, E.O. Injury 44(3), 293-298 (2013). [3] Piešová, M, Mach, M. Impact of perinatal hypoxia on the developing brain. (2020)