Yoganandan Narayan, Shah Alok, Koser Jared, Somberg Lewis, Stemper Brian D, Chancey Valeta Carol, McEntire Joseph Barney
Department of Neurosurgery, Medical College of Wisconsin, Milwaukee, WI 53226, USA.
Department of Surgery, Medical College of Wisconsin, Milwaukee, WI 53226, USA.
Mil Med. 2024 Nov 5;189(11-12):e2462-e2467. doi: 10.1093/milmed/usae297.
Warfighters are issued hard body armor designed to defeat ballistic projectiles. The resulting backface deformation can injure different thoracoabdominal organs. Developed over decades ago, the behind armor blunt impact criterion of maximum 44 mm depth in clay continues to be used independent of armor type or impact location on the thoracoabdominal region covered by the armor. Because thoracoabdominal components have different energy absorption capabilities, their mode of failures and mechanical properties are different. These considerations underscore the lack of effectiveness of using the single standard to cover all thoracoabdominal components to represent the same level of injury risk. The objective of this pilot study is to conduct cardiac impact tests with a live animal model and analyze biomechanical injury candidate metrics for behind armor blunt trauma applications.
Live swine tests were conducted after obtaining approvals from the U.S. DoD. Trachea tubes. An intravenous line were introduced into the swine before administering anesthesia. Pressure transducers were inserted into lungs and aorta. An indenter simulating backface deformation profiles produced by body armor from military-relevant ballistics to human cadavers delivered impact to the heart region. The approved test protocol included 6-hour monitoring and necropsies. Indenter accelerometer signals were processed to compute the velocity and deflection, and their peak magnitudes were obtained. The deflection-time signal was normalized with respect to chest depth along the impact axis. The peak magnitude of the viscous criterion, kinetic energy, force, momentum and stiffness were obtained.
Out of the 8 specimens, 2 were sham controls. The mean total body mass and soft tissue thickness at the impact site were 81.1 ± 4.1 kg and 3.8 ± 1.1 cm. The peak velocities ranged from 30 to 59 m/s, normalized deflections ranged from 15 to 21%, and energies ranged from 105 to 407 J. The range in momentum and stiffness were 7.0 to 13.9 kg-m/s and 22.3 to 79.9 N/m. The maximum forces and impulse data ranged from 2.9 to 11.7 kN and 1.9 to 5.8 N-s. The peak viscous criterion ranged from 2.0 to 5.3 m/s. One animal did not sustain any injuries, 2 had cardiac injuries, and others had lung and skeletal injuries.
The present study applied blunt impact loads to the live swine cardiac region and determined potential candidate injury metrics for characterization. The sample size of 6 swine produced injuries ranging from none to pure skeletal to pure organ trauma. The viscous criterion metric associated with the response of the animal demonstrated a differing pattern than other variables with increasing velocity. These findings demonstrate that our live animal experimental design can be effectively used with testing additional samples to develop behind armor blunt injury criteria for cardiac trauma in the form of risk curves. Injury criteria obtained for cardiac trauma can be used to enhance the effectiveness of the body armor, reduce morbidity and mortality, and improve warfighter readiness in combat operations.
作战人员配备有旨在抵御弹道射弹的硬质防弹衣。由此产生的背向变形可能会损伤不同的胸腹器官。早在几十年前就已制定的防弹衣后钝击标准,即黏土中最大深度为44毫米,无论防弹衣类型或其覆盖的胸腹区域的撞击位置如何,该标准仍在使用。由于胸腹部位的组成部分具有不同的能量吸收能力,它们的失效模式和力学性能也各不相同。这些因素凸显了使用单一标准来涵盖所有胸腹部位以代表相同损伤风险水平的做法缺乏有效性。这项初步研究的目的是使用活体动物模型进行心脏撞击测试,并分析防弹衣后钝击创伤应用中的生物力学损伤候选指标。
在美国国防部批准后进行了活体猪测试。在给猪麻醉前,插入气管导管和静脉输液管。将压力传感器插入肺部和主动脉。一个模拟防弹衣从军事相关弹道到人体尸体产生的背向变形轮廓的压头,对心脏区域进行撞击。批准的测试方案包括6小时监测和尸检。对压头加速度计信号进行处理以计算速度和挠度,并获取其峰值大小。挠度 - 时间信号相对于沿撞击轴的胸部深度进行归一化。获取了粘性准则、动能、力、动量和刚度的峰值大小。
8个样本中,2个为假手术对照。撞击部位的平均总体重和软组织厚度分别为81.1 ± 4.1千克和3.8 ± 1.1厘米。峰值速度范围为30至59米/秒,归一化挠度范围为15%至21%,能量范围为1,05至407焦耳。动量和刚度范围分别为7.0至13.9千克·米/秒和22.3至79.9牛/米。最大力和冲量数据范围分别为2.9至11.7千牛和1.9至5.8牛·秒。峰值粘性准则范围为2.0至5.3米/秒。1只动物未受任何损伤,2只出现心脏损伤,其他动物有肺部和骨骼损伤。
本研究对活体猪心脏区域施加钝击载荷,并确定了用于表征的潜在候选损伤指标。6只猪的样本量产生了从无损伤到单纯骨骼损伤再到单纯器官损伤的不同损伤情况。与动物反应相关的粘性准则指标与其他变量随速度增加呈现出不同的模式。这些发现表明,我们的活体动物实验设计可有效地用于测试更多样本,以制定风险曲线形式的防弹衣后心脏钝击损伤标准。获得的心脏创伤损伤标准可用于提高防弹衣的有效性,降低发病率和死亡率,并提高作战人员在战斗行动中的准备状态。
