Abstract
Background: This study investigates the damage in human tissue in regions subjected
to stress when the human body experiences localized, instantaneous impact loads.
Methods: Utilizing 727 images spanning from the shoulder to the fingertip of a digital human
model based on Chinese demographics, the geometric details of tissue structures were derived
via tissue segmentation, 3D modeling, and reverse engineering. A stress-induced damage model
for the human forearm was created using the finite element simulation software, commercial
software COMSOL Multiphysics 5.5 in the college edition. By applying an impact load of
6.4×106 N m2 to the load surface, a response time of 1×10−3 s was determined. Subsequently,
the force transmission mechanism was examined when the human forearm was under stress.
This approach represents the unique aspect of our patent study.
Results: The modeling and analysis revealed that skin, fat, and muscle -being viscoelastic tissues
-undergo deformation upon experiencing stress impacts. This deformation aids in dissipating energy.
In transient states, the body does not sustain severe damage, and the impact-induced damage
to these tissues is relatively minimal. However, if the force duration is prolonged or if the
impact load is exceedingly high, exceeding the critical limit of adhesive tissue may result in penetration
of the tissue at the stress point. Notably, tissues beyond the direct impact area remain
largely unharmed.
Conclusion: Damage due to localized, instantaneous impact loads is primarily concentrated on
the immediate stress surface, while regions beyond this point incur minimal to no damage. Calculations
indicate that, while such impacts can cause penetrating injuries, the resulting wounds
are typically small. With prompt medical intervention, these injuries are not debilitating to the
human body.
[5]
Qidwai SA, Khattak ZK, Malik M. Management of gunshot injuries to the limbs. saudi med J 1999; 20(8): 587-93.
[6]
Ahmed B, Voyiadjis GZ, Park T. Local and non-local damage model with extended stress decomposition for concrete. Int J damag mech 2021; 30(8): 1149-91.
[7]
Chen X. Automatic hard object spring back operation puncturing suction device, has spring fixed between rotating ring and fixed cylinder, and inclined plane opening whose surface is provided with trigger button that is connected with inner wall of suction tube. CN209951338, 2023.
[8]
Alexander DG. Numericalmodeling for the prediction of primary blast injury to the lungM S thesis Canada: University of Waterloo 2006.
[12]
Xing YP. Identification and simulation of stress injury of male tibia in jumping. Computer Simulation 2017; 34(2): 274-277+288.
[13]
SONG S. High-frequency ultrasonography and MRI observation of tibial stress injury in recruits. Chin J Med Imaging Technol 2009; 25(5): 863-5.
[14]
LIU HR. LUO SP, WAN YD. Magnetic resonance imaging of ankle sports injuries. Int J Med Radiol 2017; 40(4): 414-8.
[17]
Shuang ZHANG, et al. Modeling and analysis of electrical signal transduction mechanism in electroacupuncture-based electrochemotherapy of intramuscular hemangioma. Chinese J Med Phys 2022; 39(9): 1145-50.
[18]
Jining YANG, et al. Modeling and analysis of electrical signal transduction mechanism of electronic analgesic apparatus. Chinese J Med Phys 2022; 39(6): 752-7.
[19]
Cui Y, Wang X, Zhang H, et al. Research on characteristics of human pelvic and lumbar injuries based on generalized half-sine wave exci-tation. J Nanjing Univ Sci Tech 2022; 46(05): 544-52.
[20]
Ming L, Zhou Y, Zhang J, et al. Research on time interval of explosion impact on pelvis and lumbar spine injury. Explosion and Shock Waves 2021; 41(1): 138-49.
[21]
Zhen LEI, Yonghui HUANG, Wenmeng CHEN, Zhiyu ZHANG, Jiguo ZHOU. A study on the variation of cavity volume and energy dissipation with resistance line under blast impact load. J Vibt Sho 2021; 40(04): 66-71.
[25]
Eppinger RH, Marcus JH, Morgan MM. Development of dummy and injury index for NHSTA's thoracc side impact protectlon research program. Proceedines of the 28th Stapp Car Crash Conference,. 1984,SAE paper 840885.
[35]
Liu Y. Car rear-end and front end collision protection device, has instantaneous buffer for absorbing impact force of vehicle collision, and interference level protection front and rear bumper assembly for driving fixed rotating shaft. CN105882576, 2016.
[36]
Pei P, Liu A, Li Y, Huang S. Protective device for absorbing collapse landslide impact super-large opening diameter pipeline instantaneous impact energy, has pipeline main body located on outer protective buffer component sleeved with protective layer. CN115789398, 2023.