Abstract
Knowing the material properties of the musculoskeletal soft tissue could be important to develop rehabilitation therapy and surgical procedures. However, there is a lack of devices and information on the viscoelastic properties of soft tissues around the lumbar spine. The goal of this study was to develop a portable quantifying device for providing strain and stress curves of muscles and ligaments around the lumbar spine at various stretching speeds. Each sample was conditioned and applied for 20 repeatable cyclic 5 mm stretch-and-relax trials in the direction and perpendicular direction of the fiber at 2, 3 and 5 mm/s. Our device successfully provided the stress and strain curve of the samples and our results showed that there were significant effects of speed on the young’s modulus of the samples (p < 0.05). Compared to the expensive commercial device, our lower-cost device provided comparable stress and strain curves of the sample. Based on our device and findings, various sizes of samples can be measured and viscoelastic properties of the soft tissues can be obtained. Our portable device and approach can help to investigate young’s modulus of musculoskeletal soft tissues conveniently, and can be a basis for developing a material testing device in a surgical room or various lab environments.
Highlights
The human musculoskeletal soft tissue has viscoelastic properties showing time and history-dependent behaviors [1,2]
Due to recent advances in medical technology, image-guided surgeries are widely performed by using computerized-tomography (CT), magnetic resonance imaging (MRI), fluoroscopic, or X-ray images [3]
quantifying device (QD) was able to control the speeds of the motor so that the specimen can move
Summary
The human musculoskeletal soft tissue has viscoelastic properties showing time and history-dependent behaviors [1,2]. Knowing the material properties of the musculoskeletal soft tissue could be important to develop rehabilitation therapy and surgical procedures. Due to recent advances in medical technology, image-guided surgeries are widely performed by using computerized-tomography (CT), magnetic resonance imaging (MRI), fluoroscopic, or X-ray images [3]. During the image-guided surgery, over-incision, and a large amount of X-ray exposure can cause significant side effects to patients. Thereby, advanced image registration technologies are needed to minimize incision sizes and reduce amounts of X-ray exposure, especially for spine surgery [9]
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