Abstract
Bone can heal on its own through the process known as bone remodelling. Nonetheless, a critical size bone defect will hinder the natural bone-healing process and may not allow for complete fracture healing. These requires surgical intervention by employing the use of bone tissue implants and in need of realignment and fixation for proper fracture healing. Traditional knowledge of bone injury and fracture healing must be comprehended thoroughly for a proper invention of bioengineered material or devices that could enhance the physiological process. Heretofore, engineered materials used to address critical size bone defects have encountered various challenges and improvement be it in bone grafting or choices of mechanical stabilization devices. To date, researchers have been mainly focussing on the alternative material for bone graft substitute albeit the selection of fixators to establish mechanical stabilization are as important. This review highlighted the challenges, improvement and advancement in mechanical stabilization devices and bone graft substitute with respect to the physiological process of bone fracture healing. Identifying these challenges would help assist the researcher in an expedition toward the recovery and restoration of critical size bone defects.
Highlights
The bone is a crucial rigid human organ that has an orderly and complex structure to supports its diverse mechanical, biological and chemical functions
The application of biomedical engineering applies the interdisciplinary aspect of engineering and medical sciences contributed to the rapid advancement in providing a solution for bone fracture healing in critical size bone defects [3]
A study on osteoporotic comminuted radial diaphyseal fracture model revealed that the minimum contact locking plate (MC-LP) plating systems is significantly more stable than the limited contact dynamic compression plate (LC-DCP) system when tested in four-point bending and torsion
Summary
The bone is a crucial rigid human organ that has an orderly and complex structure to supports its diverse mechanical, biological and chemical functions. Current strategies for treatment of critical size bone defects include bone grafting and stabilization using internal metal plates. These strategies involve a slow healing with high infection risk and elicit considerable pain. The application of biomedical engineering applies the interdisciplinary aspect of engineering and medical sciences contributed to the rapid advancement in providing a solution for bone fracture healing in critical size bone defects [3]. In the past few decades, there were various breakthroughs in biomedical engineering to facilitate the process of critical sized bone fracture healing from a conventional autologous bone grafting to a more radical approaches using allograft and synthetic bone graft substitute [4,5]. MJoSHT 2020, Volume 6, Special Issue, eISSN: 2601-0003 highlighting the challenges, improvement and advancement in mechanical stabilisation devices and bone graft substitutes
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