Md Enamul Hoque

By Md. Enamul Hoque and Y. Leng Chuan

Part of the book: Rapid Prototyping Technology

By Shiplu Roy Chowdhury, Yogeswaran Lokanathan, Law Jia Xian, Fauzi Mh Busra, Muhammad Dain Yazid, Nadiah Sulaiman, Gargy Lahiry and Md Enamul Hoque

Tissue engineering techniques enable the fabrication of tissue substitutes integrating cells, biomaterials, and bioactive compounds to replace or repair damaged or diseased tissues. Despite the early success, current technology is unable to fabricate reproducible tissue-engineered constructs with the structural and functional similarity of the native tissue. The recent development of 3D printing technology empowers the opportunities of developing biofunctional complex tissue substitutes via layer-by-layer fabrication of cell(s), biomaterial(s), and bioactive compound(s) in precision. In this chapter, the current development of fabricating tissue-engineered constructs using 3D bioprinting technology for potential biomedical applications such as tissue replacement therapy, personalized therapy, and in vitro 3D modeling for drug discovery will be discussed. The current challenges, limitations, and role of stakeholders to grasp the future success also will be highlighted.

Part of the book: Design and Manufacturing

By Md Enamul Hoque, Md Sakif Zawad and Nur Md Atiquzzaman Rasel

Amputation of the lower limb is a life-changing experience, affecting a person’s walking, lifestyle, and daily routine activities. Although prosthetic limbs are made to replace the missing movement, they cannot mimic the natural walking mechanics. This usually causes discomfort, lack of balance, and additional energy consumption that makes performing even simple activities even more tiring. This chapter provides a focused literature review of existing challenges and the rising technologies in advanced lower-limb prosthetic development with a particular emphasis on biomechanics, smart control systems, and material innovation. Such technologies as microprocessor-controlled knees and energy-storing feet are being found effective in enhancing walking economy and addressing gait pathologies, yet usually with high costs and additional requirements of upkeep, therefore being less accessible. The custom contours of their 3D-printed sockets are simpler to produce, but are less achievable due to the constrained materials and associated limitations. A promising area is AI-supported feedback systems that can real-time adjust the alignment of the prosthetic and provide a more natural walking experience; however, the technology is currently limited by its cost and regulatory issues. In spite of this, the future of prosthetics is bright. The new technologies are making the prosthetics smarter, adaptive, and in the end, more comfortable. Future prosthetic design will aim to strike a balance between functionality, comfort, and cost, with energy-efficient feet and microprocessor-controlled joints being the most promising technologies to make people more mobile and less fatigued.

Part of the book: Rehabilitation Engineering