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"Nanophotonics has emerged rapidly into technological mainstream with the advent and maturity of nanotechnology available in photonics and enabled many new exciting applications in the area of biomedical science and engineering that were unimagined even a few years ago with conventional photonic engineering techniques. Handbook of Nanophotonics in Biomedical Engineering is intended to be a reliable resource to a wealth of information on nanophotonics that can inspire readers by detailing emerging and established possibilities of nanophotonics in biomedical science and engineering applications. This comprehensive reference presents not only the basics of nanophotonics but also explores recent experimental and clinical methods used in biomedical and bioengineering research. Each peer-reviewed chapter of this book discusses fundamental aspects and materials/fabrication issues of nanophotonics, as well as applications in interfaces, cell, tissue, animal studies, and clinical engineering. The organization provides quick access to current issues and trends of nanophotonic applications in biomedical engineering. All students and professionals in applied sciences, materials, biomedical engineering, and medical and healthcare industry will find this essential reference book highly useful."

"This book presents a thorough discussion of the physics, biology, chemistry and medicinal science behind a new and important area of materials science and engineering: polymer nanocomposites. The tremendous opportunities of polymer nanocomposites in the biomedical field arise from their multitude of applications and their ability to satisfy the vastly different functional requirements for each of these applications. In the biomedical field, a polymer nanocomposite system must meet certain design and functional criteria, including biocompatibility, biodegradability, mechanical properties, and, in some cases, aesthetic demands. "

"Summary: The definitive "bible" for the field of biomedical engineering, this collection of volumes is a major reference for all practicing biomedical engineers and students. Now in its fourth edition, this work presents a substantial revision, with all sections updated to offer the latest research findings. New sections address drugs and devices, personalized medicine, and stem cell engineering. Also included is a historical overview as well as a special section on medical ethics. This set provides complete coverage of biomedical engineering fundamentals, medical devices and systems, computer applications in medicine, and molecular engineering"

"Biomedical foams are a new class of materials, which are increasingly being used for tissue engineering applications. Biomedical Foams for Tissue Engineering Applications provides a comprehensive review of this new class of materials, whose structure can be engineered to meet the requirements of nutrient trafficking and cell and tissue invasion, and to tune the degradation rate and mechanical stability on the specific tissue to be repaired.Part one explores the fundamentals, properties, and modification of biomedical foams, including the optimal design and manufacture of biomedical foam pore structure for tissue engineering applications, biodegradable biomedical foam scaffolds, tailoring the pore structure of foam scaffolds for nerve regeneration, and tailoring properties of polymeric biomedical foams. Chapters in part two focus on tissue engineering applications of biomedical foams, including the use of bioactive glass foams for tissue engineering applications, bioactive glass and glass-ceramic foam scaffolds for bone tissue restoration, composite biomedical foams for engineering bone tissue, injectable biomedical foams for bone regeneration, polylactic acid (PLA) biomedical foams for tissue engineering, porous hydrogel biomedical foam scaffolds for tissue repair, and titanium biomedical foams for osseointegration."

"Teknik biomedik telah menjadi komponen penting dalam pengembangan teknologi kesehatan di Indonesia selama dua dekade terakhir. Program sarjana yang dibuka oleh beberapa universitas diharapkan menjadi titik temu antara fakultas teknik dan rumpun ilmu kesehatan (RIK), serta menjadi solusi untuk tantangan teknologi biomedik. Meski demikian, pemahaman tentang peran teknik biomedik dalam konteks kebijakan kesehatan Indonesia dan implementasinya di fasilitas kesehatan masih perlu ditingkatkan. Penelitian ini bertujuan untuk memahami signifikansi peran profesi teknik biomedik dalam penyusunan kebijakan kesehatan Indonesia dan implementasinya di fasilitas kesehatan.. Metode analisis kebijakan Grindle yang digunakan dalam penelitian sebagai pengamatan mendalam terhadap keterikatan peran teknik biomedik dalam kebijakan kesehatan Indonesia berbasis wawancara dengan ahli terkait di bidang teknologi kesehatan, kebijakan kesehatan, dan di bidang teknik biomedik. Melalui penelitian ini, ditemukan permasalahan utama pada perkembangan profesi teknik biomedik berada pada kelemahan legalitas akibat dari ketiadaan asosiasi dan wadah aspirasi yang jelas. Ditemukan pula penguatan regulasi untuk mendorong alokasi tenaga kerja dari teknik biomedik dapat menjadi evaluasi kebijakan yang selama ini telah berjalan. Diharapkan, penelitian ini menjadi awal dari diskusi lebih lanjut dalam kontribusi produktif teknik biomedik dalam peningkatan industri kesehatan Indonesia.

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Biomedical engineering has become an important component in the development of health technology in Indonesia over the past two decades. The undergraduate programs established by several universities are expected to become a meeting point between engineering faculties and the health sciences cluster (RIK), as well as providing solutions to the challenges of biomedical technology. However, the understanding of the role of biomedical engineering in the context of Indonesian health policy and its implementation in health facilities still needs to be improved. This research aims to understand the significance of the role of the biomedical engineering profession in the formulation of Indonesian health policies and their implementation in health facilities. The Grindle policy analysis method used in this research allows for in-depth observation of the integration of the role of biomedical engineering in Indonesian health policy, based on interviews with experts in health technology, health policy, and biomedical engineering. This study found that the main problem in the development of the biomedical engineering profession lies in the lack of legal standing due to the absence of clear associations and advocacy platforms. Furthermore, strengthening regulations to encourage the allocation of biomedical engineering personnel can serve as an evaluation of existing policies. It is hoped that this research will initiate further discussions on the productive contributions of biomedical engineering in enhancing the Indonesian health industry."