Статті в журналах: "Medical and biomedical engineering"

1

Tooley, Mark A. "Medical Physics and Biomedical Engineering." Physiological Measurement 21, no. 4 (November 1, 2000): 549. http://dx.doi.org/10.1088/0967-3334/21/4/701.

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2

Wells, P. N. T. "Medical Physics and Biomedical Engineering." Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine 215, no. 2 (February 1, 2001): 265. http://dx.doi.org/10.1243/0954411011533670.

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3

Berry, Michael T., and William R. Hendee. "Medical Physics and Biomedical Engineering." Medicine & Science in Sports & Exercise 32, no. 2 (February 2000): 547. http://dx.doi.org/10.1097/00005768-200002000-00047.

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4

Brown, B. H., R. H. Smallwood, D. C. Barber, P. V. Lawford, D. R. Hose, and E. Russell Ritenour. "Medical Physics and Biomedical Engineering." Medical Physics 28, no. 5 (May 2001): 861. http://dx.doi.org/10.1118/1.1369117.

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5

Staton, Daniel J. "Medical Physics and Biomedical Engineering,." Health Physics 78, no. 6 (June 2000): 755–56. http://dx.doi.org/10.1097/00004032-200006000-00025.

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6

Hose, B. H. Brown, R. H. Smallwood, D. C. Barbe. "Medical Physics and Biomedical Engineering." Measurement Science and Technology 12, no. 10 (September 12, 2001): 1744. http://dx.doi.org/10.1088/0957-0233/12/10/703.

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7

Brown, B. H., R. H. Smallwood, D. C. Barber, P. V. Lawford, D. R. Rose, and Douglas R. Shearer. "Medical Physics and Biomedical Engineering." Medical Physics 26, no. 12 (December 1999): 2710–11. http://dx.doi.org/10.1118/1.598826.

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8

Wigertz, O., J. Persson, and H. Ahlfeldt. "Teaching Medical Informatics to Biomedical Engineering Students: Experiences over 15 Years." Methods of Information in Medicine 28, no. 04 (October 1989): 309–12. http://dx.doi.org/10.1055/s-0038-1636807.

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Abstract:The Departments of Biomedical Engineering and Medical Informatics at Linkoping University in Sweden were established in 1972-1973. The main purpose was to develop and offer courses in medicine, biomedical engineering and medical informatics to students in electrical engineering and computer science, for a specialization in biomedical engineering and medical informatics. The courses total about 400 hours of scheduled study in the subjects of basic cell biology, basic medicine (terminology, anatomy, physiology), biomedical engineering and medical informatics. Laboratory applications of medical computing are mainly taught in biomedical engineering courses, whereas clinical information systems, knowledge based decision support and computer science aspects are included within the medical informatics courses.

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9

Istanbullu, Ayhan, and İnan Güler. "Multimedia Based Medical Instrumentation Course in Biomedical Engineering." Journal of Medical Systems 28, no. 5 (October 2004): 447–54. http://dx.doi.org/10.1023/b:joms.0000041171.10412.0b.

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10

Miyamoto, Hiroyuki, and Yasuhisa Sakurai. "Institute of Biomedical Engineering, Tokyo Women's Medical College." Advanced Robotics 1, no. 4 (January 1986): 401–4. http://dx.doi.org/10.1163/156855386x00265.

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11

WORRELL, PAT F. "FOCUS on: Multicare Medical Center Biomedical Engineering Department." Journal of Clinical Engineering 11, no. 4 (July 1986): 279–84. http://dx.doi.org/10.1097/00004669-198607000-00004.

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12

Dabadi, Sambardhan, and Raju Raj Dhungel. "Biomedical Engineering in Nepal: Opportunities and Challenges." Annapurna Journal of Health Sciences 1, no. 1 (February 10, 2021): 52–54. http://dx.doi.org/10.52910/ajhs.18.

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Biomedical engineering is the blend of engineering and medical science, professional with a combination of knowledge of various engineering discipline to improve health care and quality of life. While biomedical engineering formally came up as major course in 1950s, the course started in Nepal just a decade back with its importance being acknowledged and biomedical engineers have been recruited by various institutes. Accounting for artificial intelligence, robotic surgery, 3-d printing, which are believed to be the future of medical science, it is necessary to strengthen the biomedical engineering. This article aims to highlight the overview as well as opportunities and challenges of biomedical engineering in Nepal.

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13

Meldrum, Stuart J. "Introduction to Biomedical Engineering." Physiological Measurement 21, no. 2 (May 1, 2000): 341. http://dx.doi.org/10.1088/0967-3334/21/2/701.

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14

Moumaris, Mohamed, Jean-Michel Bretagne, and Nisen Abuaf. "Hospital Engineering of Medical Devices in France." Open Medical Devices Journal 6, no. 1 (August 31, 2018): 10–20. http://dx.doi.org/10.2174/1875181401806010010.

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Biomedical engineering handles the organization and functioning of medical devices in the hospital. This is a strategic function of the hospital for its balance, development, and growth. This is a major focus in internal and external reports of the hospital. It's based on piloting of medical devices needs and the procedures of biomedical teams’ intervention. Multi-year projects of capital and operating expenditure in medical devices are planned as coherently as possible with the hospital's financial budgets. An information system is an essential tool for monitoring medical devices engineering and relationship with medical services.

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15

Vomero, Maria, and Giuseppe Schiavone. "Biomedical Microtechnologies Beyond Scholarly Impact." Micromachines 12, no. 12 (November 29, 2021): 1471. http://dx.doi.org/10.3390/mi12121471.

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The recent tremendous advances in medical technology at the level of academic research have set high expectations for the clinical outcomes they promise to deliver. To the demise of patient hopes, however, the more disruptive and invasive a new technology is, the bigger the gap is separating the conceptualization of a medical device and its adoption into healthcare systems. When technology breakthroughs are reported in the biomedical scientific literature, news focus typically lies on medical implications rather than engineering progress, as the former are of higher appeal to a general readership. While successful therapy and diagnostics are indeed the ultimate goals, it is of equal importance to expose the engineering thinking needed to achieve such results and, critically, identify the challenges that still lie ahead. Here, we would like to provoke thoughts on the following questions, with particular focus on microfabricated medical devices: should research advancing the maturity and reliability of medical technology benefit from higher accessibility and visibility? How can the scientific community encourage and reward academic work on the overshadowed engineering aspects that will facilitate the evolution of laboratory samples into clinical devices?

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16

Hassan, Usman, Talat Zahra, and Shrish Bajpai. "Biomedical Engineering Education in India." Comparative Professional Pedagogy 9, no. 4 (December 1, 2019): 51–58. http://dx.doi.org/10.2478/rpp-2019-0037.

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AbstractIn the industrialized nation, almost every facet of our lives is permeated by technological innovation at an accelerated pace. This is especially true in the areas related to health and medicine, which has further led to the evolution of a health care system that is technologically related and capable of providing a wide range of effective therapeutic and diagnostic treatments. The application of the principles and problem-solving techniques of engineering, biology and medicine is Biomedical engineering. Biomedical engineering focuses on the advancements to improve human health at all possible levels. Biomedical engineering has emerged as a new area of research combining biology and medicine with technology, providing new designs and concepts of medical instrumentation for the diagnosis, cure and prevention of various diseases. Biomedical engineering in the last three decades has sustained growth in human resources along with the emergence of careers as graduates and postgraduates and apart from this research works, health care and technological development are some of its other aspects. The present paper will provide an insight into biomedical engineering and future scopes, specifically in India. Biomedical engineers use and apply knowledge of the modern biological principles in their designing process. A biomedical engineer can work in a wide variety of areas and disciplines. Apart from this, there are several opportunities in industries for innovations, designing and developing new techniques. In the last few years, biomedical engineering has emerged as a booming career as the area of work and research and the possibilities of innovations in this field are nearly endless. Thus, the future of biomedical engineering is tied to both the obstacles we face in the field of medical sciences and its advancements. Hence the use of the biomedical engineering method has become a necessity for human health, research and development.

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17

Aydın, Serap. "THE ROLE OF BIOMEDICAL ENGINEERING PROFESSIONS IN MEDICAL EDUCATION." Biomedical Engineering: Applications, Basis and Communications 21, no. 04 (August 2009): 265–70. http://dx.doi.org/10.4015/s1016237209001295.

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In the present study, the important role of biomedical engineering (BME) professions in medical education (ME) is highlighted. We propose that BME and ME should be integrated in a joint department to provide high-quality occupational education in medicine. Then, we illustrate the basic connections and close relations between BME and ME with respect to the universal subfields of each scientific branch. As this regard, the proposed joint department in medical faculty would guide the medicine to use innovative educational tools such as humanistic models, realistic simulations, video games, web-based online resources, etc. in both basic and clinical ME. In addition, the combination of two disciplines would prepare the initiative facilities for multidisciplinary original research studies improving human health. Moreover, new trends in instructional evaluation could be captured by studying together in teams.

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18

Foster, Kenneth R., Robert Koprowski, and Joseph D. Skufca. "Machine learning, medical diagnosis, and biomedical engineering research - commentary." BioMedical Engineering OnLine 13, no. 1 (2014): 94. http://dx.doi.org/10.1186/1475-925x-13-94.

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19

UMEZU, Mitsuo, Kiyotaka IWASAKI, Kouichi SUZUKAWA, Naoto SHIRASAWA, Mumehiro INOUE, Yasuhisa SAKURAI, and Teruo OKANO. "New biomedical engineering research based on a collaboration between medical-engineering institutions." Proceedings of Conference of Kanto Branch 2003.9 (2003): 103–4. http://dx.doi.org/10.1299/jsmekanto.2003.9.103.

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20

Ison, K. "Medical physics and medical engineering in the UK." Medical Engineering & Physics 16, no. 1 (January 1994): 5–14. http://dx.doi.org/10.1016/1350-4533(94)90003-5.

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21

Liu, Bangtao, Min Luo, Minjun Li, Xiaoyu Kang, and Chenghu Zhang. "Medical colleges summary of biomedical engineering profession<br>—Luzhou Medical College in the perspective of biomedical engineering profession<br>." Journal of Biomedical Science and Engineering 06, no. 03 (2013): 277–79. http://dx.doi.org/10.4236/jbise.2013.63035.

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22

GESSNER, U. "Medical Engineering in Switzerland." Journal of Clinical Engineering 16, no. 1 (January 1991): 61–64. http://dx.doi.org/10.1097/00004669-199101000-00015.

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23

Mizutani, Masayoshi, and Tsunemoto Kuriyagawa. "Special Issue on Biomedical Applications." International Journal of Automation Technology 11, no. 6 (October 31, 2017): 861. http://dx.doi.org/10.20965/ijat.2017.p0861.

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Interdisciplinary research that integrates medical science, biotechnology, materials science, mechanical engineering, and manufacturing has seen rapid progress in recent years. Not only fundamental research into biological functions but also the development of clinical approaches to treating patients are being actively carried out by experts in different fields. For example, artificial materials, such as those used in orthopedic surgery and dental implants, are being used more widely in medical treatments. In the area of minimally invasive surgery using X-rays, CT, and MRI, medical devices possessing radiolucent and nonmagnetic properties are playing a major role. Medical auxiliary equipment, such as wheelchairs, prosthetic feet, and other objects used to supplement medical treatment, is also critical. To assure that such advances continue into the future, material development and manufacturing processes should eventually satisfy the requirements of medical and biological applications, which are being debated by experts in different fields. The applicable materials should have excellent specific strength and rigidity, high biocompatibility, and good formability. The various needs for material characteristics and functions make interdisciplinary research essential. Mechanical engineering and manufacturing technologies should be further developed to solve problems involved in the establishment of basic principles by integrating the knowledge of materials science, medical science, biology, chemistry, and other fields. This special issue addresses the latest research advances into the biomedical applications of different manufacturing technologies. This covers a wide area, including biotechnologies, biomanufacturing, biodevices, and biomedical technologies. We hope that learning more about these advances will enable the readers to share in the authors’ experience and knowledge of technologies and development. All papers were refereed through careful peer reviews. We would like express our sincere appreciation to the authors for their submissions and to the reviewers for their invaluable efforts, which have ensured the success of this special issue.

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24

Woo, Eung Je, Hee-Joung Kim, and Jos A. E. Spaan. "World Congress on Medical Physics and Biomedical Engineering (WC2006, Seoul)." Medical & Biological Engineering & Computing 45, no. 11 (November 15, 2007): 1003–4. http://dx.doi.org/10.1007/s11517-007-0284-9.

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25

Gil, F. J., and J. A. Planell. "Shape memory alloys for medical applications." Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine 212, no. 6 (June 1, 1998): 473–88. http://dx.doi.org/10.1243/0954411981534231.

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The shape memory alloys exhibit a number of remarkable properties, which open new possibilities in engineering and more specifically in biomedical engineering. The most important alloy used in biomedical applications is NiTi. This alloy combines the characeristics of the shape memory effect and superelasticity with excellent corrosion resistance, wear characteristics, mechanical properties and a good biocompatibility. These properties make it an ideal biological engineering material, especially in orthopaedic surgery and orthodontics. In this work the basis of the memory effect lies in the fact that the materials exhibiting such a property undergo a thermoelastic martensitic transformation. In order to understand even the most elementary engineering aspects of the shape memory effect it is necessary to review some basic principles of the formation and the characteristics of the martensitic phase. The different properties of shape memory, superelasticity, two-way shape memory, rubber-like behaviour and a high damping capacity are reviewed. Some applications proposed in recent years are described and classified according to different medical fields.

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26

Pulingam, Thiruchelvi, Jimmy Nelson Appaturi, Thaigarajan Parumasivam, Azura Ahmad, and Kumar Sudesh. "Biomedical Applications of Polyhydroxyalkanoate in Tissue Engineering." Polymers 14, no. 11 (May 24, 2022): 2141. http://dx.doi.org/10.3390/polym14112141.

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Tissue engineering technology aids in the regeneration of new tissue to replace damaged or wounded tissue. Three-dimensional biodegradable and porous scaffolds are often utilized in this area to mimic the structure and function of the extracellular matrix. Scaffold material and design are significant areas of biomaterial research and the most favorable material for seeding of in vitro and in vivo cells. Polyhydroxyalkanoates (PHAs) are biopolyesters (thermoplastic) that are appropriate for this application due to their biodegradability, thermo-processability, enhanced biocompatibility, mechanical properties, non-toxicity, and environmental origin. Additionally, they offer enormous potential for modification through biological, chemical and physical alteration, including blending with various other materials. PHAs are produced by bacterial fermentation under nutrient-limiting circumstances and have been reported to offer new perspectives for devices in biological applications. The present review discusses PHAs in the applications of conventional medical devices, especially for soft tissue (sutures, wound dressings, cardiac patches and blood vessels) and hard tissue (bone and cartilage scaffolds) regeneration applications. The paper also addresses a recent advance highlighting the usage of PHAs in implantable devices, such as heart valves, stents, nerve guidance conduits and nanoparticles, including drug delivery. This review summarizes the in vivo and in vitro biodegradability of PHAs and conducts an overview of current scientific research and achievements in the development of PHAs in the biomedical sector. In the future, PHAs may replace synthetic plastics as the material of choice for medical researchers and practitioners.

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27

Estrela, Vania V. "SDR-Based High-Definition Video Transmission for Biomedical Engineering." Medical Technologies Journal 4, no. 3 (December 7, 2020): 584–85. http://dx.doi.org/10.26415/2572-004x-vol4iss3p584-585.

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Background: Software-Defined Radio (SDR) frameworks from cellular telephone base stations, e.g., Multiservice Distributed Access System (MDAS) and small cells, employ extensively integrated RF agile transceivers. The Internet of Medical Things (IoMT) is the collection of medical devices and applications that connect to healthcare IT systems through online computer networks. Medical devices equipped with Wi-Fi allow M2M communication, which is the backbone of IoMT and associated devices linked to cloud platforms containing stored data to be analyzed. Examples of IoMT include remote patient monitoring of people with chronic or long-term conditions, tracking patient medication orders and the location of patients admitted to hospitals, and patients' wearables to send info to caregivers. Infusion pumps connected to dashboards and hospital beds rigged with sensors measuring patients' vital signs are medical devices that can be converted to or deployed as IoMT technology. Methods: This work proposes an SDR architecture to allow wireless High-Definition (HD) video broadcast for biomedical applications. This text examines a Wideband Wireless Video (WWV) signal chain implementation using the transceivers, the data transmitted volume, the matching occupied RF bandwidth, the communication distance, the transmitter’s power, and the implementation of the PHY layer as Orthogonal Frequency Division Multiplexing (OFDM) with test results to evade RF interference. Results: As the IoMT grows, the amount of possible IoMT uses increases. Many mobile devices employ Near Field Communication (NFC) Radio Frequency Identification (RFID) tags allowing them to share data with IT systems. RFID tags in medical equipment and supplies allow hospital staff can remain aware of the quantities they have in stock. The practice of using IoMT devices to observe patients in their homes remotely is also known as telemedicine. This kind of treatment spares patients from traveling to healthcare facilities whenever they have a medical question or change in their condition. Conclusion: An SDR-based HD biomedical video transmission is proposed, with its benefits and disadvantages for biomedical WWV are discussed. The security of IoMT sensitive data is a developing concern for healthcare providers.

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Renukalatha, S., and K. V. Suresh. "A REVIEW ON BIOMEDICAL IMAGE ANALYSIS." Biomedical Engineering: Applications, Basis and Communications 30, no. 04 (August 2018): 1830001. http://dx.doi.org/10.4015/s1016237218300018.

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Bio-medical image analysis is an interdisciplinary field which includes: biology, physics, medicine and engineering. It deals with application of image processing techniques to biological or medical problems. Medical images to be analyzed contain a lot of information regarding the anatomical structure under investigation to reveal valid diagnosis and thereby helping doctors to choose adequate therapy. Doctors usually analyse these medical images manually through visual interpretation. But visual analysis of these images by human observers is limited due to variation in interpersonal interpretations, fatigue errors, surrounding disturbances and moreover this kind of analysis is purely subjective. On the other hand, automated analysis of these images using computers with suitable techniques favours the objective analysis by an expert and thereby improving the diagnostic confidence and accuracy of analysis. This survey is a consolidation of the exhaustive literature records related to biomedical image analysis.

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29

King, Paul H. "Control Theory in Biomedical Engineering: Applications in Physiology and Medical Robotics." IEEE Pulse 12, no. 1 (January 2021): 37–38. http://dx.doi.org/10.1109/mpuls.2021.3052597.

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30

UYAMA, CHIKAO. "Exciting Challenge of Biomedical Engineering. Synchrotron Radiation and its Medical Applications." Journal of the Institute of Electrical Engineers of Japan 120, no. 5 (2000): 274–76. http://dx.doi.org/10.1541/ieejjournal.120.274.

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31

Perry, Seymour. "Report from the World Congress on Medical Physics and Biomedical Engineering." International Journal of Technology Assessment in Health Care 11, no. 3 (1995): 638–39. http://dx.doi.org/10.1017/s0266462300008850.

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32

Settapat, Sittapong, Tiranee Achalakul, and Michiko Ohkura. "Web-based 3D medical image visualization framework for biomedical engineering education." Computer Applications in Engineering Education 22, no. 2 (April 26, 2011): 216–26. http://dx.doi.org/10.1002/cae.20548.

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33

Zieliński, Krzysztof, Tomasz Gólczewski, Maciej Kozarski, and Marek Darowski. "Virtual and Artificial Cardiorespiratory Patients in Medicine and Biomedical Engineering." Membranes 12, no. 6 (May 25, 2022): 548. http://dx.doi.org/10.3390/membranes12060548.

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Recently, ‘medicine in silico’ has been strongly encouraged due to ethical and legal limitations related to animal experiments and investigations conducted on patients. Computer models, particularly the very complex ones (virtual patients—VP), can be used in medical education and biomedical research as well as in clinical applications. Simpler patient-specific models may aid medical procedures. However, computer models are unfit for medical devices testing. Hybrid (i.e., numerical–physical) models do not have this disadvantage. In this review, the chosen approach to the cardiovascular system and/or respiratory system modeling was discussed with particular emphasis given to the hybrid cardiopulmonary simulator (the artificial patient), that was elaborated by the authors. The VP is useful in the education of forced spirometry, investigations of cardiopulmonary interactions (including gas exchange) and its influence on pulmonary resistance during artificial ventilation, and explanation of phenomena observed during thoracentesis. The artificial patient is useful, inter alia, in staff training and education, investigations of cardiorespiratory support and the testing of several medical devices, such as ventricular assist devices and a membrane-based artificial heart.

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34

Meldrum, Stuart J. "Annual Reviews of Biomedical Engineering: Volume 2." Physiological Measurement 22, no. 3 (August 1, 2001): 647. http://dx.doi.org/10.1088/0967-3334/22/3/702.

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35

Hyman, William A. "Clinical Engineering and Medical Technology Management." Journal of Clinical Engineering 26, no. 3 (2001): 218–23. http://dx.doi.org/10.1097/00004669-200126030-00009.

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36

Viktorov, V. A. "40th Anniversary of Meditsinskaya Tekhnika (Biomedical Engineering)." Biomedical Engineering 41, no. 2 (March 2007): 51–52. http://dx.doi.org/10.1007/s10527-007-0011-8.

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37

Tabakov, Slavik. "e-Learning in Medical Engineering and Physics." Medical Engineering & Physics 27, no. 7 (September 2005): 543–47. http://dx.doi.org/10.1016/j.medengphy.2005.06.001.

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38

Hayaliev, Rustem, Sabir Nurkhodjaev, Nodira Nazarova, Jasur Rizayev, Rustam Rahimberdiyev, Tatyana Timokhina, and Ivan Petrov. "Interdisciplinary Approach of Biomedical Engineering in the Development of Technical Devices for Medical Research." Journal of Biomimetics, Biomaterials and Biomedical Engineering 53 (October 12, 2021): 85–92. http://dx.doi.org/10.4028/www.scientific.net/jbbbe.53.85.

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The article discusses the development and application of technical devices for medical research. Biomedical engineering is one of the scientific and technical fields that explores and develops the application of engineering principles and concepts in medicine and biology to create artificial organs that can compensate for the lack of physiological functions. Medical engineering combines engineering and design skills with problem solubilities in the field of medicine and life sciences, and can also improve therapies based on the fundamental principles of molecular and cell biology, including diagnosis, monitoring and treatment.

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Kruger, Randell L., Bruce H. Curran, and William R. Hendee. "The growth of biomedical engineering is a major challenge to medical physics." Medical Physics 31, no. 9 (August 13, 2004): 2375–77. http://dx.doi.org/10.1118/1.1781175.

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40

Geddes, L. A. "Biomedical engineering: Baylor Medical College-preparing for the space age, 1956-1974." IEEE Engineering in Medicine and Biology Magazine 10, no. 3 (1991): 50, 63. http://dx.doi.org/10.1109/51.84189.

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41

Round, W. H. "A survey of the Australasian clinical medical physics and biomedical engineering workforce." Australasian Physics & Engineering Sciences in Medicine 30, no. 1 (March 2007): 13–24. http://dx.doi.org/10.1007/bf03178405.

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42

Allen, Barry, and Barry Allen. "Report on the World Congress on Medical Physics and Biomedical Engineering-WC2003." Australasian Physics & Engineering Sciences in Medicine 27, no. 3 (September 2004): 160. http://dx.doi.org/10.1007/bf03178677.

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43

Gisbert-Garzarán, Miguel, and María Vallet-Regí. "Nanoparticles for Bio-Medical Applications." Nanomaterials 12, no. 7 (April 2, 2022): 1189. http://dx.doi.org/10.3390/nano12071189.

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The Special Issue of Nanomaterials “Nanoparticles for Biomedical Applications” highlights the use of different types of nanoparticles for biomedical applications, including magnetic nanoparticles, mesoporous carbon nanoparticles, mesoporous bioactive glass nanoparticles, and mesoporous silica nanoparticles [...]

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44

Moussaid, Abdelghani, Hassan Bouaouine, and Nabil Ngote. "Self-Assessment of Biomedical Activity Related to Medical Devices Embedded in EMS Ambulances: Towards a Roadmap for an Efficient Improvement." Open Biomedical Engineering Journal 15, no. 1 (December 31, 2021): 119–30. http://dx.doi.org/10.2174/1874120702115010119.

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Objective: The present investigation is focused on a self-assessment of the biomedical activity related to embedded Medical Devices on board a fleet of 46 EMS medicalized ambulances, according to the High Authority of Health standard (criterion 8K) and the Guide of the Good Practices of Biomedical Engineering. Materials and Methods: The methodology adopted for this purpose is based on an analysis allowing the evaluation and observation of practices related to biomedical activity in these ambulances. An initial assessment, carried out in March 2021, made it possible to measure the gaps between the actual situation and the recommendations of the two self-diagnosis tools (High Authority of Health and Guide of the Good Practices of Biomedical Engineering standards). A series of corrective actions were proposed and then implemented. A second self-assessment took place after 6 months, in October 2021. Results: Between March and October 2021, an improvement in the scores for almost all the axes of the two self-assessment tools was noted. Indeed, the score of the self-assessment for the High Authority of Health reference system rose from 44% in March 2021 to 63% in October 2021, i.e. an increase of 19%, and that of the Guide of the Good Practices of Biomedical Engineering increased from 67.54% in March 2021 to 80.96% in October 2021, i.e. an increase of 13.42%. Conclusion: The implementation of a maintenance strategy integrating the notion of quality, relevant procedures and pertinent work tools has made it possible to significantly improve the biomedical activity within the medical ambulances and to optimise the embedded medical devices.

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HACK, STANLEY N., JOHN HEISS, and MICHAEL J. MARTINICHIO. "Radiology Engineering at the Albany Medical Center." Journal of Clinical Engineering 12, no. 5 (September 1987): 353–60. http://dx.doi.org/10.1097/00004669-198709000-00008.

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Cohen, Ted. "Clinical Engineering at UC Davis Medical Center." Journal of Clinical Engineering 24, no. 6 (November 1999): 344. http://dx.doi.org/10.1097/00004669-199911000-00006.

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Liu, Weiwei, Jianing Yang, and Kexin Bi. "Factors Influencing Private Hospitals’ Participation in the Innovation of Biomedical Engineering Industry: A Perspective of Evolutionary Game Theory." International Journal of Environmental Research and Public Health 17, no. 20 (October 13, 2020): 7442. http://dx.doi.org/10.3390/ijerph17207442.

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The innovation of the biomedical engineering (BME) industry is inseparable from its cooperation with medical institutions. China has considerable medical institutions. Although private hospitals account for more than half of Chinese medical institutions, they rarely participate in biomedical engineering industry innovation. This paper analyzed the collaborative relationship among biomedical engineering enterprises, universities, research institutes, public hospitals and private hospitals through evolutionary game theory and discussed the influence of different factors on the collaborative innovation among them. A tripartite evolutionary game model is established which regards private hospitals as a stakeholder. The results show that (1) the good credit of private hospitals has a positive effect on their participation in collaborative innovation; (2) it is helpful for BME collaborative innovation to enhance the collaborative innovation ability of partners; (3) the novelty of innovation projects has an impact on BME collaborative innovation. The specific impacts depend on the revenue, cost and risk allocation ratio of innovation partners; (4) the higher the practicability of innovation projects, the more conducive to collaborative innovation.

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Vienni, Bianca, and Franco Simini. "INTERDISCIPLINARITY AND GLOBAL COLLABORATION IN BIOMEDICAL ENGINEERING AND INFORMATICS TEACHING." Revista Observatório 4, no. 3 (April 29, 2018): 486–508. http://dx.doi.org/10.20873/uft.2447-4266.2018v4n3p486.

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This paper takes the Núcleo of Ingeniería Biomédica (NIB) from the Universidad de la República (Uruguay) as an example of how interdisciplinarity and global collaboration can be achieved in Higher Education teaching activities with a focus on Biomedical Engineering and Medical Informatics. We have recorded and analyzed using a qualitative strategy its practices in different teaching formats to interpret the best pedagogical strategies in the combination of interdisciplinarity and distant collaboration when using new technologies of communication. KEYWORDS: Biomedical Engineering; Interdisciplinarity; University; Uruguay.

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Miranda, Inês, Andrews Souza, Paulo Sousa, João Ribeiro, Elisabete M. S. Castanheira, Rui Lima, and Graça Minas. "Properties and Applications of PDMS for Biomedical Engineering: A Review." Journal of Functional Biomaterials 13, no. 1 (December 21, 2021): 2. http://dx.doi.org/10.3390/jfb13010002.

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Polydimethylsiloxane (PDMS) is an elastomer with excellent optical, electrical and mechanical properties, which makes it well-suited for several engineering applications. Due to its biocompatibility, PDMS is widely used for biomedical purposes. This widespread use has also led to the massification of the soft-lithography technique, introduced for facilitating the rapid prototyping of micro and nanostructures using elastomeric materials, most notably PDMS. This technique has allowed advances in microfluidic, electronic and biomedical fields. In this review, an overview of the properties of PDMS and some of its commonly used treatments, aiming at the suitability to those fields’ needs, are presented. Applications such as microchips in the biomedical field, replication of cardiovascular flow and medical implants are also reviewed.

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Tian, Yin, Li Yang, Zhongyan Wang, Huiling Zhang, Wei Xu, Shuxing Zheng, Haying Zhang, and Dechun Zhao. "Explore postgraduate biomedical engineering course integration between medical signal processing and drug development: example for drug development in brain disease." ADMET and DMPK 4, no. 2 (July 3, 2016): 179. http://dx.doi.org/10.5599/admet.4.2.325.

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<p class="PaperKeywordTitle">Medical signal processing is a compulsory course in our university’s undergraduate biomedical engineering programme. Recently, application of medical signal processing in supporting new drug development has emerged as a promising strategy in neurosciences. Here, we discuss the curriculum reformation in biomedical signal processing course in the context of drug development and application in central nervous system, with a particular emphasis in knowledge integration. </p>

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