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Journal articles on the topic 'Biomedical instrumentation'

Author: Grafiati
Published: 4 June 2021
Last updated: 14 March 2023

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1

Webster, John G. "Biomedical Instrumentation." International Journal of Systems Biology and Biomedical Technologies 3, no. 1 (January 2015): 20–38. http://dx.doi.org/10.4018/ijsbbt.2015010102.

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This paper covers the measurement of biopotentials for diagnosis: the electrical voltages that can be measured from electrodes placed on the skin or within the body. Biopotentials include: the electrocardiogram (ECG), electroencephalogram (EEG), electrocortogram (ECoG), electromyogram (EMG), electroneurogram (ENG), electrogastrogram (EGG), action potential (AP), electroretinogram (ERG), electro-oculogram (EOG). This paper also covers skin conductance, pulse oximeters, urology, wearable systems and important therapeutic devices such as: the artificial cardiac pacemaker, defibrillator, cochlear implant, hemodialysis, lithotripsy, ventilator, anesthesia machine, heart-lung machine, infant incubator, infusion pumps, electrosurgery, tissue ablation, and medical imaging. It concludes by covering electrical safety. It provides future subjects for research such as a blood glucose sensor and a permanently implanted intracranial pressure sensor.
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2

Clark, Tobey. "Biomedical Instrumentation Systems." Biomedical Instrumentation & Technology 46, no. 3 (May 1, 2012): 238. http://dx.doi.org/10.2345/0899-8205-46.3.238.

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3

Kim, Gi-Hyeon. "Biomedical Optics and Instrumentation Laboratory." Journal of the Korean Society of Visualization 9, no. 3 (September 30, 2011): 16–23. http://dx.doi.org/10.5407/jksv.2011.9.3.016.

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4

Anson, M. "Recent Advances in Biomedical Instrumentation." Measurement and Control 18, no. 5 (June 1985): 166–68. http://dx.doi.org/10.1177/002029408501800505.

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5

Rubin, Stanley A. "The Principles of Biomedical Instrumentation." Journal of Clinical Engineering 13, no. 1 (January 1988): 18. http://dx.doi.org/10.1097/00004669-198801000-00004.

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6

Sandhu, A., and H. Handa. "Practical Hall sensors for biomedical instrumentation." IEEE Transactions on Magnetics 41, no. 10 (October 2005): 4123–27. http://dx.doi.org/10.1109/tmag.2005.855339.

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7

Sutdipong, Sirimonpak, and Khanchai Tunlasakun. "Heart Sound Monitor for Biomedical Instrumentation." Applied Mechanics and Materials 303-306 (February 2013): 650–53. http://dx.doi.org/10.4028/www.scientific.net/amm.303-306.650.

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This research presents the design and development of the heart sound monitor for biomedical instrumentation which can be worked with a personal computer. The prototype will receive the heart sound via the condenser microphone built-in the stethoscope. The condenser microphone will be conversed the air pressure from heart beats to electrical signal that signal will transformed to computer via sound card. The sound card will be conversed the analog signal to digital signal for process by heart sound processing program developed by LabVIEW program. The signal will be analyzed with short time Fourier transforms in heart sound processing program by graphical user interface. The user is able to select a band pass of signal for filter and choose the frequency spectrum of heart sound for display. The output database from this prototype is necessary for Medical Education or Clinical Practice.
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8

Puente, S. T., A. Úbeda, and F. Torres. "e-Health: Biomedical instrumentation with Arduino." IFAC-PapersOnLine 50, no. 1 (July 2017): 9156–61. http://dx.doi.org/10.1016/j.ifacol.2017.08.1724.

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9

Pons, J. L., E. Rocon, A. Forner-Cordero, and J. Moreno. "Biomedical instrumentation based on piezoelectric ceramics." Journal of the European Ceramic Society 27, no. 13-15 (January 2007): 4191–94. http://dx.doi.org/10.1016/j.jeurceramsoc.2007.02.126.

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10

Gajare, Milind, and Shedge D.K. "CMOS Trans Conductance based Instrumentation Amplifier for Various Biomedical Signal Analysis." NeuroQuantology 20, no. 5 (April 30, 2022): 53–60. http://dx.doi.org/10.14704/nq.2022.20.5.nq22148.

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Feed forward design techniques for the Trans-conductance operational amplifier removes the barriers of operating frequencies. It is now possible to design amplifiers with large the Trans-conductance that operates at Giga hertz frequency range. There are several Trans-conductance amplifiers used to design a medical and Industrial application that helps in processing various bio medical signals such as Electrocardiographs, Electroencephalographs, Electromyograms and several others. The proposed paper shows the implementation of an instrumentation amplifier using CMOS based the Trans-conductance operational amplifiers also the processing of biomedical ECG, EEG and EMG signals. The CMOS process technology helps to integrate complex circuits on minimal surface area. The Trans-conductance instrumentation operational amplifiers has features includes noise reduction, low DC offset, High output impedance and Common Mode rejection Ratio values. The circuit implementation and simulations has been done on Electronic Design and Automation tool with 0.13μm CMOS process technology.
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11

Tremper, Kevin K. "Principles of Applied Biomedical Instrumentation, 3rd Edition." Anesthesia & Analgesia 70, no. 5 (May 1990): 575. http://dx.doi.org/10.1213/00000539-199005000-00027.

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12

Nunes, Brain. "Principles of Applied Biomedical Instrumentation, 3red Edition." Journal of Clinical Engineering 14, no. 6 (November 1989): 523. http://dx.doi.org/10.1097/00004669-198911000-00012.

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13

Cantor, Charles R., Takeshi Sano, Natalia E. Broude, and Cassandra L. Smith. "Instrumentation in molecular biomedical diagnostics: An overview." Genetic Analysis: Biomolecular Engineering 14, no. 2 (July 1997): 31–36. http://dx.doi.org/10.1016/s1050-3862(97)00006-5.

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14

Ms. Amruta Bijwar. "CMRR Boosted Instrumentation Amplifier for Biomedical Application." International Journal of New Practices in Management and Engineering 2, no. 04 (December 31, 2013): 01–06. http://dx.doi.org/10.17762/ijnpme.v2i04.21.

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This research paper discusses about a design of an amplifier for its use in an Analog Front End for Biomedical signal acquisition. The design of an AFE is also specific to the signal of interest. This paper deals with the design of an Analog Front End using 180nm process. An amplifier is a key component of an AFE. For instrumentation amplifier to satisfy theoretical results the OPAMP used must be close to ideal. The simulations are performed using TANNER EDA tool.
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15

Kostov, Yordan, and Govind Rao. "Low-cost optical instrumentation for biomedical measurements." Review of Scientific Instruments 71, no. 12 (2000): 4361. http://dx.doi.org/10.1063/1.1319859.

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16

Valentinuzzi, M. E. "Principles of applied biomedical instrumentation (third edition)." Journal of Biomedical Engineering 14, no. 1 (January 1992): 86. http://dx.doi.org/10.1016/0141-5425(92)90043-k.

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17

Shih, Kao-Shang, Ching-Chi Hsu, Shu-Yu Zhou, and Sheng-Mou Hou. "BIOMECHANICAL INVESTIGATION OF PEDICLE SCREW-BASED POSTERIOR STABILIZATION SYSTEMS FOR THE TREATMENT OF LUMBAR DEGENERATIVE DISC DISEASE USING FINITE ELEMENT ANALYSES." Biomedical Engineering: Applications, Basis and Communications 27, no. 06 (December 2015): 1550060. http://dx.doi.org/10.4015/s101623721550060x.

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Fusion has been the gold standard treatment for treating lumbar degenerative disc disease. Many clinical studies have demonstrated that adjacent segment degeneration was observed in patients over time. Various instrumentations of pedicle screw-based stabilization systems have been investigated using numerical approaches. However, numerical models developed in the past were simplified to reduce computational time. The aim of this study was to evaluate and to compare the biomechanical performance of rigid, semi-rigid, and dynamic posterior instrumentations using a more realistic numerical model. Three-dimensional nonlinear finite element models of the T11-S1 multilevel spine with various posterior instrumentations were developed. The intersegmental rotation, the maximum disc stress, and the maximum implant stress were calculated. The results indicated that the rigid instrumentation resulted in greater fixation stability but also a greater risk of adjacent segment degeneration and implant failure. The biomechanical performance of the dynamic instrumentation was closer to that of the intact spine model compared with the rigid and semi-rigid instrumentations. The results of this study could help surgeons understand the biomechanical characteristics of different posterior instrumentations for the treatment of lumbar degenerative disc diseases.
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18

Natarajan, Maya, Maya Natarajan, and Charles Patrick. "Clinical instrumentation." Annals of Biomedical Engineering 25, no. 1 (January 1997): S—59. http://dx.doi.org/10.1007/bf02647374.

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19

Moazzam, Muhammad, and Suleman Atique. "Review of “Handbook of Biomedical Instrumentation, Third Edition"." Advances in Medical, Dental and Health Sciences 3, no. 2 (July 24, 2020): 18. http://dx.doi.org/10.5530/amdhs.2020.2.4.

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20

Zou, Chunpeng, Beibei Wu, Yanyan Dong, Zhangwei Song, Yaping Zhao, Xianwei Ni, Yan Yang, and Zhe Liu. "Biomedical photoacoustics: fundamentals, instrumentation and perspectives on nanomedicine." International Journal of Nanomedicine Volume 12 (December 2016): 179–95. http://dx.doi.org/10.2147/ijn.s124218.

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21

King, Paul H. "Modern Practical Health Care Issues in Biomedical Instrumentation." IEEE Pulse 13, no. 4 (July 2022): 35–36. http://dx.doi.org/10.1109/mpuls.2022.3191449.

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22

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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23

Barnes, A., A. L. Evans, H. M. Job, R. Laing, and D. C. Smith. "A calibration service for biomedical instrumentation maintenance laboratories." Journal of Medical Engineering & Technology 23, no. 1 (January 1999): 1–4. http://dx.doi.org/10.1080/030919099294357.

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24

Sonkusare, Reena, Omkar Joshi, and S. S. Rathod. "SOI FinFET based instrumentation amplifier for biomedical applications." Microelectronics Journal 91 (September 2019): 1–10. http://dx.doi.org/10.1016/j.mejo.2019.07.005.

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25

Qu, Wenchao, Syed Kamrul Islam, Mohamed R. Mahfouz, Mohammad R. Haider, Gary To, and Salwa Mostafa. "Microcantilever Array Pressure Measurement System for Biomedical Instrumentation." IEEE Sensors Journal 10, no. 2 (February 2010): 321–30. http://dx.doi.org/10.1109/jsen.2009.2034134.

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26

Edwards, G. S., R. H. Austin, F. E. Carroll, M. L. Copeland, M. E. Couprie, W. E. Gabella, R. F. Haglund, et al. "Free-electron-laser-based biophysical and biomedical instrumentation." Review of Scientific Instruments 74, no. 7 (July 2003): 3207–45. http://dx.doi.org/10.1063/1.1584078.

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27

Ramana, Lakshmi Adusumilli, Shaik Razia, and K. Srinivasa Rao. "THE ANALYSIS ON APPLICATION OF IOT IN BIOMEDICAL INSTRUMENTATION." ECS Transactions 107, no. 1 (April 24, 2022): 20243–52. http://dx.doi.org/10.1149/10701.20243ecst.

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IoT-based biomedical applications are used in biomedical systems such as healthcare, diagnostics, prevention, therapy and monitoring. In addition, healthcare studies are moving toward individualised measurement as a whole. Observed assessments in the laboratory/clinic must be replaced by more comprehensive evaluations. But traditional barriers to long-term free-lived assessment have been the high cost and complexity of equipment. Due to the lack of supervised conditions in free-living assessments, environmental analysis is needed to provide context to individual measurements. Biomedical engineers should be aware of the opportunities, challenges, and limitations presented by low-cost and easily accessible Internet of Things (IoT) technologies. In our biomedical research project, IoT hardware and software technologies have been used to extract quantitative data for comparison with cloud-based cognitive information. A custom interface shows patient-specific information, pathology details and user interaction results to increase the user experience.
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28

Christensen, Doug. "Optical instrumentation systems." Annals of Biomedical Engineering 25, no. 1 (January 1997): S—4. http://dx.doi.org/10.1007/bf02647345.

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29

Chen, Xuequan, Hannah Lindley-Hatcher, Rayko I. Stantchev, Jiarui Wang, Kaidi Li, Arturo Hernandez Serrano, Zachary D. Taylor, Enrique Castro-Camus, and Emma Pickwell-MacPherson. "Terahertz (THz) biophotonics technology: Instrumentation, techniques, and biomedical applications." Chemical Physics Reviews 3, no. 1 (March 2022): 011311. http://dx.doi.org/10.1063/5.0068979.

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Terahertz (THz) technology has experienced rapid development in the past two decades. Growing numbers of interdisciplinary applications are emerging, including materials science, physics, communications, and security as well as biomedicine. THz biophotonics involves studies applying THz photonic technology in biomedicine, which has attracted attention due to the unique features of THz waves, such as the high sensitivity to water, resonance with biomolecules, favorable spatial resolution, capacity to probe the water–biomolecule interactions, and nonionizing photon energy. Despite the great potential, THz biophotonics is still at an early stage of development. There is a lack of standards for instrumentation, measurement protocols, and data analysis, which makes it difficult to make comparisons among all the work published. In this article, we give a comprehensive review of the key findings that have underpinned research into biomedical applications of THz technology. In particular, we will focus on the advances made in general THz instrumentation and specific THz-based instruments for biomedical applications. We will also discuss the theories describing the interaction between THz light and biomedical samples. We aim to provide an overview of both basic biomedical research as well as pre-clinical and clinical applications under investigation. The paper aims to provide a clear picture of the achievements, challenges, and future perspectives of THz biophotonics.
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30

Dukes, Madeline J., Rebecca Thomas, John Damiano, Kate L. Klein, Sharavanan Balasubramaniam, Sanem Kayandan, Judy S. Riffle, Richey M. Davis, Sarah M. McDonald, and Deborah F. Kelly. "Improved Microchip Design and Application for In Situ Transmission Electron Microscopy of Macromolecules." Microscopy and Microanalysis 20, no. 2 (December 13, 2013): 338–45. http://dx.doi.org/10.1017/s1431927613013858.

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AbstractUnderstanding the fundamental properties of macromolecules has enhanced the development of emerging technologies used to improve biomedical research. Currently, there is a critical need for innovative platforms that can illuminate the function of biomedical reagents in a native environment. To address this need, we have developed an in situ approach to visualize the dynamic behavior of biomedically relevant macromolecules at the nanoscale. Newly designed silicon nitride devices containing integrated “microwells” were used to enclose active macromolecular specimens in liquid for transmission electron microscopy imaging purposes.We were able to successfully examine novel magnetic resonance imaging contrast reagents, micelle suspensions, liposome carrier vehicles, and transcribing viral assemblies. With each specimen tested, the integrated microwells adequately maintained macromolecules in discrete local environments while enabling thin liquid layers to be produced.
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31

Ghaeb, Nebras. "A Study to Improve the Biomedical Instrumentation Lab Training." Engineering and Technology Journal 37, no. 4C (December 25, 2019): 427–30. http://dx.doi.org/10.30684/etj.37.4c.7.

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32

Noblitt, John. "Introduction to Biomedical Instrumentation: The Technology of Patient Care." Biomedical Instrumentation & Technology 43, no. 4 (July 1, 2009): 284. http://dx.doi.org/10.2345/0899-8205-43.4.284.

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33

Paltauf, Guenther, Robert Nuster, and Martin Frenz. "Progress in biomedical photoacoustic imaging instrumentation toward clinical application." Journal of Applied Physics 128, no. 18 (November 14, 2020): 180907. http://dx.doi.org/10.1063/5.0028190.

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34

bama, G. Sathiya. "A Survey on Instrumentation Amplifiers used for Biomedical application." International Journal of Advanced Research in Electrical, Electronics and Instrumentation Engineering 04, no. 03 (March 20, 2015): 1224–31. http://dx.doi.org/10.15662/ijareeie.2015.0403007.

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35

Shirmohammadi, Shervin, Kurt Barbe, Domenico Grimaldi, Sergio Rapuano, and Sabrina Grassini. "Instrumentation and measurement in medical, biomedical, and healthcare systems." IEEE Instrumentation & Measurement Magazine 19, no. 5 (October 2016): 6–12. http://dx.doi.org/10.1109/mim.2016.7579063.

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36

King, Paul H. "A College-Level Overview of Biomedical Instrumentation [Book Review]." IEEE Pulse 9, no. 6 (November 2018): 35. http://dx.doi.org/10.1109/mpul.2018.2870700.

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37

Mendes Junior, José Jair Alves, Daniel Prado Campos, Lorenzo Coelho de Andrade Villela De Biassio, Pedro Carlin Passos, Paulo Broniera Júnior, André Eugênio Lazzaretti, and Eddy Krueger. "AD8232 to Biopotentials Sensors: Open Source Project and Benchmark." Electronics 12, no. 4 (February 7, 2023): 833. http://dx.doi.org/10.3390/electronics12040833.

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Acquiring biopotentials with fidelity using low-cost circuits is a significant challenge in biomedical instrumentation. In this perspective, our goal is to investigate the characteristics of the widely applied AD8232®, an analog front-end for biopotential acquisition. We designed and evaluated circuits to acquire the most common biosignals: electrocardiogram (ECG), electromyogram (EMG), and electroencephalogram (EEG). Our findings show that the circuit is suitable for ECG and EMG instrumentation, although it has limitations for EEG signals, particularly concerning the gain. The entire project of the boards is also a contribution of this work as we intend to corroborate open-source do-it-yourself biomedical instrumentation.
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38

Pilling, Michael, and Peter Gardner. "Fundamental developments in infrared spectroscopic imaging for biomedical applications." Chemical Society Reviews 45, no. 7 (2016): 1935–57. http://dx.doi.org/10.1039/c5cs00846h.

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39

Cheng, J.-X. "Driving CARS into Biomedical Field." Microscopy and Microanalysis 14, S2 (August 2008): 68–69. http://dx.doi.org/10.1017/s1431927608086248.

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40

Pallás-Areny, R., and J. G. Webster. "Composite instrumentation amplifier for biopotentials." Annals of Biomedical Engineering 18, no. 3 (May 1990): 251–62. http://dx.doi.org/10.1007/bf02368441.

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41

Spicher, Anna, Werner Schmoelz, Rene Schmid, Hannes Stofferin, and Niall J. A. Craig. "Functional and radiographic evaluation of an interspinous device as an adjunct for lumbar interbody fusion procedures." Biomedical Engineering / Biomedizinische Technik 65, no. 2 (April 28, 2020): 183–89. http://dx.doi.org/10.1515/bmt-2018-0086.

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AbstractIn the last decades, several interspinous process devices were designed as a minimally invasive treatment option for spinal stenosis. In order to minimise surgical trauma, interspinous process devices were recently discussed as an alternative posterior fixation in vertebral interbody fusions. Therefore, the purpose of this study was to evaluate the effect of a newly designed interspinous device with polyester bands (PBs) on range of motion (RoM) and centre of rotation (CoR) of a treated motion segment in comparison with an established interspinous device with spikes (SC) as well as with pedicle screw instrumentation in lumbar fusion procedures. Flexibility tests with an applied pure moment load of 7.5 Nm were performed in six monosegmental thoracolumbar functional spinal units (FSUs) in the following states: (a) native, (b) native with PB device, (c) intervertebral cage with PB device, (d) cage with SC and (e) cage with internal fixator. The resulting RoM was normalised to the native RoM. The CoR was determined of X-ray images taken in maximal flexion and extension during testing. In flexion and extension, the PB device without and with the cage reduced the RoM of the native state to 58% [standard deviation (SD) 17.8] and 53% (SD 15.7), respectively. The SC device further reduced the RoM to 27% (SD 16.8), while the pedicle screw instrumentation had the most reducing effect to 17% (SD 17.2) (p < 0.01). In lateral bending and axial rotation, the interspinous devices had the least effect on the RoM. Compared to the native state, for all instrumentations the CoR showed a small shift towards cranial. In the anterior-posterior direction, the SC device and the pedicle screw instrumentation shifted the CoR towards the posterior wall. The interspinous devices significantly reduced the RoM in flexion/extension, while in axial rotation and lateral bending only the internal fixator had a significant effect on the RoM.
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42

Mathern, Ryan Michael, Sarah Schopman, Kyle Kalchthaler, Khanjan Mehta, and Peter Butler. "Design of affordable and ruggedized biomedical devices using virtual instrumentation." Journal of Medical Engineering & Technology 37, no. 4 (May 2013): 237–51. http://dx.doi.org/10.3109/03091902.2013.785608.

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43

Farrar, Emily J. "Implementing a Design Thinking Project in a Biomedical Instrumentation Course." IEEE Transactions on Education 63, no. 4 (November 2020): 240–45. http://dx.doi.org/10.1109/te.2020.2975558.

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44

Brown, M. B., J. N. Miller, D. P. Riley, N. J. Seare, Martin J. Bloxham, Steve J. Hill, Paul J. Worsfold, et al. "Novel instrumentation and biomedical applications of very near-infrared fluorescence." Analytical Proceedings 30, no. 3 (1993): 157. http://dx.doi.org/10.1039/ap9933000157.

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45

Brown, Marc B., Tony E. Edmonds, James N. Miller, David P. Riley, and Nichola J. Seare. "Novel instrumentation and biomedical applications of very near infrared fluorescence." Analyst 118, no. 4 (1993): 407. http://dx.doi.org/10.1039/an9931800407.

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46

Bianchi, A. M., L. T. Mainardi, and S. Cerutti. "Time–frequency analysis of biomedical signals." Transactions of the Institute of Measurement and Control 22, no. 3 (March 1, 2000): 215–30. http://dx.doi.org/10.1191/014233100676586099.

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47

Carvalho, T. M., M. F. Dunlap, and R. D. Allen. "The Biological Electron Microscope Facility, University of Hawai‘I at Mānoa: a Shared Microscopy Resource in the Pacific." Microscopy and Microanalysis 3, S2 (August 1997): 285–86. http://dx.doi.org/10.1017/s143192760000831x.

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The Biological Electron Microscope Facility (BEMF) at the University of Hawai‘i at Mānoa (UHM) is located 2400 miles over water from the next nearest research university. BEMF is a multi-user core facility, administered by the Pacific Biomedical Research Center (PBRC), an organized research unit at the UHM. The mission of the BEMF is to provide state-of-the-art instrumentation, services and training for electron microscopy to the biomedical and biological researchers in Hawai‘i and the Pacific region. The BEMF was established in 1984 under the direction of Dr. Richard D. Allen, and has since grown steadily in its instrumentation, expertise, and use. In the past 5 years it has served researchers from over 50 laboratories in PBRC and the colleges of Natural Sciences, Tropical Agriculture and Human Resources, Engineering, Medicine, and Ocean and Earth Sciences and Technology, as well as visiting investigators from other Hawai‘i, mainland and foreign institutions.The BEMF has a full line of instrumentation for conventional transmission and field emission scanning electron microscopy as well as a complete line of instruments for cryoelectron microscopy.
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48

Gong, Aiping, Yating Qiu, Xiaowan Chen, Zhenyu Zhao, Linzhong Xia, and Yongni Shao. "Biomedical applications of terahertz technology." Applied Spectroscopy Reviews 55, no. 5 (October 12, 2019): 418–38. http://dx.doi.org/10.1080/05704928.2019.1670202.

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49

Morris, Michael D. "Book Reviews: Biomedical Photonics Handbook." Applied Spectroscopy 58, no. 3 (March 2004): 86A. http://dx.doi.org/10.1366/000370204322886771.

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50

Nagulapalli, Rajasekhar, Khaled Hayatleh, Steve Barker, Saddam Zourob, Nabil Yassine, Sumathi Raparthy, and Amr Tammam. "A novel high CMRR trans-impedance instrumentation amplifier for biomedical applications." Analog Integrated Circuits and Signal Processing 98, no. 2 (June 26, 2018): 233–41. http://dx.doi.org/10.1007/s10470-018-1256-8.

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