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  • Course Information
    • Course Title Code Semester Laboratory+Practice (Hour) Pool Type ECTS
    Biomedical Sensors KİM604 FALL-SPRING 3+0 University E 6
    Learning Outcomes
    1-Explains various types of biomedical sensors and biosensors used to measure electrical, chemical and physical changes in the human body.
    2-Explains the medical applications of wearable and portable sensors and biosensors.
    3-Defines various types of sensors and biosensors used in biomedical applications.
    4-Explains the materials used in the preparation of biomedical sensors and biosensors.
  • ECTS / WORKLOAD
    • ActivityPercentage

    (100)

    		NumberTime (Hours)Total Workload (hours)
    Course Duration (Weeks x Course Hours)14342
    Classroom study (Pre-study, practice)14570
    Assignments0000
    Short-Term Exams (exam + preparation) 0000
    Midterm exams (exam + preparation)4013030
    Project0000
    Laboratory 0000
    Final exam (exam + preparation) 6014040
    0000
    Total Workload (hours)   182
    Total Workload (hours) / 30 (s)     6,07 ---- (6)
    ECTS Credit   6
  • Course Content
    • Week Topics Study Metarials
    1 Transducer, physical and biological sensor and biosensor, stimulus definitions and types R1-Section 1, 2, 3 R2-Section 1
    2 Introduction to biomedical sensors and biosensors and classification R1-Section 1, 2, 3 R2-Section 1, 2
    3 Biomedical biopotential electrodes R2-Section 5 R3-Section 7 R4- pp 10-16 R5- pp 524-529
    4 Biomedical transducer R6- pp 1-4
    5 Biomedical immunosensors R7- pp 4124 R8- pp 96 R9- pp 493-505
    6 Biomedical optical sensors and biosensors R2-Section 6 R3-Section 6, 7
    7 Biomedical electrochemical sensors and biosensors R1-Section 4 R2-Section 6 R3-Section 6 R10- pp 51-56 R11- pp 113-129
    8 Biomedical wearable sensors and biosensors R1-Section 5 R2-Section 6 R3-Section 5 R12- pp 363-371 R13- pp 29-46 R14- pp 402-408
    9 Portable biomedical biosensors R15- pp 2376-2396 R16- pp 273-284 R17- pp 115701
    10 QR Code Based Biomedical Sensors and Biosensors R18- pp 963-971 R19- pp 111769
    11 Smartphone based biomedical sensors and biosensors R20- pp 136-149 R21- pp 5339-5351
    12 Biomedical applications of physical sensors R22- pp 1-3 R23- pp 85-108 R24- pp 341-366
    13 Biomedical applications of biological sensors R9- pp 493-505 R11- pp 113-129 R15- pp 364
    14 Recent developments in biomedical sensors R26- pp 67-89 R27- pp 297-327 R28- pp 51-79 R29- pp
    Prerequisites -
    Language of Instruction Turkish
    Responsible Assoc. Prof.Dr.
    Instructors

    1-)Doçent Dr. Melike Bilgi Kamaç
    Assistants -
    Resources Refences R1- Wang, P., & Liu, Q. (2011). Biomedical sensors and measurement. Springer Science & Business Media. R2- Spichiger-Keller, U. E. (2008). Chemical sensors and biosensors for medical and biological applications. John Wiley & Sons. R3- Bronzino, J. D. (1995). The Biomedical Engineering Handbook?CRC Press. Boca Raton FL. R4- Griss, P., Enoksson, P., Tolvanen-Laakso, H. K., Merilainen, P., Ollmar, S., & Stemme, G. (2001). Micromachined electrodes for biopotential measurements. Journal of Microelectromechanical Systems, 10(1), 10-16. R5- Adzima, J., Penhaker, M., Klinkovsky, T., Oczka, D., Kubicek, J., Schmidt, M., ... & Barvik, D. (2019). Device for Evaluation of Electrical Parameters of Biopotential Electrodes. IFAC-PapersOnLine, 52(27), 524-529. R6- Lai, W. C., & Chung, M. A. (2016). Integrated chip health transducer and wireless control for biomedical and computer systems. In 2016 Sixth International Conference on Information Science and Technology (ICIST) (pp. 1-4). IEEE. R7- Felix, F. S., Baccaro, A. L., & Angnes, L. (2018). Disposable Voltammetric Immunosensors Integrated with Microfluidic Platforms for Biomedical, Agricultural and Food Analyses: A Review. Sensors, 18(12), 4124. R8- Mansuriya, B. D., & Altintas, Z. (2020). Graphene Quantum Dot-Based Electrochemical Immunosensors for Biomedical Applications. Materials, 13(1), 96. R9- Zhao, X., Gao, W., Zhang, H., Qiu, X., & Luo, Y. (2020). Graphene quantum dots in biomedical applications: recent advances and future challenges. In Handbook of Nanomaterials in Analytical Chemistry (pp. 493-505). Elsevier. R10- Ozoemena, K. I., & Carrara, S. (2017). Biomedical electrochemical sensors for resource-limited countries. Current Opinion in Electrochemistry, 3(1), 51-56. R11- Maduraiveeran, G., Sasidharan, M., & Ganesan, V. (2018). Electrochemical sensor and biosensor platforms based on advanced nanomaterials for biological and biomedical applications. Biosensors and Bioelectronics, 103, 113-129. R12- Bandodkar, A. J., & Wang, J. (2014). Non-invasive wearable electrochemical sensors: a review. Trends in biotechnology, 32(7), 363-371. R13- Windmiller, J. R., & Wang, J. (2013). Wearable electrochemical sensors and biosensors: a review. Electroanalysis, 25(1), 29-46. R14- Vilela, D., Romeo, A., & Sánchez, S. (2016). Flexible sensors for biomedical technology. Lab on a Chip, 16(3), 402-408. R15- Samiei, E., Tabrizian, M., & Hoorfar, M. (2016). A review of digital microfluidics as portable platforms for lab-on a-chip applications. Lab on a Chip, 16(13), 2376-2396. R16- Zhang, D., & Liu, Q. (2016). Biosensors and bioelectronics on smartphone for portable biochemical detection. Biosensors and Bioelectronics, 75, 273-284. R17- Liu, D., Wang, J., Wu, L., Huang, Y., Zhang, Y., Zhu, M., ... & Yang, C. (2019). Trends in miniaturized biosensors for point-of-care testing. TrAC Trends in Analytical Chemistry, 115701. R18- Yuan, M., Liu, K. K., Singamaneni, S., & Chakrabartty, S. (2016). Self-powered forward error-correcting biosensor based on integration of paper-based microfluidics and self-assembled quick response codes. IEEE transactions on biomedical circuits and systems, 10(5), 963-971. R19- Zheng, X., Li, L., Zhang, L., Xie, L., Song, X., & Yu, J. (2020). Multiple self-cleaning paper-based electrochemical ratiometric biosensor based on the inner reference probe and exonuclease III-assisted signal amplification strategy. Biosensors and Bioelectronics, 147, 111769. R20- Kanchi, S., Sabela, M. I., Mdluli, P. S., & Bisetty, K. (2018). Smartphone based bioanalytical and diagnosis applications: A review. Biosensors and Bioelectronics, 102, 136-149. R21- Huang, X., Xu, D., Chen, J., Liu, J., Li, Y., Song, J., ... & Guo, J. (2018). Smartphone-based analytical biosensors. Analyst, 143(22), 5339-5351. R22- Ahmad, R., & Salama, K. N. (2018, October). Physical Sensors for Biomedical Applications. In 2018 IEEE Sensors (pp. 1-3). IEEE. R23- McCutcheon, E. P. (2018). The Application of Physical Sensors to Studies of the Cardiovascular System. In Physical sensors for biomedical applications (pp. 85-108). CRC Press. R24- Mostafalu, P., Nezhad, A. S., Nikkhah, M., & Akbari, M. (2017). Flexible electronic devices for biomedical applications. In Advanced Mechatronics and MEMS Devices II (pp. 341-366). Springer, Cham. R25- Tavakoli, J., & Tang, Y. (2017). Hydrogel based sensors for biomedical applications: an updated review. Polymers, 9(8), 364. R26- Darwish, A., Ismail Sayed, G., & Ella Hassanien, A. (2019). The Impact of Implantable Sensors in Biomedical Technology on the Future of Healthcare Systems. Intelligent Pervasive Computing Systems for Smarter Healthcare, 67-89. R27- Maduraiveeran, G., & Jin, W. (2020). Functional nanomaterial-derived electrochemical sensor and biosensor platforms for biomedical applications. In Handbook of Nanomaterials in Analytical Chemistry (pp. 297-327). Elsevier. R28- Wan, H., Zhuang, L., Pan, Y., Gao, F., Tu, J., Zhang, B., & Wang, P. (2020). Biomedical sensors. In Biomedical Information Technology (pp. 51-79). Academic Press. R29- Kar, X. L., Shameli, K., Yew, Y. P., Teow, S. Y., Jahangirian, H., Rafiee-Moghaddam, R., & Webster, T. J. (2020). Recent Developments in the Facile Bio-Synthesis of Gold Nanoparticles (AuNPs) and Their Biomedical Applications. International Journal of Nanomedicine, 15, 275.
    Supplementary Book -
    Goals To teach a wide range of sensors and biosensors used in biomedical applications to measure changes in pressure, flow, motion, temperature, heat flow, potential, current, conductivity, mass, and light intensity; to give information about portable, wearable, sensor, and biosensors.
    Content Introduction to biomedical sensors and biosensors and classification; biomedical transducer; biomedical immunosensors; biomedical optical sensors and biosensors; biomedical electrochemical sensors and biosensors; biomedical wearable sensors and biosensors; portable biomedical biosensors; QR code based biomedical sensors and biosensors; smartphone based biomedical sensors and biosensors; recent developments İn biomedical sensors.
  • Program Learning Outcomes
    • Program Learning Outcomes Level of Contribution
    1 Develops, deepens and analyzes, and interprets the knowledge and skills at the master`s level at the level of expertise in the same field. 3
    2 Specializes in using and developing modern tools and equipment related to the field. 4
    3 Interprets and creates new ideas by synthesizing the knowledge gained in the field with the knowledge from other disciplines. -
    4 Presents the current developments in the field and the research results with quantitative and qualitative data to the groups in the field and outside the field in a detailed and systematic way, in written, oral - visual form. 4
    5 Analyzes a problem in the field independently, develops a solution method, evaluates the results, and applies them when necessary. -
    6 Has advanced oral and written communication skills in at least one foreign language. -
    7 Performs a comprehensive study that puts a new face to science and technology, develops a scientific method and/or technological product/process, or applies a known method to a new field. -
    8 Has the ability to do advanced resource research, and access databases and other information resources in order to access information related to the field. -
    9 Conducts leadership in identifying and solving unique and interdisciplinary problems related to the field. -
    10 Expands the boundaries of knowledge in its field by publishing at least one scientific article related to the field in international peer-reviewed journals. 3
    11 Evaluates the scientific, technological, social and cultural improvements and to transfer the knowledge to society objectively with ethical responsibility. -
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