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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
    Other 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 275
    Prerequisites -
    Language of Instruction Turkish
    Responsible Assist. Prof. Dr. Melike BİLGİ KAMAÇ
    Instructors

    1-)Doçent Dr. Melike Bilgi Kamaç
    Assistants -
    Resources 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 Based on the competencies of the doctorate, to develop and deepen the current and advanced knowledge in the field with original thinking and research at the level of expertise and to reach original definitions that will bring innovation to science. 4
    2 Understanding the interaction between the disciplines related to the field of chemistry; to achieve original results by using expertise in analyzing, synthesizing and evaluating new and complex ideas. 5
    3 To reach new scientific knowledge in the field of chemistry and to gain high level skills in research methods related to the field. 5
    4 To be able to develop a new scientific method in the field of chemistry or to apply a known method to a different problem. -
    5 To be able to research, comprehend, design, adapt and apply an original subject. -
    6 To be able to question, synthesize and evaluate new and complex ideas. 4
    7 Publishing original studies in peer-reviewed journals. -
    8 To be able to develop original ideas and methods related to the field and interdisciplinary by using high level mental processes such as creative and questioning thinking, problem solving and decision making -
    9 To be able to present their original views effectively in a professional community. -
    10 To be able to communicate and discuss in at least one foreign language at an advanced level, written, oral and visual. -
    11 To contribute to the process of becoming an information society by introducing technological advances in academic and professional contexts. -
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