Creating a Novel Mathematical Model of the Kv10.1 Ion Channel and Controlling Channel Activity with Nanoelectromechanical Systems
Апстракт
Featured Application Nanoelectromechanical systems and nanorobots can be used to treat cancers associated with the Kv10.1 voltage-gated ion channel activity. The Kv10.1 model was developed by applying the control engineering theory. Nanoelectromechanical systems play the role of a PID regulator. The use of nanoelectromechanical systems or nanorobots offers a new concept for sensing and controlling subcellular structures, such as ion channels. We present here a novel method for mathematical modeling of ion channels based on control system theory and system identification. We investigated the use of nanoelectromechanical devices to control the activity of ion channels, particularly the activity of the voltage-gated ion channel Kv10.1, an important channel in cancer development and progression. A mathematical model of the dynamic behavior of the selected ion channel Kv10.1 in the Laplace (s) domain was developed, which is given in the representation of a transfer function. In addition, we... addressed the possibilities of controlling ion channel activity by nanoelectromechanical devices and nanorobots and finally presented a control algorithm for the Kv10.1 as a control object. A use case demonstrates the potential of a Kv10.1 controlled nanorobot for cancer treatment at a single-cell level.
Кључне речи:
system identification / nanorobots / nanoelectromechanical system (NEMS) / mathematical modeling / ion channel Kv10 / control algorithmИзвор:
Applied Sciences-Basel, 2022, 12, 8Издавач:
- MDPI, Basel
Финансирање / пројекти:
- Graz University of Technology
DOI: 10.3390/app12083836
ISSN: 2076-3417
WoS: 000786829600001
Scopus: 2-s2.0-85128808296
Институција/група
Inovacioni centarTY - JOUR AU - Lozanović Šajić, Jasmina AU - Langthaler, Sonja AU - Baumgartner, Christian PY - 2022 UR - https://machinery.mas.bg.ac.rs/handle/123456789/3694 AB - Featured Application Nanoelectromechanical systems and nanorobots can be used to treat cancers associated with the Kv10.1 voltage-gated ion channel activity. The Kv10.1 model was developed by applying the control engineering theory. Nanoelectromechanical systems play the role of a PID regulator. The use of nanoelectromechanical systems or nanorobots offers a new concept for sensing and controlling subcellular structures, such as ion channels. We present here a novel method for mathematical modeling of ion channels based on control system theory and system identification. We investigated the use of nanoelectromechanical devices to control the activity of ion channels, particularly the activity of the voltage-gated ion channel Kv10.1, an important channel in cancer development and progression. A mathematical model of the dynamic behavior of the selected ion channel Kv10.1 in the Laplace (s) domain was developed, which is given in the representation of a transfer function. In addition, we addressed the possibilities of controlling ion channel activity by nanoelectromechanical devices and nanorobots and finally presented a control algorithm for the Kv10.1 as a control object. A use case demonstrates the potential of a Kv10.1 controlled nanorobot for cancer treatment at a single-cell level. PB - MDPI, Basel T2 - Applied Sciences-Basel T1 - Creating a Novel Mathematical Model of the Kv10.1 Ion Channel and Controlling Channel Activity with Nanoelectromechanical Systems IS - 8 VL - 12 DO - 10.3390/app12083836 ER -
@article{ author = "Lozanović Šajić, Jasmina and Langthaler, Sonja and Baumgartner, Christian", year = "2022", abstract = "Featured Application Nanoelectromechanical systems and nanorobots can be used to treat cancers associated with the Kv10.1 voltage-gated ion channel activity. The Kv10.1 model was developed by applying the control engineering theory. Nanoelectromechanical systems play the role of a PID regulator. The use of nanoelectromechanical systems or nanorobots offers a new concept for sensing and controlling subcellular structures, such as ion channels. We present here a novel method for mathematical modeling of ion channels based on control system theory and system identification. We investigated the use of nanoelectromechanical devices to control the activity of ion channels, particularly the activity of the voltage-gated ion channel Kv10.1, an important channel in cancer development and progression. A mathematical model of the dynamic behavior of the selected ion channel Kv10.1 in the Laplace (s) domain was developed, which is given in the representation of a transfer function. In addition, we addressed the possibilities of controlling ion channel activity by nanoelectromechanical devices and nanorobots and finally presented a control algorithm for the Kv10.1 as a control object. A use case demonstrates the potential of a Kv10.1 controlled nanorobot for cancer treatment at a single-cell level.", publisher = "MDPI, Basel", journal = "Applied Sciences-Basel", title = "Creating a Novel Mathematical Model of the Kv10.1 Ion Channel and Controlling Channel Activity with Nanoelectromechanical Systems", number = "8", volume = "12", doi = "10.3390/app12083836" }
Lozanović Šajić, J., Langthaler, S.,& Baumgartner, C.. (2022). Creating a Novel Mathematical Model of the Kv10.1 Ion Channel and Controlling Channel Activity with Nanoelectromechanical Systems. in Applied Sciences-Basel MDPI, Basel., 12(8). https://doi.org/10.3390/app12083836
Lozanović Šajić J, Langthaler S, Baumgartner C. Creating a Novel Mathematical Model of the Kv10.1 Ion Channel and Controlling Channel Activity with Nanoelectromechanical Systems. in Applied Sciences-Basel. 2022;12(8). doi:10.3390/app12083836 .
Lozanović Šajić, Jasmina, Langthaler, Sonja, Baumgartner, Christian, "Creating a Novel Mathematical Model of the Kv10.1 Ion Channel and Controlling Channel Activity with Nanoelectromechanical Systems" in Applied Sciences-Basel, 12, no. 8 (2022), https://doi.org/10.3390/app12083836 . .