A simulation model is a testing model, that mimics the operation of an existing or proposed system, providing evidence for decision-making by being able to test different scenarios or process changes. Trackability refers to the measurement of the force required to advance the device through a tortuous anatomy with or without the assistance of a guiding accessory such as a guide wire and guide catheter. Simulation is becoming increasingly important in medical device development, because its main objective is to lower the development cost by improving device’s performance and dependability, eliminating bench top tests clinical trials, and accelerating the regulatory approval process. It could be challenging to compare the performance of several devices because each manufacturer might employ a different “Simulated Neurovascular Model”. To reduce the risk of device failure and patient's injury during clinical use, it is important to adequately examine these devices. As a result, “Simulated Neurovascular Model”" is used in the present work, to understand the performance of testing for 'Intravascular devices' meant to access the 'Neurovasculature'. This test process intends to examine or determine the trackability of “Intracranial Aneurysm Flow Diverter System” by using” “Simulated Neurovascular Model”. A flow diversion operation is used to treat a number of unruptured brain aneurysms. Sterilized “Intracranial Aneurysm Flow Diverter Stent” samples are used in the present research work.
| Published in | International Journal of Medical Imaging (Volume 11, Issue 2) |
| DOI | 10.11648/j.ijmi.20231102.14 |
| Page(s) | 42-45 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Simulated Neurovascular Model, Intracranial Aneurysm Flow Diverter System, Trackability Test
| [1] | ISO 25539: 2012. |
| [2] | Kenny S., and McDermott E. Simulated Testing in Medical Device Design. Medical Device Technology. 2006. |
| [3] | Xiang Nian -de, Wang Shi-ying, and Yu Er-keng. A New Approach for Detection and Identification of Multiple Bad Data in Power System State Estimation. IEEE Transactions on Power Apparatus and Systems. PAS-101 (2). |
| [4] | Swan Melanie. Emerging patient driven health care models: An examination of health social networks, consumer personalized medicine and quantified self tracking. International Journal of Environment Research in Public Health. 2009; 6 (2): 492-525. |
| [5] | Schmidt W., Behrens P., Wunderlich C. B., Siewert S., Grabow N., and Schmitz K. P. In vitro performance investigation of bioresorbable scaffold-standard tests for vascular stents and beyond. Cardiovascular Revascularization Medicine. 2016; 17 (6): 375-383. |
| [6] | Norris N. G., Merritt W. C., and Becker T. A. Application of non destructive mechanical characterization testing for creating in vitro vessel models with material properties similar to human neurovasculature. Journal of Biomedical Materials Research Part A. 2021. 110 (3): 612-622. |
| [7] | Srinivasan V. S., Chen S. R., Camstra K. M. Chintalapani G., and Kan P. Development of a recalcitrant, large clot burden, bifurcation occlusion model for mechanical thrombectomy. 2017; 42 (4): E6. |
| [8] | Takashima K., Yoshinaka A. O. K., Ohta M., Koji M., and Toma Naoki. Evaluation of the effect of catheter on the guidewire motion in a blood vessel model by physical and numerical simulations. Journal of Biomechanical Science and Engineering. 2017; 12 (4); 17-00181. |
| [9] | Barry M. M., Shayan M., Jankowitz B. T., Chen Y., Duan X., Robertson A. M., Chyu M. K., and Chun Y. Smart Guide wires for smooth navigation in Neurovascular Intervention. Journal of Medical Devices. 2015; 9 (1): 011011 (9 pages). |
| [10] | Saleeb A. F., Dhakal B., and Danquah J. S. On the role of SMA modeling in simulating NiTinol self expanding stenting surgeries to assess the performance characteristics of mechanical and thermal activation schemes. Journal of the mechanical behaviour of biomedical materials. 2015; 49: 43-60. |
| [11] | Kerrien E., Yureidini A., Dequidt J., Duriez C., Anxionnat R., and Cotin S. Blood vessel modeling for interactive simulation of interventional neuroradiology procedures. Medical Image Analysis. 2017; 35: 685-698. |
| [12] | Berczeli M., Chinnadurai P., Legeza P. T., Britz G. W., and Lumsden A. B. Transcarotid access for remote robotic endovascular neuro interventions: a cadaveric proof of concept study. 2021; 52 (1): E18. |
| [13] | Nasser A., Fourman M. S., Gersch R. P., Phillips B. T., Hsi H. K., Khan S. U., Gelfand M. A., Dagum A. B., and Bui D. T. Utilizing Indocyanine Green Dye Angiography to detect simulated flap venous congestion in a Novel Experimental Rat Model. Journal of Reconstructive Microsurgery. 2015; 31 (08): 590-596. |
| [14] | Pouliart N., and Gagey O. Simulated humeral avulsion of the glenohumeral liggaments: A new instability model. Journal of Shoulder and Elbow Surgery. 2006: 15 (6): 728-735. |
| [15] | Bjornsson C. S., Oh S. J., Kofahi Y. A. Al., Lim Y. J., Smith K. L., Turner J. N., De S., Roysam B., Shain W., and Kim S. J. Effect of insertion conditions on tissue strain and vascular damage during neuro prosthetic device insertion. Journal of Neural Engineering. 2006; 3 (3). |
| [16] | Kohn B., Honarvar M., Darvish K., and Hutapea Parsaoran. Simulation and experimental studies in needle tissue interactions. Journal of Clinical Monitoring and Computing. 2017; 31: 861-872. |
APA Style
Minocha Pramod Kumar, Kothwala Deveshkumar Mahendralal, Shaikh Amirhamzah Mahmadiqbal, Patel Chirag Jitubhai. (2023). Evaluation of Trackability Test Method for Intracranial Aneurysm Flow Diverter System Using Simulated Neurovascular Model. International Journal of Medical Imaging, 11(2), 42-45. https://doi.org/10.11648/j.ijmi.20231102.14
ACS Style
Minocha Pramod Kumar; Kothwala Deveshkumar Mahendralal; Shaikh Amirhamzah Mahmadiqbal; Patel Chirag Jitubhai. Evaluation of Trackability Test Method for Intracranial Aneurysm Flow Diverter System Using Simulated Neurovascular Model. Int. J. Med. Imaging 2023, 11(2), 42-45. doi: 10.11648/j.ijmi.20231102.14
AMA Style
Minocha Pramod Kumar, Kothwala Deveshkumar Mahendralal, Shaikh Amirhamzah Mahmadiqbal, Patel Chirag Jitubhai. Evaluation of Trackability Test Method for Intracranial Aneurysm Flow Diverter System Using Simulated Neurovascular Model. Int J Med Imaging. 2023;11(2):42-45. doi: 10.11648/j.ijmi.20231102.14
Share This Article
Twitter
Linked In
Facebook
Copy
Download@article{10.11648/j.ijmi.20231102.14,
author = {Minocha Pramod Kumar and Kothwala Deveshkumar Mahendralal and Shaikh Amirhamzah Mahmadiqbal and Patel Chirag Jitubhai},
title = {Evaluation of Trackability Test Method for Intracranial Aneurysm Flow Diverter System Using Simulated Neurovascular Model},
journal = {International Journal of Medical Imaging},
volume = {11},
number = {2},
pages = {42-45},
doi = {10.11648/j.ijmi.20231102.14},
url = {https://doi.org/10.11648/j.ijmi.20231102.14},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.ijmi.20231102.14},
abstract = {A simulation model is a testing model, that mimics the operation of an existing or proposed system, providing evidence for decision-making by being able to test different scenarios or process changes. Trackability refers to the measurement of the force required to advance the device through a tortuous anatomy with or without the assistance of a guiding accessory such as a guide wire and guide catheter. Simulation is becoming increasingly important in medical device development, because its main objective is to lower the development cost by improving device’s performance and dependability, eliminating bench top tests clinical trials, and accelerating the regulatory approval process. It could be challenging to compare the performance of several devices because each manufacturer might employ a different “Simulated Neurovascular Model”. To reduce the risk of device failure and patient's injury during clinical use, it is important to adequately examine these devices. As a result, “Simulated Neurovascular Model”" is used in the present work, to understand the performance of testing for 'Intravascular devices' meant to access the 'Neurovasculature'. This test process intends to examine or determine the trackability of “Intracranial Aneurysm Flow Diverter System” by using” “Simulated Neurovascular Model”. A flow diversion operation is used to treat a number of unruptured brain aneurysms. Sterilized “Intracranial Aneurysm Flow Diverter Stent” samples are used in the present research work.},
year = {2023}
}
TY - JOUR T1 - Evaluation of Trackability Test Method for Intracranial Aneurysm Flow Diverter System Using Simulated Neurovascular Model AU - Minocha Pramod Kumar AU - Kothwala Deveshkumar Mahendralal AU - Shaikh Amirhamzah Mahmadiqbal AU - Patel Chirag Jitubhai Y1 - 2023/06/09 PY - 2023 N1 - https://doi.org/10.11648/j.ijmi.20231102.14 DO - 10.11648/j.ijmi.20231102.14 T2 - International Journal of Medical Imaging JF - International Journal of Medical Imaging JO - International Journal of Medical Imaging SP - 42 EP - 45 PB - Science Publishing Group SN - 2330-832X UR - https://doi.org/10.11648/j.ijmi.20231102.14 AB - A simulation model is a testing model, that mimics the operation of an existing or proposed system, providing evidence for decision-making by being able to test different scenarios or process changes. Trackability refers to the measurement of the force required to advance the device through a tortuous anatomy with or without the assistance of a guiding accessory such as a guide wire and guide catheter. Simulation is becoming increasingly important in medical device development, because its main objective is to lower the development cost by improving device’s performance and dependability, eliminating bench top tests clinical trials, and accelerating the regulatory approval process. It could be challenging to compare the performance of several devices because each manufacturer might employ a different “Simulated Neurovascular Model”. To reduce the risk of device failure and patient's injury during clinical use, it is important to adequately examine these devices. As a result, “Simulated Neurovascular Model”" is used in the present work, to understand the performance of testing for 'Intravascular devices' meant to access the 'Neurovasculature'. This test process intends to examine or determine the trackability of “Intracranial Aneurysm Flow Diverter System” by using” “Simulated Neurovascular Model”. A flow diversion operation is used to treat a number of unruptured brain aneurysms. Sterilized “Intracranial Aneurysm Flow Diverter Stent” samples are used in the present research work. VL - 11 IS - 2 ER -
Information
Email: