Journal of Space Science and Technology

Journal of Space Science and Technology

Evaluating Optimal Ultrasound to Deform the Blood Clot in a Vessel for Astronauts Health

Document Type : Original Research Paper

Authors
Ramin Kamalimoghadam 1
Mahmoud Najafi 2
Masoomeh Azadegan 3
Nasrin Sahranavardfar 4
1 Aerospace Research Institute, Ministry of Science, Research and Technology, Tehran, Iran
2 Department of Mathematical Sciences, Kent State University, Ohio, USA
3 Department of Electrical Engineering, Khatam University, Tehran, Iran
4 Department of Engineering, University of Perugia, Perugia, Italy
10.22034/jsst.2025.1519
Abstract
Formation of blood clot in the astronaut veins in space may have dangerous consequences. In the absence of gravity, body fluids shift from the legs to the upper body and the head. This shift affects the flow of blood through the vessels in the head. Removing of the blood clot in the vessels in space may help astronauts’ health. Although using the medicine to remove the blood clot in the vein, it can be applied just for very small size. When the blood clot is large, using the ultrasonic waves with making small bubbles may be a useful method to remove the blood clots in the veins. The goal of the present paper is to gain an optimal intensity of ultrasound to achieve required pressure field generated by the collapsing bubble in blood to deform blood clots. The collapse pressure within the bubble has been calculated using Rayleigh–Plesset (RP) equation. Moreover, a coupling simulation of the flow and clot structure is performed using the full Navier-Stokes equations, which governs the blood domain, and linearized discrete equations for the clot medium to calculate the desired bubble collapsing pressure necessary to deform the clots, which has immense importance in medical applications. Simulation results are presented to show the effectiveness of the proposed method. Using the captured results, one can find the optimum ultrasound frequency for clot fragment. It can be useful for an astronaut to use the ultrasonic waves to remove some clots in the vein, treat and get back the health.
Keywords
Bubble dynamic
Ultrasound control
3D CFD
Blood clot deformation
Astronauts health

Subjects

Article Title Persian

ارزیابی شدت بهینه امواج اولتراسوند برای تغییر شکل لخته خون در رگ‌ها به منظور سلامت فضانوردان

Authors Persian

رامین کمالی مقدم 1
محمود نجفی 2
معصومه آزادگان 3
نسرین صحرانورد فر 4
1 پژوهشگاه هوافضا
2 گروه علوم ریاضی، دانشگاه ایالتی کنت، اوهایو، ایالات متحده آمریکا
3 دانشکده مهندسی برق، دانشگاه خاتم، تهران، ایران
4 دانشکده مهندسی، دانشگاه پروجا، پروجا، ایتالیا
Abstract Persian

تشکیل لخته خون در رگ‌های فضانوردان در فضا می‌تواند پیامدهای خطرناکی به همراه داشته باشد. در نبود گرانش، مایعات بدن از پاها به سمت سینه و سر منتقل می‌شوند. این جابه‌جایی بر جریان خون در شریان‌ها و رگ‌های سر تأثیر می‌گذارد. خارج‌سازی لخته خون در رگ‌های فضایی می‌تواند به بهبود سلامت فضانوردان کمک کند. هرچند استفاده از دارو برای از بین بردن لخته خون در ورید فقط برای اندازه‌های بسیار کوچک کاربرد دارد. زمانی که لخته خون بزرگ است، استفاده از امواج اولتراسوند با ایجاد حباب‌های کوچک می‌تواند روشی مفید برای از بین بردن لخته‌ها در رگ‌ها باشد. هدف مقاله حاضر دستیابی به شدت بهینه امواج اولتراسوند است تا با ایجاد میدان فشار لازم ناشی از فروپاشی حباب در خون، لخته‌ها را تغییر شکل دهد. فشار فروپاشی درون حباب با استفاده از معادله Rayleigh–Plesset (RP) محاسبه شده است. علاوه بر این، یک شبیه‌سازی هم‌پیوندی جریان و ساختار لخته با استفاده از معادلات کامل ناویه-استوکس که حوزه خون را می‌سازند و معادلات گسسته خطی‌شده برای محیط لخته برای محاسبه فشار فروپاشی مطلوب حباب که برای تغییر شکل لخته‌ها ضروری است، انجام می‌شود؛ که این امر در کاربردهای پزشکی اهمیت بالایی دارد. نتایج شبیه‌سازی برای نشان دادن کارایی روش پیشنهادی ارائه می‌شود.

Keywords Persian

دینامیک حباب
کنترل امواج اولتراسوند
دینامیک سیالات محاسبه شده سه‌بعدی
تغییر شکل لخته خون
سلامت فضانوردان
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Journal of Space Science and Technology
Volume 18, Issue 4
2025
Pages 22-31

  • Receive Date 11 January 2025
  • Revise Date 02 August 2025
  • Accept Date 09 August 2025
  • First Publish Date 02 September 2025