Study on the intervention of platelet biological activity by ultrasound_Journal of Biomedical Engineering

Authors：

LIU Taotao ,  YANG Fang

Jiangsu Key Laboratory for Biomaterials and Devices, State Key Laboratory of Bioelectronics, School of Biological Sciences and Medical Engineering, Southeast University, Nanjing 210096, P.R.China;

Corresponding author：

YANG Fang, Email: yangfang2080@seu.edu.cn

Keywords：

platelets; ultrasound; platelet components; bioactivity; aggregation

DOI：

10.7507/1001-5515.202005036

Video：

Export PDF Favorites Scan Get Citation

Abstract Full text Figures/Tables Video References Cited by

Platelets are non-nucleated blood effector cells, which plays an important role in coagulation, hemostasis, and thrombosis. However, platelets are extremely susceptible to activation by external stimuli, which in turn damages the platelet’s natural biological activity and affects its biological function. Platelet biological activity has become a hotspot in the field of vascular diseases. In this study, ultrasound parameters (ultrasound intensity and duration time) were used to intervene in the biological activity of platelets. The response of platelets to ultrasound energy was explored from the aspects of platelet morphology, aggregation ability and particle release (the expression of P-selectin and the number of particles). The results showed that the ultrasound intensity of 0.25 W/cm² (1 MHz, 60 s) had no effect on the morphology, aggregation ability and particle release of platelets. When the ultrasonic intensity was increased to greater than 0.25 W/cm², the generation of platelet pseudopods, morphological changes, increase of particle release, as well as effect on aggregation were observed. When the ultrasound duration time was 60 s (1 MHz, 0.25 W/cm²), it had no effect on the biological activity of platelets. However, when the ultrasound time was greater than 60 s, the morphology, aggregation ability and microparticles release would been induced with no effect on the secretion of CD62P and total protein components. Therefore, when the ultrasound parameters were 1 MHz and 0.25 W/cm² with 60 s duration time, the ultrasound energy had no effect on the biological activity of platelets. The results in this study are of great significant for ultrasound energy intervention for the treatment of platelet-related diseases.

Citation： LIU Taotao, YANG Fang. Study on the intervention of platelet biological activity by ultrasound. Journal of Biomedical Engineering, 2021, 38(4): 709-715. doi: 10.7507/1001-5515.202005036 Copy

1.	Zhou M, Wang H, Zeng X, et al. Mortality, morbidity, and risk factors in China and its provinces, 1990-2017: a systematic analysis for the Global Burden of Disease Study 2017. Lancet, 2019, 394(10204): 1145-1158.
2.	Tan X, Liu X, Shao H. Healthy China 2030: a vision for health care. Value Health Reg Issues, 2017, 12: 112-114.
3.	陈小凤, 卫娟, 赵峰. 凝血功能检验对心脑血管疾病患者预后中的判断价值分析. 心理医生, 2015, 21(12): 70-71.
4.	王禹. 平均血小板体积在心血管病诊疗中的临床意义. 中国心血管病研究, 2018, 16(1): 22-26.
5.	Holinstat M. Normal platelet function. Cancer Metastasis Rev, 2017, 36(2): 1-4.
6.	Rana A, Westein E, Niego B, et al. Shear-dependent platelet aggregation: mechanisms and therapeutic opportunities. Front Cardiovasc Med, 2019, 6: 1-8.
7.	Yeung J, Li W J, Holinstat M. Platelet signaling and disease: targeted therapy for thrombosis and other related diseases. Pharmacol Rev, 2018, 70(3): 526-548.
8.	Brass L F, Newman D K, Wannermacher K M, et al. Signal transduction during platelet plug formation. Platelets, 2013, 58: 367-398.
9.	Tomaiuolo M, Brass L F, Stalker T J. Regulation of platelet activation and coagulation and its role in vascular injury and arterial thrombosis. Intervent Cardiol Clin, 2017, 6(1): 1-12.
10.	van der Meijden P E J, Heemskerk J W M. Platelet biology and functions: new concepts and clinical perspectives. Nat Rev Cardiol, 2019, 16(3): 166-179.
11.	李丽. 血小板相关参数在早发冠心病冠脉病变中的临床意义及预测价值. 合肥: 安徽医科大学, 2016.
12.	阎蓉, 林靓, 孙慧韦. 促血小板生成素和平均血小板体积在2型糖尿病合并心血管疾病中的意义. 医学研究杂志, 2016, 45(10): 128-131.
13.	Koupenova M, Clancy L, Corkrey H A, et al. Circulating platelets as mediators of immunity, inflammation and thrombosis. Circ Res, 2018, 122(2): 337-351.
14.	刘威. 超声引导下经皮血管成形术治疗血透患者动静脉内瘘狭窄的疗效分析. 中国超声医学杂志, 2021, 37(2): 210-213.
15.	孙厚启. 超声介入在治疗血管外科疾病中的应用现状. 血管与腔内血管外科杂志, 2018, 4(2): 163-168.
16.	温尚煜. 血管内超声指导下零对比剂行经皮冠状动脉介入治疗. 中国介入心脏病学杂志, 2021, 29(1): 55-57.
17.	高重阳. 基于活动轮廓模型的血管内超声序列图像边缘提取研究. 西安: 西安科技大学, 2010.
18.	欧阳竹. 术中超声辅助颅内血管性疾病的外科治疗研究. 中国现代医学杂志, 2012, 22(10): 79-82.
19.	Perren F, Hom P, Kern R, et al. A rapid noninvasive method to visualize ruptured aneurysms in the emergency room: three-dimensional power Doppler imaging. J. Neurosurg, 2004, 100(4): 619-622.
20.	葛志通. 超声介入治疗在血管疾病中的应用. 协和医学杂志, 2020, 11(1): 62-67.
21.	栾烁, 栗晓, 林彩娜, 等. 超声引导下关节腔注射富血小板血浆治疗膝骨性关节炎疗效的回顾性研究. 中山大学, 2020, 35(5): 568-573.
22.	Moore K J, Tabas I. The cellular biology of macrophages in atherosclerosis. Cell, 2011, 145(3): 341-355.
23.	Sun X, Xu H, Shen J, et al. Real-time detection of intracellular reactive oxygen species and mitochondrial membrane potential in THP-1 macrophages during ultrasonic irradiation for optimal sonodynamic therapy. Ultrason Sonochem, 2015, 22: 7-14.
24.	吕铭, 陈雷. 浅析医学超声治疗技术及其应用. 中国医疗器械信息, 2017, 23(13): 33-34.
25.	Stief T W, Klingmüller V. The ultrasound frequency determines the degree of intrinsic coagulation activation. Blood Coagul. Fibrinolysis, 2012, 23(5): 440-444.
26.	Jin J, Liu T T, Li M X, et al. Rapid in situ biosynthesis of gold nanoparticles in living platelets for multimodal biomedical imaging. Colloids Surf B, 2018, 163: 385-393.
27.	Liu T T, Li M X, Tang J, et al. An acoustic strategy for gold nanoparticle loading in platelets as biomimetic multifunctional carriers. J Mat Chem B, 2019, 7: 2138-2144.

1. Zhou M, Wang H, Zeng X, et al. Mortality, morbidity, and risk factors in China and its provinces, 1990-2017: a systematic analysis for the Global Burden of Disease Study 2017. Lancet, 2019, 394(10204): 1145-1158.
2. Tan X, Liu X, Shao H. Healthy China 2030: a vision for health care. Value Health Reg Issues, 2017, 12: 112-114.
3. 陈小凤, 卫娟, 赵峰. 凝血功能检验对心脑血管疾病患者预后中的判断价值分析. 心理医生, 2015, 21(12): 70-71.
4. 王禹. 平均血小板体积在心血管病诊疗中的临床意义. 中国心血管病研究, 2018, 16(1): 22-26.
5. Holinstat M. Normal platelet function. Cancer Metastasis Rev, 2017, 36(2): 1-4.
6. Rana A, Westein E, Niego B, et al. Shear-dependent platelet aggregation: mechanisms and therapeutic opportunities. Front Cardiovasc Med, 2019, 6: 1-8.
7. Yeung J, Li W J, Holinstat M. Platelet signaling and disease: targeted therapy for thrombosis and other related diseases. Pharmacol Rev, 2018, 70(3): 526-548.
8. Brass L F, Newman D K, Wannermacher K M, et al. Signal transduction during platelet plug formation. Platelets, 2013, 58: 367-398.
9. Tomaiuolo M, Brass L F, Stalker T J. Regulation of platelet activation and coagulation and its role in vascular injury and arterial thrombosis. Intervent Cardiol Clin, 2017, 6(1): 1-12.
10. van der Meijden P E J, Heemskerk J W M. Platelet biology and functions: new concepts and clinical perspectives. Nat Rev Cardiol, 2019, 16(3): 166-179.
11. 李丽. 血小板相关参数在早发冠心病冠脉病变中的临床意义及预测价值. 合肥: 安徽医科大学, 2016.
12. 阎蓉, 林靓, 孙慧韦. 促血小板生成素和平均血小板体积在2型糖尿病合并心血管疾病中的意义. 医学研究杂志, 2016, 45(10): 128-131.
13. Koupenova M, Clancy L, Corkrey H A, et al. Circulating platelets as mediators of immunity, inflammation and thrombosis. Circ Res, 2018, 122(2): 337-351.
14. 刘威. 超声引导下经皮血管成形术治疗血透患者动静脉内瘘狭窄的疗效分析. 中国超声医学杂志, 2021, 37(2): 210-213.
15. 孙厚启. 超声介入在治疗血管外科疾病中的应用现状. 血管与腔内血管外科杂志, 2018, 4(2): 163-168.
16. 温尚煜. 血管内超声指导下零对比剂行经皮冠状动脉介入治疗. 中国介入心脏病学杂志, 2021, 29(1): 55-57.
17. 高重阳. 基于活动轮廓模型的血管内超声序列图像边缘提取研究. 西安: 西安科技大学, 2010.
18. 欧阳竹. 术中超声辅助颅内血管性疾病的外科治疗研究. 中国现代医学杂志, 2012, 22(10): 79-82.
19. Perren F, Hom P, Kern R, et al. A rapid noninvasive method to visualize ruptured aneurysms in the emergency room: three-dimensional power Doppler imaging. J. Neurosurg, 2004, 100(4): 619-622.
20. 葛志通. 超声介入治疗在血管疾病中的应用. 协和医学杂志, 2020, 11(1): 62-67.
21. 栾烁, 栗晓, 林彩娜, 等. 超声引导下关节腔注射富血小板血浆治疗膝骨性关节炎疗效的回顾性研究. 中山大学, 2020, 35(5): 568-573.
22. Moore K J, Tabas I. The cellular biology of macrophages in atherosclerosis. Cell, 2011, 145(3): 341-355.
23. Sun X, Xu H, Shen J, et al. Real-time detection of intracellular reactive oxygen species and mitochondrial membrane potential in THP-1 macrophages during ultrasonic irradiation for optimal sonodynamic therapy. Ultrason Sonochem, 2015, 22: 7-14.
24. 吕铭, 陈雷. 浅析医学超声治疗技术及其应用. 中国医疗器械信息, 2017, 23(13): 33-34.
25. Stief T W, Klingmüller V. The ultrasound frequency determines the degree of intrinsic coagulation activation. Blood Coagul. Fibrinolysis, 2012, 23(5): 440-444.
26. Jin J, Liu T T, Li M X, et al. Rapid in situ biosynthesis of gold nanoparticles in living platelets for multimodal biomedical imaging. Colloids Surf B, 2018, 163: 385-393.
27. Liu T T, Li M X, Tang J, et al. An acoustic strategy for gold nanoparticle loading in platelets as biomimetic multifunctional carriers. J Mat Chem B, 2019, 7: 2138-2144.

Journal of Biomedical Engineering

Study on the intervention of platelet biological activity by ultrasound

Abstract Full text Figures/Tables Video References Cited by

Previous Article

Next Article

Format

Content