Focused High/Low Intensity Ultrasound System for Minimally Invasive Inside Body Bio Printing and Drug Delivery

用于微创体内生物打印和药物输送的聚焦高/低强度超声系统

• 批准号: RTI-2022-00615
• 负责人: Packirisamy, Muthukumaran
• 金额: $ 10.93万
• 依托单位: Concordia University
• 依托单位国家: 加拿大
• 项目类别: Research Tools and Instruments
• 财政年份: 2021
• 资助国家: 加拿大
• 起止时间: 2021-01-01 至 2022-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=742980
• 关键词: Focused; Low; Intensity; Ultrasound; System

Even though Concordia University houses various state-of-the-art research facilities, a number of crucial studies initiated and patented from our lab in the areas of inside body bio printing, noninvasive cell stimulation and drug delivery using ultrasound waves are currently limited due to the dire need for a highly specialized ultrasound beam steering and focusing. Such equipment would enhance ongoing research on developing cutting edge technologies in the area of remote tissue printing and noninvasive nano particle synthesis and drug delivery. The supported research programs includes but limited to: 1)Micro particle and cell manipulation/stimulation, 2) Selective nano particle synthesis, 3) Micro particle and cell streaming control and 4) In-situ/in-vitro bio printing and drug delivery. The Phased Array High Intensity Focused Ultrasound Transducer from Sonicconcepts enables our research group to conduct research on the mentioned programs. Having 128 piezo actuator provides a wide range of ultrasound beam steering and focusing capabilities. No similar equipment is available at Concordia or known partner institutions. Acquiring this equipment would not only advance effective collaboration between engineers, biologists and physicists for future convergence but would also sustain leading-edge research success, strengthen training goals, enhance quality of dissertations, and shorten graduation time. We currently have 25 graduate students and 5 postdocs working on the mentioned research programs. They have mastered the theory and conducted multiphysics simulations related to the ultrasound wave patterning. In addition to conducting cutting edge research, the equipment enables them to validate their modeling and simulations. In addition, we believe that the collaboration of these 8 labs in multidisciplinary research and development around this equipment will lead to practical products that has huge market and a few spin-off can be resulted from universities. The collaborations between research labs around this equipment with diverse expertise, acoustic, micro/nano elector mechanical systems and head and neck cancer treatment, will manifest themselves and converge in the proposed multidisciplinary research programs. This essential research is complementary to both our engineers, physicists and physicians working in the area of microsystems, microfluidics, application of micro-nano integrated systems for bio and chemical applications and cancer treatment and tissue printing. The proposed research programs introduces new trend in bioprinting. However, the incapability of controlling the ultrasonic field electronically is a major setback. The requested equipment surmounts this obstacle by permitting electronic steering and focusing of high intensity ultrasound. Housed in the Optical-bio Microsystems Lab, the system will be open to on-site and other inter-institutional collaborations across Canada including McGill, UdeM, ETS and École Polytechnique.

尽管康科迪亚大学拥有各种最先进的研究设施，但我们实验室在体内生物打印、非侵入性细胞刺激和使用超声波的药物输送领域发起并获得专利的许多关键研究目前仍受到限制，因为对高度专业化的超声波束转向和聚焦的迫切需求将加强远程组织打印和非侵入性纳米粒子合成和药物输送领域的前沿技术的持续研究。 : 1)微粒子和细胞操纵/刺激，2) 选择性纳米粒子合成，3) 微粒和细胞流控制以及 4) 原位/体外生物打印和药物输送 Sonicconcepts 的相控阵高强度聚焦超声换能器使我们的研究小组能够对上述程序进行研究。拥有 128 个压电执行器可提供广泛的超声波束控制和聚焦功能。Concordia 或已知的合作机构没有提供类似的设备。不仅促进工程师、生物学家和物理学家之间的有效合作以实现未来的融合，而且还将维持前沿研究的成功，加强培训目标，提高论文质量，并缩短毕业时间。我们目前有 25 名研究生和 5 名博士后从事该研究。他们已经掌握了与超声波图案相关的理论并进行了多物理场模拟，除了进行前沿研究之外，这些设备还使他们能够验证他们的建模和模拟。这 8 个围绕该设备进行多学科研究和开发的实验室将带来具有巨大市场的实用产品，并且大学之间围绕该设备的不同专业知识、声学、微/纳米领域的合作可以产生一些副产品。选举机械系统和头颈癌症治疗，将在拟议的多学科研究项目中体现出来并集中起来，这项重要研究是对我们在微系统、微流体、应用领域工作的工程师、物理学家和医生的补充。用于生物和化学应用以及癌症治疗和组织打印的微纳米集成系统引入了生物打印的新趋势。然而，无法以电子方式控制超声波场是所要求的设备克服这一障碍的主要障碍。该系统位于光学生物微系统实验室，将向加拿大各地的现场和其他机构间合作开放，包括麦吉尔大学、UdeM、ETS 和综合理工学院。