Magnetically propelled microwheels for rapid thrombolysis in small arteries

Information

  • Research Project
  • 9941152
  • ApplicationId
    9941152
  • Core Project Number
    R01NS102465
  • Full Project Number
    5R01NS102465-03
  • Serial Number
    102465
  • FOA Number
    PA-16-160
  • Sub Project Id
  • Project Start Date
    7/1/2018 - 6 years ago
  • Project End Date
    3/31/2023 - a year ago
  • Program Officer Name
    KOENIG, JAMES I
  • Budget Start Date
    4/1/2020 - 4 years ago
  • Budget End Date
    3/31/2021 - 3 years ago
  • Fiscal Year
    2020
  • Support Year
    03
  • Suffix
  • Award Notice Date
    3/30/2020 - 4 years ago

Magnetically propelled microwheels for rapid thrombolysis in small arteries

Project Summary: In small vessel stroke (SVS), which accounts for 20% of ischemic strokes, tissue plasminogen activator (tPA) is ineffective because it can take a prohibitively long time to diffuse to the clot, and catheter-based thrombectomy devices cannot access small vessels. Moreover, treatment associated hemorrhaging limits tPA use to within a few hours of the onset of symptoms for all ischemic strokes. As a result, there is an urgent need for strategies that overcome these limitations, particularly in SVS, while reducing the risks associated with tPA. Building on a successful previous work, a drug delivery strategy is proposed that can selectively target small artery occlusions and deliver mechanical force to accelerate thrombolysis. The objective of this proposal is to investigate and test within realistic models an approach where injected, dispersed magnetic beads are assembled into blood cell sized microwheels (µwheels) capable of targeting occlusive clots located in small vessels and lysing them with a combination of mechanical and biochemical action. The central hypothesis is that µwheels can (i) target occluded small arteries by exploiting the low flow regions at the entrance of these vessels, (ii) achieve reperfusion at rates an order-of-magnitude faster than soluble tPA, and (iii) improve outcomes in murine models of stroke. This hypothesis will be tested with the following specific aims: Aim 1. Identify magnetic field conditions for µwheels targeting of occlusions. µWheels will be assembled in flowing blood and directed to occluded channels or vessels. Microfluidic, zebrafish, and 3D human cerebrovascular models will be used to test the assembly and targeting. Aim 2. Determine rates for thrombolysis of occlusive thrombi using tPA functionalized µwheels. It is postulated that tPA functionalized µwheels can dissolve fibrin- and platelet-rich clots within microfluidic models and achieve reperfusion in zebrafish and 3D human cerebrovascular models, at rates significantly faster than soluble tPA. Aim 3. Measure the functional benefit of µwheel thrombolysis in vivo. In comparison to soluble tPA, µwheel mediated thrombolysis will improve safety, motor, and neurological outcomes in murine stroke models and can be visualized using high-resolution MRI and micro-CT. In Aims 1 and 2 the expected outcomes are identifying the operating conditions for µwheel assembly, targeting, and fibrinolysis that provide faster reperfusion compared to tPA and can be scaled-up to human-size vascular networks. In Aim 3, it will be shown that µwheel thrombolysis is a superior strategy to systemic administration of tPA in terms of neurobehavioral outcomes in a stroke model and can be imaged in vivo. This approach is significant because it could lead to the development of a more rapid and less invasive strategy for alleviating ischemia than methods currently available. This approach is innovative because of the use of external magnetic fields to propel fibrinolytic microdevices to the sites of occlusion and provide mechanical action to accelerate reperfusion time compared to systemic administration of tPA.

IC Name
NATIONAL INSTITUTE OF NEUROLOGICAL DISORDERS AND STROKE
  • Activity
    R01
  • Administering IC
    NS
  • Application Type
    5
  • Direct Cost Amount
    394811
  • Indirect Cost Amount
    102927
  • Total Cost
    497738
  • Sub Project Total Cost
  • ARRA Funded
    False
  • CFDA Code
    853
  • Ed Inst. Type
    SCHOOLS OF ARTS AND SCIENCES
  • Funding ICs
    NINDS:497738\
  • Funding Mechanism
    Non-SBIR/STTR RPGs
  • Study Section
    ISD
  • Study Section Name
    Instrumentation and Systems Development Study Section
  • Organization Name
    COLORADO SCHOOL OF MINES
  • Organization Department
    ENGINEERING (ALL TYPES)
  • Organization DUNS
    010628170
  • Organization City
    GOLDEN
  • Organization State
    CO
  • Organization Country
    UNITED STATES
  • Organization Zip Code
    804011887
  • Organization District
    UNITED STATES