Enhanced Fibrinolysis with Magnetically Powered Colloidal Microwheels

Tasci, Tonguc O.; Disharoon, Dante; Schoeman, Rogier M.; Rana, Kuldeepsinh; Herson, Paco S.; Marr, David W. M.; Neeves, Keith B.

doi:10.1002/smll.201700954

Cited by 61 publications

(88 citation statements)

References 53 publications

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“…Magnetic fields overcome these limitations as they do not attenuate in tissue for frequencies < 30 Mhz . They can also be used to concentrate PA‐laden magnetic particles at the thrombus periphery . Magnetic nanoparticles (MNP) used for fibrinolysis are made from <30‐nm superparamagnetic iron oxide crystals of magnetite (Fe 3 O 4 ) or maghemite (γ‐Fe 2 O 3 ), FDA‐approved materials with low toxicity in humans, embedded in a polymer matrix .…”

Section: Magnetic Particles and Magnetic Field Controlmentioning

confidence: 99%

“…A covalent bonding strategy is functionalization of PAA particle surfaces using N‐hydroxysuccinimide followed by coupling with tPA . Alternatively, streptavidin‐functionalized particles can be conjugated to biotinylated tPA . Such immobilization of PA protects the enzyme from inhibition by PAI‐1 and degradation in the liver.…”

Section: Magnetic Particles and Magnetic Field Controlmentioning

confidence: 99%

“…Tasci et al. demonstrated enhanced fibrinolysis using a combination of biochemical and mechanical action using magnetically powered microwheels assembled in situ . Biotinylated tPA was immobilized on 1‐μm streptavidin‐coated MNP.…”

Section: Magnetic Particles and Magnetic Field Controlmentioning

confidence: 99%

“…90 Alternatively, streptavidin-functionalized particles can be conjugated to biotinylated tPA. 74 Such immobilization of PA protects the enzyme from inhibition by PAI-1 and degradation in the liver.…”

Section: Synthesis and Functionalization Of Magnetic Nanoparticle Cmentioning

confidence: 99%

“…96 Some of the most novel MNP strategies initiate thrombolysis through both chemical and mechanical mechanisms ( Table 2) cally powered microwheels assembled in situ. 74 Biotinylated tPA was immobilized on 1-μm streptavidin-coated MNP. The microwheels rolled to the interface of a plasma clot ( Figure 3D) and accumulated tPA at this interface at a concentration 50 times higher than the injected concentration.…”

Section: Magnetic Field Control Of Magnetic Particlesmentioning

confidence: 99%

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Engineered microparticles and nanoparticles for fibrinolysis

Disharoon

Marr

Neeves

2019

Journal of Thrombosis and Haemostasis

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Fibrinolytic agents including plasmin and plasminogen activators improve outcomes in acute ischemic stroke and thrombosis by recanalizing occluded vessels. In the decades since their introduction into clinical practice, several limitations of have been identified in terms of both efficacy and bleeding risk associated with these agents. Engineered nanoparticles and microparticles address some of these limitations by improving circulation time, reducing inhibition and degradation in circulation, accelerating recanalization, improving targeting to thrombotic occlusions, and reducing off‐target effects; however, many particle‐based approaches have only been used in preclinical studies to date. This review covers four advances in coupling fibrinolytic agents with engineered particles: (a) modifications of plasminogen activators with macromolecules, (b) encapsulation of plasminogen activators and plasmin in polymer and liposomal particles, (c) triggered release of encapsulated fibrinolytic agents and mechanical disruption of clots with ultrasound, and (d) enhancing targeting with magnetic particles and magnetic fields. Technical challenges for the translation of these approaches to the clinic are discussed.

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Section: Magnetic Particles and Magnetic Field Controlmentioning

confidence: 99%

Section: Magnetic Particles and Magnetic Field Controlmentioning

confidence: 99%

Section: Magnetic Particles and Magnetic Field Controlmentioning

confidence: 99%

Section: Synthesis and Functionalization Of Magnetic Nanoparticle Cmentioning

confidence: 99%

Section: Magnetic Field Control Of Magnetic Particlesmentioning

confidence: 99%

See 3 more Smart Citations

Engineered microparticles and nanoparticles for fibrinolysis

Disharoon

Marr

Neeves

2019

Journal of Thrombosis and Haemostasis

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High‐Performance Magnetic FePt (L1₀) Surface Microrollers Towards Medical Imaging‐Guided Endovascular Delivery Applications

Bozuyuk

Suadiye

Aghakhani

et al. 2021

Adv Funct Materials

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Controlled microrobotic navigation in the vascular system can revolutionize minimally invasive medical applications, such as targeted drug and gene delivery. Magnetically controlled surface microrollers have emerged as a promising microrobotic platform for controlled navigation in the circulatory system. Locomotion of micrororollers in strong flow velocities is a highly challenging task, which requires magnetic materials having strong magnetic actuation properties while being biocompatible. The L10‐FePt magnetic coating can achieve such requirements. Therefore, such coating has been integrated into 8 µm‐diameter surface microrollers and investigated the medical potential of the system from magnetic locomotion performance, biocompatibility, and medical imaging perspectives. The FePt coating significantly advanced the magnetic performance and biocompatibility of the microrollers compared to a previously used magnetic material, nickel. The FePt coating also allowed multimodal imaging of microrollers in magnetic resonance and photoacoustic imaging in ex vivo settings without additional contrast agents. Finally, FePt‐coated microrollers showed upstream locomotion ability against 4.5 cm s−1 average flow velocity with real‐time photoacoustic imaging, demonstrating the navigation control potential of microrollers in the circulatory system for future in vivo applications. Overall, L10‐FePt is conceived as the key material for image‐guided propulsion in the vascular system to perform future targeted medical interventions.

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Trends in Micro‐/Nanorobotics: Materials Development, Actuation, Localization, and System Integration for Biomedical Applications

et al. 2020

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Micro‐/nanorobots (m‐bots) have attracted significant interest due to their suitability for applications in biomedical engineering and environmental remediation. Particularly, their applications in in vivo diagnosis and intervention have been the focus of extensive research in recent years with various clinical imaging techniques being applied for localization and tracking. The successful integration of well‐designed m‐bots with surface functionalization, remote actuation systems, and imaging techniques becomes the crucial step toward biomedical applications, especially for the in vivo uses. This review thus addresses four different aspects of biomedical m‐bots: design/fabrication, functionalization, actuation, and localization. The biomedical applications of the m‐bots in diagnosis, sensing, microsurgery, targeted drug/cell delivery, thrombus ablation, and wound healing are reviewed from these viewpoints. The developed biomedical m‐bot systems are comprehensively compared and evaluated based on their characteristics. The current challenges and the directions of future research in this field are summarized.

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Enhanced Fibrinolysis with Magnetically Powered Colloidal Microwheels

Cited by 61 publications

References 53 publications

Engineered microparticles and nanoparticles for fibrinolysis

Engineered microparticles and nanoparticles for fibrinolysis

High‐Performance Magnetic FePt (L1₀) Surface Microrollers Towards Medical Imaging‐Guided Endovascular Delivery Applications

Trends in Micro‐/Nanorobotics: Materials Development, Actuation, Localization, and System Integration for Biomedical Applications

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Enhanced Fibrinolysis with Magnetically Powered Colloidal Microwheels

Cited by 61 publications

References 53 publications

Engineered microparticles and nanoparticles for fibrinolysis

Engineered microparticles and nanoparticles for fibrinolysis

High‐Performance Magnetic FePt (L10) Surface Microrollers Towards Medical Imaging‐Guided Endovascular Delivery Applications

Trends in Micro‐/Nanorobotics: Materials Development, Actuation, Localization, and System Integration for Biomedical Applications

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High‐Performance Magnetic FePt (L1₀) Surface Microrollers Towards Medical Imaging‐Guided Endovascular Delivery Applications