An MRI study of the differences in the rate of thrombolysis between red blood cell‐rich and platelet‐rich components of venous thrombi ex vivo

Vidmar, Jernej; Blinc, Aleš; Kralj, Eduard; Balažic, Jože; Bajd, Franci; Serša, Igor

doi:10.1002/jmri.22731

Cited by 7 publications

(7 citation statements)

References 33 publications

(44 reference statements)

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“…These conditions are relevant both to deep vein thrombosis where fibrin‐rich thrombi several centimeters in length can form, attenuating any pressure difference across the thrombus, as well as in to arterial thrombosis where low permeability platelet‐rich thrombi result in very low interstitial flows even for significant pressure gradients . In both cases, heterogeneities in thrombus structure can result in regions that are more permeable and more susceptible to fibrinolysis under pressure‐driven flow . In our studies, the size of individual colloids and small µwheels is on the same order of magnitude as dense fibrin gel pores and may benefit from convective transport by either enhancing µwheel penetration or by conveying plasmin deeper into a thrombus.…”

Section: Resultsmentioning

confidence: 77%

Enhanced Fibrinolysis with Magnetically Powered Colloidal Microwheels

Tasci

Disharoon

Schoeman

et al. 2017

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Thrombi that occlude blood vessels can be resolved with fibrinolytic agents that degrade fibrin, the polymer that forms between and around platelets to provide mechanical stability. Fibrinolysis rates however are often constrained by transport-limited delivery to and penetration of fibrinolytics into the thrombus. Here, these limitations are overcome with colloidal microwheel (µwheel) assemblies functionalized with the fibrinolytic tissue-type plasminogen activator (tPA) that assemble, rotate, translate, and eventually disassemble via applied magnetic fields. These microwheels lead to rapid fibrinolysis by delivering a high local concentration of tPA to induce surface lysis and, by taking advantage of corkscrew motion, mechanically penetrating into fibrin gels and platelet-rich thrombi to initiate bulk degradation. Fibrinolysis of plasma-derived fibrin gels by tPA-microwheels is fivefold faster than with 1 µg mL tPA. µWheels following corkscrew trajectories can also penetrate through 100 µm sized platelet-rich thrombi formed in a microfluidic model of hemostasis in ≈5 min. This unique combination of surface and bulk dissolution mechanisms with mechanical action yields a targeted fibrinolysis strategy that could be significantly faster than approaches relying on diffusion alone, making it well-suited for occlusions in small or penetrating vessels not accessible to catheter-based removal.

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Section: Resultsmentioning

confidence: 77%

Enhanced Fibrinolysis with Magnetically Powered Colloidal Microwheels

Tasci

Disharoon

Schoeman

et al. 2017

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“…For example, at pressures typical of large human arteries one would except fibrinolytic agents like tissue plasminogen activator (tPA) to penetrate no further than ∼100 μm over 1 hr into the interior platelet rich clot. This is too slow for most clinical applications and supports reports that fibrinolytic drugs have limited success on platelet rich clots [24]. In addition, the hindrance of transport of coagulation proteins and platelet agonists out of clots is a potential mechanism for the arrest of clots growth.…”

Section: Discussionmentioning

confidence: 67%

Fluid and Solute Transport in the Interstitial Space of Blood Clots

Wufsus¹,

Neeves²

2015

Pore Scale Phenomena

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Biological tissues can be described as porous media consisting of granular cells and a fibrous extracellular matrix. The transport of fluids and solutes through the interstitial space between cells regulates many physiological and pathological processes. In the case of blood clots, the ability of solutes to move into and out of the inner core of a clot dictates both growth and dissolution. Two physical properties that govern the rate of fluid and solute transport are the hydraulic permeability and diffusivity. Here, we report the experimental measurement of these two properties over a large range of clot compositions. Hydraulic permeability was calculated by measuring the interstitial fluid velocity through clots at a constant pressure gradient. The permeability changes by up to five orders-of-magnitude, spanning the range of 10 −5 -10 −1 μm 2 , depending on the absolute and relative volume fractions of-cells (platelets) and a fibrous protein (fibrin). The permeability of clots can be predicted using solutions to Stokes flow in disordered fibrous media in the low cell volume fraction limit and by the Brinkman equation for clots with moderate to high cell volume fractions. The diffusivity of macromolecule tracers was measured using fluorescence recovery after photobleaching (FRAP) in fibrin gels. Diffusion of macromolecules becomes hindered even at low fibrin volume fractions (<0.05). These data are the first measurements of permeability and diffusivity over the physiological range of blood clot compositions, and thus will allow for better modeling and predictions of clot growth. These findings have important implications in the development of drug delivery strategies for disrupting clot formation and enhancing clot dissolution. 457

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“…The distribution of platelets in a thrombus is actually an important factor in thrombolysis. For instance, the laminations of coalescent platelets mixed with the fibrin network (known as Zahn lines 41 42 ) in in vivo thrombi may result in a stronger resistance to thrombolysis 43 . For these reasons, the performance of using Nakagami imaging to evaluate the lysis of thrombus in vivo should be investigated using animal models.…”

Section: Discussionmentioning

confidence: 99%

Evaluation of thrombolysis by using ultrasonic imaging: an in vitro study

Fang

Tsui

2015

Sci Rep

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The hematocrit of a thrombus is a key factor associated with the susceptibility to thrombolysis. Ultrasonic imaging is currently the first-line screening tool for thrombus examinations. Different hematocrits result in different acoustical structures of thrombi, which alter the behavior of ultrasonic backscattering. This study explored the relationships among thrombolytic efficiencies, hematocrits, and ultrasonic parameters (the echo intensity and backscattered statistics). Porcine thrombi with different hematocrits, ranging from 0% to 50%, were induced in vitro. An ultrasonic scanner was used to scan thrombi and acquire raw image data for B-mode (echo intensity measurements) and Nakagami imaging (backscattered statistics analysis). Experiments on thrombolysis were performed using urokinase to explore the effect of the hematocrit on thrombolytic efficiency. Results showed that the weight loss ratio of thrombi exponentially decreased as the hematocrit increased from 0% to 50%. Compared with the echo intensity obtained from the conventional B-scan, the Nakagami parameter predicts the weight loss ratio, increasing from 0.6 to 1.2 as the weight loss ratio decreased from 0.67 to 0.26. The current findings suggest that using Nakagami imaging characterizing thrombi provides information of backscattered statistics, which may be associated with the thrombolytic efficiency.

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An MRI study of the differences in the rate of thrombolysis between red blood cell‐rich and platelet‐rich components of venous thrombi ex vivo

Cited by 7 publications

References 33 publications

Enhanced Fibrinolysis with Magnetically Powered Colloidal Microwheels

Enhanced Fibrinolysis with Magnetically Powered Colloidal Microwheels

Fluid and Solute Transport in the Interstitial Space of Blood Clots

Evaluation of thrombolysis by using ultrasonic imaging: an in vitro study

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