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1. Computations of the shear stresses distribution experienced by passive particles as they circulate in turbulent flow: A case study for vWF protein molecules

   https://doi.org/10.1371/journal.pone.0273312  

   Pham, Oanh L.; Feher, Samuel E.; Nguyen, Quoc T.; Papavassiliou, Dimitrios V. (August 2022, PLOS ONE)

   Borazjani, Iman (Ed.)

   The stress distribution along the trajectories of passive particles released in turbulent flow were computed with the use of Lagrangian methods and direct numerical simulations. The flow fields selected were transitional Poiseuille-Couette flow situations found in ventricular assist devices and turbulent flows at conditions found in blood pumps. The passive particle properties were selected to represent molecules of the von Willebrand factor (vWF) protein. Damage to the vWF molecule can cause disease, most often related to hemostasis. The hydrodynamic shear stresses along the trajectories of the particles were calculated and the changes in the distribution of stresses were determined for proteins released in different locations in the flow field and as a function of exposure time. The stress distributions indicated that even when the average applied stress was within a safe operating regime, the proteins spent part of their trajectories in flow areas of damaging stress. Further examination showed that the history of the distribution of stresses applied on the vWF molecules, rather than the average, should be used to evaluate hydrodynamically-induced damage. 

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2. Aptamer-based biotherapeutic conjugate for shear responsive release of Von Willebrand factor A1 domain

   https://doi.org/10.1039/D4NR02715A  

   Ismail, Esraa; Liu, Yi; Wang, Yi; Yazdanparast_Tafti, Sajedehalsadat; Zhang, X Frank; Cheng, Xuanhong (January 2025, Nanoscale)

   Smart polymers that mimic and even surpass the functionality of natural responsive materials have been actively researched. This study explores the design and characterization of a Single-MOlecule-based material REsponsive to Shear (SMORES) for the targeted release of A1, the platelet binding domain of the blood clotting protein von Willebrand factor (VWF). Each SMORES construct employs an aptamer molecule as the flow transducer and a microparticle to sense and amplify the hydrodynamic force. Within the construct, the aptamer, ARC1172, undergoes conformational changes beyond a shear stress threshold, mimicking the shear-responsive behavior of VWF. This conformational alteration modulates the bioavailability of its target, the VWF-A1 domain, ultimately releasing it at elevated shear. Through optical tweezer-based single-molecule force measurement, ARC1172s role as a force transducer was assessed by examining its unfolding under constant pulling force. We also investigated its refolding rate as a function of force under varied relaxation periods. These analyses revealed a narrow range of threshold forces (3–7 pN) governing the transition between folded and unfolded states. We subsequently constructed the SMORES material by conjugating ARC1172 and a microbead, and immobilizing the other end of the aptamer on a substrate. Single-molecule flow experiments on immobilized SMORES constructs revealed a peak A1 domain release within a flow rate range of (40–70 μL min−1). A COMSOL Multiphysics model translated these flow rates to total forces of 3.10 pN–5.63 pN experienced by the aptamers, aligning with single-molecule force microscopy predictions. Evaluation under variable flow conditions showed a peak binding of A1 to the platelet glycoprotein Ib (GPIB) within the same force range, confirming released payload functionality. Building on knowledge of aptamer biomechanics, this study presents a new strategy to create shear-stimulated biomaterials based on single biomolecules. 

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3. Effect of pulsatility on shear‐induced extensional behavior of Von Willebrand factor

   https://doi.org/10.1111/aor.14133  

   Wang, Yi; Nguyen, Khanh T.; Ismail, Esraa; Donoghue, Leslie; Giridharan, Guruprasad A.; Sethu, Palaniappan; Cheng, Xuanhong (December 2021, Artificial Organs)

   Abstract BackgroundPatients with continuous flow ventricular assist devices (CF‐VADs) are at high risk for non‐surgical bleeding, speculated to associate with the loss of pulsatility following CF‐VAD placement. It has been hypothesized that continuous shear stress causes elongation and increased enzymatic degradation of von Willebrand Factor (vWF), a key player in thrombus formation at sites of vascular damage. However, the role of loss of pulsatility on the unravelling behavior of vWF has not been widely explored. MethodsvWF molecules were immobilized on the surface of microfluidic devices and subjected to various pulsatile flow profiles, including continuous flow and pulsatile flow of different magnitudes,dQ/dt(i.e., first derivative of flow rate) of pulsatility and pulse frequencies to mimic in vivo shear flow environments with and without CF‐VAD support. VWF elongation was observed using total internal reflection fluorescence (TIRF) microscopy. Besides, the vWF level is measured from the patients’ blood sample before and after CF‐VAD implantation from a clinical perspective. To our knowledge, this work is the first in providing direct, visual observation of single vWF molecule extension under controlled‐pulsatile shear flow. ResultsUnravelling of vWF (total sample sizen ~ 200 molecules) is significantly reduced under pulsatile flow (p < 0.01) compared to continuous flow. An increase in the magnitude of pulsatility further reduces unravelling lengths, while lower frequency of pulsatility (20 vs. 60 pulses per min) does not have a major effect on the maximum or minimum unravelling lengths. Evaluation of CF‐VAD patient blood samples (n = 13) demonstrates that vWF levels decreased by ~40% following CF‐VAD placement (p < 0.01), which correlates to single‐molecule observations from a clinical point of view. ConclusionsPulsatile flow reduces unfolding of vWF compared to continuous flow and a lower pulse frequency of 20 pulses/minute yielded comparable vWF unfolding to 60 pulses/minute. These findings could shed light on non‐surgical bleeding associated with the loss of pulsatility following CF‐VAD placement. 

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4. Loss of pulsatility with continuous‐flow left ventricular assist devices and the significance of the arterial endothelium in von‐Willebrand factor production and degradation

   https://doi.org/10.1111/aor.14456  

   Giridharan, Guruprasad A.; Berg, Ian C.; Ismail, Esraa; Nguyen, Khanh T.; Hecking, Jana; Kirklin, James K.; Cheng, Xuanhong; Sethu, Palaniappan (April 2023, Artificial Organs)

   Patients on continuous flow ventricular assist devices (CF-VADs) are at high risk for the development of Acquired von-Willebrand Syndrome (AVWS) and non-surgical bleeding. von Willebrand Factor (vWF) plays an essential role in maintaining hemostasis via platelet binding to the damaged endothelium to facilitate coagulation. In CF-VAD patients, degradation of vWF into low MW multimers that are inefficient in facilitating coagulation occurs and has been primarily attributed to the supraphysiological shear stress associated with the CF-VAD impeller. Methods In this review, we evaluate information from the literature regarding the unraveling behavior of surface-immobilized vWF under pulsatile and continuous flow pertaining to: (A) the process of arterial endothelial vWF production and release into circulation, (B) the critical shear stress required to unravel surface bound versus soluble vWF which leads to degradation, and (C) the role of pulsatility in on the production and degradation of vWF. Results and Conclusion Taken together, these data suggests that the loss of pulsatility and its impact on arterial endothelial cells plays an important role in the production, release, unraveling, and proteolytic degradation of vWF into low MW multimers, contributing to the development of AVWS. Restoration of pulsatility can potentially mitigate this issue by preventing AVWS and minimizing the risk of non-surgical bleeding. 

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5. Grain-Scale Stress Heterogeneity in Concrete from In-Situ X-Ray Measurements

   https://doi.org/10.2139/ssrn.5025153  

   Thakur, Mohmad Mohsin; Henningsson, Axel; Engqvist, Jonas; Pierre, Olivier Autran; Wright, J; Hurley, Ryan (November 2024, SSRN)

   Concrete features significant microstructural heterogeneity which affects its mechanical behavior. Strain localization in the matrix phase of concrete has received significant attention due to its relation to microcracking and our ability to quantify it with X-ray computed tomography (XRCT). In contrast, stresses in sand and aggregates remain largely unmeasured but remain critical for micromechanics-based theories of failure. Here, we use a combination of in-situ XRCT, 3D X-ray diffraction (3DXRD), and scanning 3DXRD to directly measure strain and stress within sand grains in two samples of mortar containing different sand volume fractions. Our results reveal that, in contrast to inclusion theories from continuum micromechanics, aggregates feature a broad distribution of average stresses and significant gradients in their internal stress fields. Our work furnishes the first known dataset with these quantitative stress measurements and motivates improvements in micromechanics models for concrete which can capture stress heterogeneity. 

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