Sublethal mechanical trauma alters the electrochemical properties and increases aggregation of erythrocytes

McNamee, Antony P.; Tansley, Geoff; Simmonds, Michael J.

doi:10.1016/j.mvr.2018.05.008

Cited by 16 publications

(18 citation statements)

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“…When standardizing for hematocrit, the intrinsic physical properties of RBCs—that is, cellular deformability and their tendency to form reversible multi‐cell aggregates—govern blood fluidity. Previous experimentation has established that exposure to supraphysiological shear environments may cause both increased RBC aggregation and decreased RBC deformability in human blood samples 47,48 . Normal bovine RBC do not readily form aggregates; however, have been shown to aggregate following exposure to a centrifugal blood pump in vivo 48 .…”

Section: Discussionmentioning

confidence: 99%

“…Previous experimentation has established that exposure to supraphysiological shear environments may cause both increased RBC aggregation and decreased RBC deformability in human blood samples. 47,48 Normal bovine RBC do not readily form aggregates; however, have been shown to aggregate following exposure to a centrifugal blood pump in vivo. 48 Further exploration of underlying RBC alterations following exposure to high mechanical shear stresses could reveal sublethal-specific alterations and potentially identify new markers sensitive to detecting pre-hemolytic blood trauma.…”

Section: Discussionmentioning

confidence: 99%

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Ex vivo assessment of erythrocyte tolerance to the HeartWare ventricular assist device operated in three discrete configurations

et al. 2020

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Despite technological advances in ventricular assist devices (VADs) to treat end‐stage heart failure, hemocompatibility remains a constant concern, with supraphysiological shear stresses an unavoidable reality with clinical use. Given that impeller rotational speed is related to the instantaneous shear within the pump housing, it is plausible that the modulation of pump speed may regulate peak mechanical shear stresses and thus ameliorate blood damage. The present study investigated the hemocompatibility of the HeartWare HVAD in three configurations typical of clinical applications: standard systemic support left VAD (LVAD), pediatric support LVAD, and pulmonary support right VAD (RVAD) conditions. Two ex vivo mock circulation blood loops were constructed using explanted HVADs, in which pump speed and external loop resistance were manipulated to reflect the flow rates and differential pressures reported in configurations for standard adult LVAD (at 3150 rev⸱min−1), pediatric LVAD (at 2400 rev⸱min−1), and adult RVAD (at 1900 rev⸱min−1). Using bovine blood, the mock circulation blood loops were tested at 37°C over a period of 6 hours (consistent with ASTM F1841‐97) and compared with static control. Hemocompatibility assessments were conducted for each test condition, examining hematology, hemolysis (absolute and normalized index), osmotic fragility, and blood viscosity. Regardless of configuration, continuous exposure of blood to the VAD over the 6‐hour period significantly altered hematological and rheological blood parameters, and induced increased hemolysis when compared with a static control sample. Comparison of the three operational VAD configurations identified that the adult LVAD condition—associated with the highest pump speed, flow rate, and differential pressure across the pump—resulted in increased normalized hemolysis index (NIH; 0.07) when compared with the lower pump speed “off‐label” counterparts (NIH of 0.04 in pediatric LVAD and 0.01 in adult RVAD configurations). After normalizing blood residence times between configurations, pump speed was identified as the primary determinant of accumulated blood damage; plausibly, blood damage could be limited by restricting pump speed to the minimum required to support matched cardiac output, but not beyond.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Ex vivo assessment of erythrocyte tolerance to the HeartWare ventricular assist device operated in three discrete configurations

et al. 2020

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“…Exposure of blood to supraphysiological shear stresses, below hemolytic levels at which cell rupture is induced, alters the physical and electrochemical properties of RBCs by remodeling the membrane, denaturing cytoskeletal proteins, and thinning the glycocalyx 18,27‐29 . A number of recent reports have identified that exposure of RBCs to sublethal mechanical trauma also decreases RBC deformability as measured using laser diffractometry 13,16,17,30 .…”

Section: Discussionmentioning

confidence: 99%

“…Within circulation, the physiological shear stresses that RBCs are exposed to typically range from 0‐10 Pa 12 Mechanical stresses >10 Pa therefore represent a supraphysiological condition; initially, cells tolerate these stresses without substantial effects, although biophysical properties of cells become impaired when exposed to 40‐80 Pa (depending on exposure duration 13 ) and eventually hemolyze at shears >150 Pa (again, depending on exposure duration 12,14,15 ). The range of shears that induce biophysical impairment to RBC are progressively termed “sublethal,” while stresses that induce overt cell destruction are hemolytic and/or “lethal.” Recent advances in characterizing mechanically induced blood damage identified that shear stress magnitudes that are supraphysiological, yet non‐lethal, can negatively impact RBC structure and function as evidenced through: (a) aberrations to cell morphology 16 ; (b) decreased cellular deformability 17 ; (c) altered cell electronegativity and cell surface chemistry and thus thresholds for cell aggregation/disaggregation 18 ; and (d) cell fragmentation 19 . The extent to which these alterations influence in vivo hemodynamics remains to be elucidated, although it is hypothesized that altered RBC mechanobiology may propagate malperfusion and/or flow stagnation that lead to poor tissue oxygenation 11,20 .…”

Section: Introductionmentioning

confidence: 99%

“…(c) altered cell electronegativity and cell surface chemistry and thus thresholds for cell aggregation/disaggregation 18 ; and (d) cell fragmentation. 19 The extent to which these alterations influence in vivo hemodynamics remains to be elucidated, although it is hypothesized that altered RBC mechanobiology may propagate malperfusion and/ or flow stagnation that lead to poor tissue oxygenation.…”

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Sublethal mechanical shear stress increases the elastic shear modulus of red blood cells but does not change capillary transit velocity

2020

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Mechanical circulatory support is commonly used to assist (or replace) the function of native organs during acute surgical interventions and/or chronic organ failure. Over the past half-century, these devices have been continually improved; however, significant complications continue to plague recipients, with "blood trauma" being implicated. 1-3 Blood interactions with foreign surfaces, excessive turbulence, and mechanical stresses can cause dangerous complications of altered blood rheology and organ perfusion (for review, see Nemeth et al, 2018 4). The capability of red blood cells (RBCs) to deform is vital for successful blood circulation and fluidity. The human RBC has a resting diameter of ~8 µm, and must be able to reversibly stretch, fold, and deform through the smallest capillaries of the body (<3 µm lumen) to facilitate gas exchange and tissue perfusion. 5 The unique capacity of RBCs to endure large deformations and subsequent recovery is predominantly determined by a few key attributes: Unlike most cells,

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Complexation‐Induced Resolution Enhancement Pleiotropic Small Diameter Vascular Constructs with Superior Antibacterial and Angiogenesis Properties

Liu

Yan

et al. 2023

Adv Healthcare Materials

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Abstract3D printing has been widely applied for preparing artificial blood vessels, which will bring innovation to cardiovascular disorder intervention. However, the printing resolution and anti‐infection properties of small‐diameter vessels (Φ < 6 mm) have been challenging in 3D printing. The primary objective of this research is to design a noval coaxial 3D printing post‐processing method for preparing small‐size blood vessels with improved antibacterial and angiogenesis properties. The coaxial printing resolution can be more conveniently improved. Negatively charged polyvinyl alcohol (PVA) and alginate (Alg) interpenetrating networks artificial vessels are immersed in positively charged chitosan (CTS) solution. Rapid dimensional shrinkage takes place on its outer surface through electrostatic interactions. The maximum shrinkage size of wall thickness can reach 61.2%. The vessels demonstrate strong antibacterial properties against Escherichia coli (98.8 ± 0.5%) and Staphylococcus aureus (97.6 ± 1.4%). In rat dorsal skin grafting experiments, Cu2+ can promote angiogenesis by regulating hypoxia‐inducible factor‐1 pathway. No artificial blood vessel blockage occur after 5 d of blood circulation in vitro.This article is protected by copyright. All rights reserved

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Sublethal mechanical trauma alters the electrochemical properties and increases aggregation of erythrocytes

Cited by 16 publications

References 42 publications

Ex vivo assessment of erythrocyte tolerance to the HeartWare ventricular assist device operated in three discrete configurations

Ex vivo assessment of erythrocyte tolerance to the HeartWare ventricular assist device operated in three discrete configurations

Sublethal mechanical shear stress increases the elastic shear modulus of red blood cells but does not change capillary transit velocity

Complexation‐Induced Resolution Enhancement Pleiotropic Small Diameter Vascular Constructs with Superior Antibacterial and Angiogenesis Properties

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