As platelets aggregate and activate at the site of vascular injury to stem bleeding, they are subjected to a myriad of biochemical and biophysical signals and cues. As clot formation ensues, platelets interact with polymerizing fibrin scaffolds, exposing platelets to a large range of mechanical microenvironments. Here, we show for the first time (to our knowledge) that platelets, which are anucleate cellular fragments, sense microenvironmental mechanical properties, such as substrate stiffness, and transduce those cues into differential biological signals. Specifically, as platelets mechanosense the stiffness of the underlying fibrin/fibrinogen substrate, increasing substrate stiffness leads to increased platelet adhesion and spreading. Importantly, adhesion on stiffer substrates also leads to higher levels of platelet activation, as measured by integrin α IIb β 3 activation, α-granule secretion, and procoagulant activity. Mechanistically, we determined that Rac1 and actomyosin activity mediate substrate stiffness-dependent platelet adhesion, spreading, and activation to different degrees. This capability of platelets to mechanosense microenvironmental cues in a growing thrombus or hemostatic plug and then mechanotransduce those cues into differential levels of platelet adhesion, spreading, and activation provides biophysical insight into the underlying mechanisms of platelet aggregation and platelet activation heterogeneity during thrombus formation. mechanotransduction | cell mechanics | platelet cytoskeleton | biomaterials A s the first responders at the site of vascular injury, platelets are subjected to a dynamic microenvironment during the process of hemostasis (1-5). Biochemically, platelets are exposed to diverse and rapidly changing gradients of soluble proteins and agonists such as von Willebrand factor, ADP, and thrombin, all of which drive platelet adhesion and activation (6, 7). During this process, platelet activation may take several forms including activation of platelet α IIb β 3 integrins, secretion of α-and dense granules, and membrane phosphatidylserine (PS) exposure leading to a procoagulant phenotype (8, 9). Biophysically, platelets also activate and aggregate in response to the hemodynamic and shear forces of the circulation (10, 11). As clot formation ensues, platelets then interact with polymerizing fibrin scaffolds, exposing platelets to a large range of mechanical microenvironments. Although the underlying biochemical signaling pathways that govern the fibrinogen-α IIb β 3 -mediated processes have been well characterized, if and how the mechanical cues in the microenvironment affect platelet activation and physiology remain largely unknown. Indeed, as clot structure and mechanics are known to be heterogeneous within the same clot and more recent studies have demonstrated that platelet activation is also vastly heterogeneous within a growing thrombus (12-14), a systematic approach to investigate how platelet activation is affected by the mechanical microenvironment could lead to profoun...
Alterations in the mechanical properties of erythrocytes occurring in inflammatory and hematologic disorders such as sickle cell disease (SCD) and malaria often lead to increased endothelial permeability, haemolysis, and microvascular obstruction. However, the associations among these pathological phenomena remain unknown. Here, we report a perfusable, endothelialized microvasculature-on-a-chip featuring an interpenetrating-polymer-network hydrogel that recapitulates the stiffness of blood-vessel intima, basement membrane self-deposition and self-healing endothelial barrier function for longer than 1 month. The microsystem enables the real-time visualization, with high spatiotemporal resolution, of microvascular obstruction and endothelial permeability under physiological flow conditions. We found how extracellular heme, a hemolytic byproduct, induces delayed but reversible endothelial permeability in a dose-dependent manner, and demonstrate that endothelial interactions with SCD or malaria-infected erythrocytes cause reversible microchannel occlusion and increased in situ endothelial permeability. The microvasculature-on-a-chip enables mechanistic insight into the endothelial barrier dysfunction associated with SCD, malaria and other inflammatory and haematological diseases.
Haemostasis occurs at sites of vascular injury, where flowing blood forms a clot, a dynamic and heterogeneous fibrin-based biomaterial. Paramount in the clot’s capability to stem haemorrhage are its changing mechanical properties, the major driver of which are the contractile forces exerted by platelets against the fibrin scaffold 1. However, how platelets transduce microenvironmental cues to mediate contraction and alter clot mechanics is unknown. This is clinically relevant, as overly softened and stiffened clots are associated with bleeding 2 and thrombotic disorders 3. Here, we report a high-throughput hydrogel based platelet-contraction cytometer that quantifies single-platelet contraction forces in different clot microenvironments. We also show that platelets, via the Rho/ROCK pathway, synergistically couple mechanical and biochemical inputs to mediate contraction. Moreover, highly contractile platelet subpopulations present in healthy controls are conspicuously absent in a subset of patients with undiagnosed bleeding disorders, and therefore may function as a clinical diagnostic biophysical biomarker.
The vascular endothelium presents a major transport barrier to drug delivery by only allowing selective extravasation of solutes and small molecules. Therefore, enhancing drug transport across the endothelial barrier has to rely on leaky vessels arising from disease states such as pathological angiogenesis and inflammatory response. Here we show that the permeability of vascular endothelium can be increased using an external magnetic field to temporarily disrupt endothelial adherens junctions through internalized iron oxide nanoparticles, activating the paracellular transport pathway and facilitating the local extravasation of circulating substances. This approach provides a physically controlled drug delivery method harnessing the biology of endothelial adherens junction and opens a new avenue for drug delivery in a broad range of biomedical research and therapeutic applications.
SummaryMesenchymal stromal cells have shown clinical promise; however, variations in treatment responses are an ongoing concern. We previously demonstrated that MSCs are functionally stunned after thawing. Here, we investigated whether this cryopreservation/thawing defect also impacts the postinfusion biodistribution properties of MSCs. Under both static and physiologic flow, compared with live MSCs in active culture, MSCs thawed from cryopreservation bound poorly to fibronectin (40% reduction) and human endothelial cells (80% reduction), respectively. This reduction correlated with a reduced cytoskeletal F-actin content in post-thaw MSCs (60% reduction). In vivo, live human MSCs could be detected in murine lung tissues for up to 24 hr, whereas thawed MSCs were undetectable. Similarly, live MSCs whose actin cytoskeleton was chemically disrupted were undetectable at 24 hr postinfusion. Our data suggest that post-thaw cryopreserved MSCs are distinct from live MSCs. This distinction could significantly affect the utility of MSCs as a cellular therapeutic.
Leukocytes normally marginate toward the vascular wall in large vessels and within the microvasculature. Reversal of this process, leukocyte demargination, leads to substantial increases in the clinical white blood cell and granulocyte count and is a welldocumented effect of glucocorticoid and catecholamine hormones, although the underlying mechanisms remain unclear. Here we show that alterations in granulocyte mechanical properties are the driving force behind glucocorticoid-and catecholamine-induced demargination. First, we found that the proportions of granulocytes from healthy human subjects that traversed and demarginated from microfluidic models of capillary beds and veins, respectively, increased after the subjects ingested glucocorticoids. Also, we show that glucocorticoid and catecholamine exposure reorganizes cellular cortical actin, significantly reducing granulocyte stiffness, as measured with atomic force microscopy. Furthermore, using simple kinetic theory computational modeling, we found that this reduction in stiffness alone is sufficient to cause granulocyte demargination. Taken together, our findings reveal a biomechanical answer to an old hematologic question regarding how glucocorticoids and catecholamines cause leukocyte demargination. In addition, in a broader sense, we have discovered a temporally and energetically efficient mechanism in which the innate immune system can simply alter leukocyte stiffness to fine tune margination/demargination and therefore leukocyte trafficking in general. These observations have broad clinically relevant implications for the inflammatory process overall as well as hematopoietic stem cell mobilization and homing. cellular mechanics | leukocyte deformability | demargination | microfluidics | atomic force microscopy L eukocyte margination within the microvasculature and in larger blood vessels is an integral part of the inflammatory process and innate immune system (1, 2). This margination phenomenon is twofold, involving sequestration of leukocytes in the capillary bed (3, 4) as well as movement of leukocytes toward the blood vessel wall (Fig. 1A) (5, 6). Recent experimental and computational data, including our own, indicate that the mechanical properties of leukocytes play a major role in margination and are sufficient to drive leukocytes in whole blood toward the vessel wall (7-12).What is not known is whether leukocyte softening can cause the reversal of leukocyte margination, which would indicate that leukocyte stiffness may be modulated by the immune system as an additional biophysical means to mediate leukocyte trafficking. To that end, we explored whether leukocyte stiffness alterations play a role in leukocyte demargination induced by glucocorticoid and catecholamine hormones. Although this phenomenon, which causes significant increases in the white blood cell (WBC) count within the clinical complete blood count (CBC) and specifically involves the granulocyte subpopulation of leukocytes, has been well documented from a clinical perspective for deca...
Inflammation-mediated endothelial cell (EC) dysfunction likely contributes to the pathogenesis of several vascular diseases including atherosclerosis. We found that stimulation of human umbilical vein ECs with lipopolysaccharide induced secretion of cyclophilin (CyPA) an intracellular protein belonging to the immunophilin family. We then found that when added exogenously CyPA has direct effects on ECs in vitro. At low concentrations (10 to 100 ng/ml) CyPA increased EC proliferation, migration, invasive capacity, and tubulogenesis. Gelatin zymography indicated increased secretion of active matrix metalloproteinase-2, a mediator of cell migration and angiogenesis. At high concentrations (eg, 2 g/ml) CyPA had opposite effects, decreasing EC migration and viability, possibly in relation to induction of Toll-like receptor-4 expression, detected by immunocytochemistry and flow cytometry. In vivo CyPA expression was not detectable in the luminal ECs of normal mouse carotid arteries but was rapidly induced after systemic lipopolysaccharide injection. In an experimental mouse model of atherosclerosis, CyPA expression was detected in the ECs of neocapillaries of carotid artery lesions, supporting its association with pathological angiogenesis suggested by our in vitro results. In conclusion, we found that CyPA has a biphasic activity on ECs in vitro and is up-regulated in vivo in ECs under pathological states. Our results suggest that CyPA is a novel paracrine and autocrine modulator of EC functions in immune-mediated vascular disease.
CYP1A1 and CYP1B1 gene and protein expressions vary with time, magnitude, and pattern of shear stress. Increased CYP1A1 gene expression modulates AhR-regulated genes. Based on our in vitro reversing flow data and in vivo immunostained mouse aorta, we suggest that increased expression of both genes reflects an anti-atherogenic endothelial cell phenotype.
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