Exposure of human megakaryocytes to high shear rates accelerates platelet production

Dunois-Lardé, Claire; Capron, Claude; Fichelson, Serge; Bauer, Thomas W.; Cramer–Bordé, Elisabeth; Baruch, Dominique

doi:10.1182/blood-2009-03-209205

Cited by 120 publications

(151 citation statements)

References 52 publications

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“…A major limitation of twodimensional liquid cultures has been their inability to account for three-dimensional BM composition and stiffness, directionality of proPLT extension, and proximity to venous endothelium. 15,24,25 Alternatively, intravital microscopy studies have provided physiologically accurate examples of proPLT production, however, poor resolution and limited control of the microenvironment has prohibited detailed study of how the BM microenvironment contributes to PLT release. 11,15 Nakagawa et al 50 recently published 3 bioreactor designs to produce human PLTs at scale from hiPSC-and ESC-derived MKs.…”

Section: Discussionmentioning

confidence: 99%

“…Mounting evidence that cell-cell contacts, 22,23 ECM composition 19,20 and stiffness, 21 vascular shear stress, 24,25 pO2/pH, 51,52 soluble factor interactions, 22,53 and temperature 54 contribute to proPLT formation and PLT release have suggested that recapitulating key components of BM and blood vessel microenvironments within a three-dimensional microfluidic culture system is necessary to achieve clinically significant numbers of functional human PLTs. Our microfluidic bioreactor design expands control and resolution of the microenvironment, and has allowed us to drastically improve the time to PLT release (from 18 hours down to 2 hours) and more For personal use only.…”

Section: Discussionmentioning

confidence: 99%

“…This results in yields of 10 122 PLTs per CD34 1 cord blood-derived or embryonic stem cell-derived MK, 18 which are themselves of limited availability, constituting a significant bottleneck in the ex vivo production of a PLT transfusion unit. Although second-generation cell culture approaches have provided further insight into the physiological drivers of PLT release, they have been unable to recreate the entire BM microenvironment, exhibiting limited individual control of extracellular matrix (ECM) composition, 19,20 BM stiffness, 21 endothelial cell contacts, 22,23 and vascular shear stresses, 24,25 and have been unsuccessful in synchronizing proPLT production, resulting in nonuniform PLT release over a period of 6 to 8 days. 26 Moreover, the inability to reproduce the BM microenvironment ex vivo, and resolve physiological proPLT extension and release by high-resolution live-cell microscopy, has significantly hampered efforts to study the cytoskeletal and signaling mechanics of PLT production.…”

Section: Introductionmentioning

confidence: 99%

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Platelet bioreactor-on-a-chip

Thon

Mažutis

et al. 2014

Blood

185

210

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• We have developed a biomimetic microfluidic platelet bioreactor that recapitulates bone marrow and blood vessel microenvironments.• Application of shear stress in this bioreactor triggers physiological proplatelet production, and platelet release.Platelet transfusions total >2.17 million apheresis-equivalent units per year in the United States and are derived entirely from human donors, despite clinically significant immunogenicity, associated risk of sepsis, and inventory shortages due to high demand and 5-day shelf life. To take advantage of known physiological drivers of thrombopoiesis, we have developed a microfluidic human platelet bioreactor that recapitulates bone marrow stiffness, extracellular matrix composition, micro-channel size, hemodynamic vascular shear stress, and endothelial cell contacts, and it supports high-resolution live-cell microscopy and quantification of platelet production. Physiological shear stresses triggered proplatelet initiation, reproduced ex vivo bone marrow proplatelet production, and generated functional platelets. Modeling human bone marrow composition and hemodynamics in vitro obviates risks associated with platelet procurement and storage to help meet growing transfusion needs. (Blood. 2014;124(12):1857-1867) IntroductionAlthough platelets (PLTs) play critical roles in hemostasis, 1 angiogenesis, 2 and innate immunity, 3 PLT production remains poorly understood. Consequently, PLT units are derived entirely from human donors, despite serious clinical concerns owing to their immunogenicity and associated risk of sepsis. 4 More than 2.17 million apheresisequivalent PLT units are transfused yearly in the United States 5,6 at a cost of .$1 billion per year. Although demand for PLT transfusions has increased markedly in the past decade, a near-static pool of donors and a 5-day PLT unit shelf life resulting from bacterial contamination 7 and storage-related PLT deterioration, 8 have resulted in significant PLT shortages. 9 Furthermore, artificial platelet substitutes have failed to replace physiological platelet products. 10 An efficient, donorindependent PLT bioreactor capable of generating clinically significant numbers of functional human PLTs is necessary to obviate risks associated with PLT procurement and storage, and help meet growing transfusion needs. In vivo, megakaryocytes (MKs) PLT progenitors sit outside blood vessels in the bone marrow (BM) and extend long, branching cellular structures designated proPLTs into the circulation from which PLTs are released. 11-15 Nearly 100% of human adult MKs must produce ;10 3 PLTs each to account for circulating PLT counts. 16 Although functional human PLTs were first grown in vitro in 1995, 17 to date only ;10% of human MKs initiate proPLT production in culture. This results in yields of 10 122 PLTs per CD34 1 cord blood-derived or embryonic stem cell-derived MK, 18 which are themselves of limited availability, constituting a significant bottleneck in the ex vivo production of a PLT transfusion unit. Although second-generation c...

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Platelet bioreactor-on-a-chip

Thon

Mažutis

et al. 2014

Blood

185

210

View full text Add to dashboard Cite

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“…The CD41 1 subpopulation is short lived, preactivated, weakly reactive, and underincorporated into thrombi. EV-PLPs generated in bioreactors [51][52][53][54][55] have been described and such high-throughput devices are clearly needed to achieve largescale EV-platelet production. Like infused EV-megakaryocytes, they would have the advantage of producing mostly young platelets.…”

Section: Discussionmentioning

confidence: 99%

Comparative analysis of human ex vivo–generated platelets vs megakaryocyte-generated platelets in mice: a cautionary tale

Wang

Hayes

Jarocha

et al. 2015

Blood

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• Infused human megakaryocytes release young platelets in the lungs with characteristics similar to donor platelets.• Platelets released from ex vivo-derived megakaryocytes are preactivated and compare poorly to donor platelets.Thrombopoiesis is the process by which megakaryocytes release platelets that circulate as uniform small, disc-shaped anucleate cytoplasmic fragments with critical roles in hemostasis and related biology. The exact mechanism of thrombopoiesis and the maturation pathways of platelets released into the circulation remain incompletely understood. We showed that ex vivo-generated murine megakaryocytes infused into mice release platelets within the pulmonary vasculature. Here we now show that infused human megakaryocytes also release platelets within the lungs of recipient mice. In addition, we observed a population of platelet-like particles (PLPs) in the infusate, which include platelets released during ex vivo growth conditions. By comparing these 2 platelet populations to human donor platelets, we found marked differences: platelets derived from infused megakaryocytes closely resembled infused donor platelets in morphology, size, and function. On the other hand, the PLP was a mixture of nonplatelet cellular fragments and nonuniform-sized, preactivated platelets mostly lacking surface CD42b that were rapidly cleared by macrophages. These data raise a cautionary note for the clinical use of human platelets released under standard ex vivo conditions. In contrast, human platelets released by intrapulmonary-entrapped megakaryocytes appear more physiologic in nature and nearly comparable to donor platelets for clinical application. (Blood. 2015;125(23):3627-3636)

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“…Blood shear stress contributes to the shedding of PPs Dunois-Lardé et al, 2009;Thon et al, 2010); however, whether additional signals are required for efficient PP shedding was completely unknown. In this study, we show that hydrodynamic forces alone are not sufficient to allow the release of new platelets from MK PP extensions.…”

Section: S1p Navigates Pp Extensions Into Bm Sinusoids and Initiates mentioning

confidence: 99%