HÉMO-IONIC®, a new hemostatic active in tissue repair : from hemostasis to maturation phase

Suite à une lésion, la réparation d’un tissu à l’identique est l’objectif clinique recherché. Ainsi un hémostatique, au-delà de sa capacité à arrêter un saignement, se doit au minimum de ne pas être délétère pour la réparation tissulaire. Or, malgré une efficacité hémostatique démontrée Tachosil® et Surgicel®, couramment utilisés en chirurgie, peuvent générer en raison de leur persistance in situ associée à une résorption incomplète, des évènements indésirables graves (nécrose, hypersensibilité, allergie, sténose, complication thromboembolique, sepsis…). Dans ce contexte, nous avons étudié les effets d’un nouvel hémostatique non implantable, HÉMO-IONIC®, sur toutes les étapes de la réparation tissulaire : de l’hémostase à la phase de maturation. HÉMO-IONIC®, Tachosil® et Surgicel® ont été évalués in vitro sur la fonctionnalité des Endothelial Colony Forming Cells (ECFCs) ; et in vivo dans deux modèles murins, un modèle d’hémostase et un de réparation tissulaire. Grâce à ces travaux, constituant une approche originale de l’évaluation des hémostatiques, nous avons démontré que seul HÉMO-IONIC®, en plus d’être un hémostatique efficace, maintient l’ensemble des propriétés fonctionnelles des cellules endothéliales et agit, à plus long terme, positivement sur l’ensemble des étapes de la réparation tissulaire. Ces données ouvrent des perspectives particulièrement intéressantes, notamment dans la prise en charge des brûlures nécessitant la restitution d’un tissu cutané de qualité (souple et élastique). Ainsi, l’association d’HÉMO-IONIC® à l’expertise du Service de Santé des Armées (SSA) dans l’utilisation des cellules stromales mésenchymateuses comme Médicament de Thérapie Innovante (MTI) pourrait représenter, dans la prise en charge des brûlures, une avancée thérapeutique en améliorant les résultats fonctionnels et esthétiques.After an injury, the clinical objective is to faithfully repair tissues. Thus, a hemostatic agent, beyond its ability to stop bleeding, must at least not be deleterious for tissue repair. However, despite proven hemostatic efficacy, Tachosil® and Surgicel®, which are commonly used in surgery, can lead to serious adverse events (necrosis, hypersensitivity, allergy, stenosis, thromboembolic complication, sepsis…) due to their in situ persistence associated with their incomplete resorption. In this context, we studied the effects of a new non-implantable hemostatic agent, HÉMO-IONIC®, on all stages of tissue repair : from hemostasis to maturation phase. The effects of HÉMO-IONIC®, Tachosil® and Surgicel® were assessed in vitro on Endothelial Colony Forming Cell function (ECFCs) and in vivo in two mouse models of hemostasis and tissue repair. Using an original approach to the assessment of hemostatic agents, we showed that only HÉMO-IONIC®, in addition to being effective, maintained all the functional properties of endothelial cells and acted positively on all stages of tissue repair in the longer term. These data open up very interesting perspectives, in particular in the management of burns where restoring a quality cutaneous tissue (supple and elastic) is required. Thus, in burn management, combining HÉMO-IONIC® with the French Defence Health service expertise in the use of mesenchymatous stromal cells as an advanced therapy medicinal product could be a therapeutic advance by improving the functional and esthetic outcomes

HÉMO-IONIC®,un nouvel hémostatique actif sur la réparation tissulaire : de l'hémostase à la phase de maturation

After an injury, the clinical objective is to faithfully repair tissues. Thus, a hemostatic agent, beyond its ability to stop bleeding, must at least not be deleterious for tissue repair. However, despite proven hemostatic efficacy, Tachosil® and Surgicel®, which are commonly used in surgery, can lead to serious adverse events (necrosis, hypersensitivity, allergy, stenosis, thromboembolic complication, sepsis…) due to their in situ persistence associated with their incomplete resorption. In this context, we studied the effects of a new non-implantable hemostatic agent, HÉMO-IONIC®, on all stages of tissue repair : from hemostasis to maturation phase. The effects of HÉMO-IONIC®, Tachosil® and Surgicel® were assessed in vitro on Endothelial Colony Forming Cell function (ECFCs) and in vivo in two mouse models of hemostasis and tissue repair. Using an original approach to the assessment of hemostatic agents, we showed that only HÉMO-IONIC®, in addition to being effective, maintained all the functional properties of endothelial cells and acted positively on all stages of tissue repair in the longer term. These data open up very interesting perspectives, in particular in the management of burns where restoring a quality cutaneous tissue (supple and elastic) is required. Thus, in burn management, combining HÉMO-IONIC® with the French Defence Health service expertise in the use of mesenchymatous stromal cells as an advanced therapy medicinal product could be a therapeutic advance by improving the functional and esthetic outcomes.Suite à une lésion, la réparation d’un tissu à l’identique est l’objectif clinique recherché. Ainsi un hémostatique, au-delà de sa capacité à arrêter un saignement, se doit au minimum de ne pas être délétère pour la réparation tissulaire. Or, malgré une efficacité hémostatique démontrée Tachosil® et Surgicel®, couramment utilisés en chirurgie, peuvent générer en raison de leur persistance in situ associée à une résorption incomplète, des évènements indésirables graves (nécrose, hypersensibilité, allergie, sténose, complication thromboembolique, sepsis…). Dans ce contexte, nous avons étudié les effets d’un nouvel hémostatique non implantable, HÉMO-IONIC®, sur toutes les étapes de la réparation tissulaire : de l’hémostase à la phase de maturation. HÉMO-IONIC®, Tachosil® et Surgicel® ont été évalués in vitro sur la fonctionnalité des Endothelial Colony Forming Cells (ECFCs) ; et in vivo dans deux modèles murins, un modèle d’hémostase et un de réparation tissulaire. Grâce à ces travaux, constituant une approche originale de l’évaluation des hémostatiques, nous avons démontré que seul HÉMO-IONIC®, en plus d’être un hémostatique efficace, maintient l’ensemble des propriétés fonctionnelles des cellules endothéliales et agit, à plus long terme, positivement sur l’ensemble des étapes de la réparation tissulaire. Ces données ouvrent des perspectives particulièrement intéressantes, notamment dans la prise en charge des brûlures nécessitant la restitution d’un tissu cutané de qualité (souple et élastique). Ainsi, l’association d’HÉMO-IONIC® à l’expertise du Service de Santé des Armées (SSA) dans l’utilisation des cellules stromales mésenchymateuses comme Médicament de Thérapie Innovante (MTI) pourrait représenter, dans la prise en charge des brûlures, une avancée thérapeutique en améliorant les résultats fonctionnels et esthétiques

A new hemostatic agent composed of Zn2+-enriched Ca2+ alginate activates vascular endothelial cells in vitro and promotes tissue repair in vivo

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Endothelial and hematopoietic hPSCs differentiation via a hematoendothelial progenitor

International audienceAbstract Background hPSC-derived endothelial and hematopoietic cells (ECs and HCs) are an interesting source of cells for tissue engineering. Despite their close spatial and temporal embryonic development, current hPSC differentiation protocols are specialized in only one of these lineages. In this study, we generated a hematoendothelial population that could be further differentiated in vitro to both lineages. Methods Two hESCs and one hiPSC lines were differentiated into a hematoendothelial population, hPSC-ECs and blast colonies (hPSC-BCs) via CD144 + -embryoid bodies (hPSC-EBs). hPSC-ECs were characterized by endothelial colony-forming assay, LDL uptake assay, endothelial activation by TNF-α, nitric oxide detection and Matrigel-based tube formation. Hematopoietic colony-forming cell assay was performed from hPSC-BCs. Interestingly, we identified a hPSC-BC population characterized by the expression of both CD144 and CD45. hPSC-ECs and hPSC-BCs were analyzed by flow cytometry and RT-qPCR; in vivo experiments have been realized by ischemic tissue injury model on a mouse dorsal skinfold chamber and hematopoietic reconstitution in irradiated immunosuppressed mouse from hPSC-ECs and hPSC-EB-CD144 + , respectively. Transcriptomic analyses were performed to confirm the endothelial and hematopoietic identity of hESC-derived cell populations by comparing them against undifferentiated hESC, among each other’s ( e.g. hPSC-ECs vs. hPSC-EB-CD144 + ) and against human embryonic liver (EL) endothelial, hematoendothelial and hematopoietic cell subpopulations. Results A hematoendothelial population was obtained after 84 h of hPSC-EBs formation under serum-free conditions and isolated based on CD144 expression. Intrafemorally injection of hPSC-EB-CD144 + contributed to the generation of CD45 + human cells in immunodeficient mice suggesting the existence of hemogenic ECs within hPSC-EB-CD144 + . Endothelial differentiation of hPSC-EB-CD144 + yields a population of > 95% functional ECs in vitro. hPSC-ECs derived through this protocol participated at the formation of new vessels in vivo in a mouse ischemia model. In vitro, hematopoietic differentiation of hPSC-EB-CD144 + generated an intermediate population of > 90% CD43 + hPSC-BCs capable to generate myeloid and erythroid colonies. Finally, the transcriptomic analyses confirmed the hematoendothelial, endothelial and hematopoietic identity of hPSC-EB-CD144 + , hPSC-ECs and hPSC-BCs, respectively, and the similarities between hPSC-BC-CD144 + CD45 + , a subpopulation of hPSC-BCs, and human EL hematopoietic stem cells/hematopoietic progenitors. Conclusion The present work reports a hPSC differentiation protocol into functional hematopoietic and endothelial cells through a hematoendothelial population. Both lineages were proven to display characteristics of physiological human cells, and therefore, they represent an interesting rapid source of cells for future cell therapy and tissue engineering

Cord blood-endothelial colony forming cells are immunotolerated and participate at post-ischemic angiogenesis in an original dorsal chamber immunocompetent mouse model

International audienceBackground: Cardiovascular diseases are the main cause of morbidity and mortality worldwide. Restoring blood supply to ischemic tissues is an essential goal for the successful treatment of these diseases. Growth factor or gene therapy efficacy remains controversial, but stem cell transplantation is emerging as an interesting approach to stimulate angiogenesis. Among the different stem cell populations, cord blood-endothelial progenitor cells (CB-EPCs) and more particularly cord blood-endothelial progenitor cell-derived endothelial colony forming cells (CB-ECFCs) have a great proliferative potential without exhibiting signs of senescence. Even if it was already described that CB-ECFCs were able to restore blood perfusion in hind-limb ischemia in an immunodeficient mouse model, until now, the immunogenic potential of allogenic CB-ECFCs remains controversial. Therefore, our objectives were to evaluate the immune tolerance potency of CB-ECFCs and their capacity to restore a functional vascular network under ischemic condition in immunocompetent mice. Methods: In vitro, the expression and secretion of immunoregulatory markers (HLA-G, IL-10, and TGF-β1) were evaluated on CB-ECFCs. Moreover, CB-ECFCs were co-cultured with activated peripheral blood mononuclear cells (PBMCs) for 6 days. PBMC proliferation was evaluated by [3H]-thymidine incorporation on the last 18 h. In vivo, CB-ECFCs were administered in the spleen and muscle of immunocompetent mice. Tissues were collected at day 14 after surgery. Finally, CB-ECFCs were injected intradermally in C57BL/6JRj mice close to ischemic macrovessel induced by thermal cauterization. Mice recovered until day 5 and were imaged, twice a week until day 30