The only available option to treat radiation-induced hematopoietic syndrome is allogeneic hematopoietic cell transplantation, a therapy unavailable to many patients undergoing treatment for malignancy, which would also be infeasible in a radiological disaster. Stromal cells serve as critical components of the hematopoietic stem cell niche and are thought to protect hematopoietic cells under stress. Prior studies that have transplanted mesenchymal stromal cells (MSCs) without co-administration of a hematopoietic graft have shown underwhelming rescue of endogenous hematopoiesis and have delivered the cells within 24 h of radiation exposure. Herein, we examine the efficacy of a human bone marrow-derived MSC therapy delivered at 3 h or 30 h in ameliorating radiation-induced hematopoietic syndrome and show that pancytopenia persists despite MSC therapy. Animals exposed to radiation had poorer survival and experienced loss of leukocytes, platelets, and red blood cells. Importantly, mice that received a therapeutic dose of MSCs were significantly less likely to die but experienced equivalent collapse of the hematopoietic system. The cause of the improved survival was unclear, as complete blood counts, splenic and marrow cellularity, numbers and function of hematopoietic stem and progenitor cells, and frequency of niche cells were not significantly improved by MSC therapy. Moreover, human MSCs were not detected in the bone marrow. MSC therapy reduced crypt dropout in the small intestine and promoted elevated expression of growth factors with established roles in gut development and regeneration, including PDGF-A, IGFBP-3, IGFBP-2, and IGF-1. We conclude that MSC therapy improves survival not through overt hematopoietic rescue but by positive impact on other radiosensitive tissues, such as the intestinal mucosa. Collectively, these data reveal that MSCs could be an effective countermeasure in cancer patients and victims of nuclear accidents but that MSCs alone do not significantly accelerate or contribute to recovery of the blood system.
Background- The use of the Resuscitative Endovascular Balloon Occlusion (REBOA) device is expanding in adult trauma. Reports of its use in pediatric patients have been published but no guidelines are established nor has it been FDA approved in pediatric use. Methods- 289 CT scans were reviewed to determine the average aortic diameter at the xyphoid process and umbilicus for each Broselow category. These measurements were the basis of 3D printed aortas using TangoPlus FullCure 930®. These aortas were inserted into a circulatory system model featuring two tracks to simulate thoracic and cerebral perfusion. Sonographic flow meters and pressure monitors were placed throughout and flow and pressure readings were recorded as a REBOA device was inflated in the printed aorta segment. Results- Distal aortic flow and pressure decreased while the cerebral branch demonstrated an inverse increase in flow and pressure with REBOA inflation. An initial delay between inflation and flow occlusion was noted with the initial 50% of volume inflated causing a 10% reduction in flow. The REBOA balloon inflation volumes (cc) for each Broselow Category for zone 1 and 3 are as follows: Black 7.5 & 5.5, Green 6 & 3.5, Orange 5.5 & 3, Blue 5 & 2, White 3 & 1.5 Conclusions- Pediatric patients present with a range of vessel sizes that occlude with a range of REBOA balloon inflation volumes. This study provides a basis to establish initial inflation volumes for REBOA deployment in appropriate pediatric trauma patients.
Enhancing Mesenchymal Stromal Cell Potency: Inflammatory Licensing via Mechanotransduction
Mesenchymal stromal cells (MSC) undergo functional maturation upon their migration from bone marrow and introduction to a site of injury. This inflammatory licensing leads to heightened immune regulation via cell-to-cell interaction and the secretion of immunomodulatory molecules, such as anti-inflammatory mediators and antioxidants. Pro-inflammatory cytokines are a recognized catalyst of inflammatory licensing; however, biomechanical forces, such as fluid shear stress, are a second, distinct class of stimuli that incite functional maturation. Here we show mechanotransduction, achieved by exposing MSC to various grades of wall shear stress (WSS) within a scalable conditioning platform, enhances the immunomodulatory potential of MSC independent of classical pro-inflammatory cytokines. A dose-dependent effect of WSS on potency is evidenced by production of prostaglandin E2 (PGE2) and indoleamine 2,3 dioxygenase 1 (IDO1), as well as suppression of tumor necrosis factor-α (TNF- α) and interferon-γ (IFN-γ) production by activated immune cells. Consistent, reproducible licensing is demonstrated in adipose tissue and bone marrow human derived MSC without significant impact on cell viability, cellular yield, or identity. Transcriptome analysis of WSS-conditioned BM-MSC elucidates the broader phenotypic implications on the differential expression of immunomodulatory factors. These results suggest mechanotransduction as a viable, scalable pre-conditioning alternative to pro-inflammatory cytokines. Enhancing the immunomodulatory capacity of MSC via biomechanical conditioning represents a novel cell therapy manufacturing approach.
Platelet contraction provides a minimally invasive source for physiologic information. In this article, we describe a device that directly measures the kinetics of platelet contraction. Whole blood is injected between acrylic plates and an adherent clot forms. The bottom plate is fixed, and the top plate is attached to a wire cantilever. Platelet contraction drives deflection of the wire cantilever which is captured by a camera. Force generated by the clot with time is derived using beam equations. Force derivations were verified using a microelectromechanical (MEMS) force sensor. Kinetics of clot contraction were defined, including maximum contraction force (FMAX), lift-off time (TLIFTOFF), and contraction rate (CR). Metrics were compared with optical aggregometry and thromboelastography. FMAX correlates with optical aggregometry maximal amplitude with a Spearman's rho of 0.7904 and p = 0.0195 and thromboelastography maximal amplitude with a Spearman's rho of 0.8857 and p = 0.0188. Lift-off time correlates with optical aggregometry lag time with a Spearman's rho of 0.9048 and p = 0.002. This preliminary study demonstrates the repeatability of a useful platelet contraction device and its correlation with thromboelastography and optical aggregometry, the gold standard platelet function test.
The immune system plays critical roles in promoting tissue repair during recovery from neurotrauma but is also responsible for unchecked inflammation that causes neuronal cell death, systemic stress, and lethal immunodepression. Understanding the immune response to neurotrauma is an urgent priority, yet current models of traumatic brain injury (TBI) inadequately recapitulate the human immune response. Here, we report the first description of a humanized model of TBI and show that TBI places significant stress on the bone marrow. Hematopoietic cells of the marrow are regionally decimated, with evidence pointing to exacerbation of underlying graft-versus-host disease (GVHD) linked to presence of human T cells in the marrow. Despite complexities of the humanized mouse, marrow aplasia caused by TBI could be alleviated by cell therapy with human bone marrow mesenchymal stromal cells (MSCs). We conclude that MSCs could be used to ameliorate syndromes triggered by hypercytokinemia in settings of secondary inflammatory stimulus that upset marrow homeostasis such as TBI. More broadly, this study highlights the importance of understanding how underlying immune disorders including immunodepression, autoimmunity, and GVHD might be intensified by injury. Traumatic brain injury (TBI) is a major contributor to long-term disability and mortality in children and adults, and, despite intensive efforts, there are no effective treatments for TBI 1,2. Sequelae of TBI and soft tissue injuries resulting from polytrauma include changes in cerebral metabolism, excitotoxicity, induction of emergency hematopoiesis, infiltration of fluid and inflammatory cells into the brain, systemic cytokine storm and localized cytokine release, and activation of microglia, the resident macrophage of the central nervous system 3-8. The immune system plays critical roles in promoting tissue repair and clearance of dying neurons during recovery from neurotrauma but is also responsible for the deleterious inflammation that kills healthy neurons. Systemic immunodepression and vulnerability to infection often follow the acute phase of TBI wherein hypercytokinemia and inflammation resolve, placing patients at increased risk of pneumonia and sepsis 9. Thus, understanding the contribution of the immune system to recovery is critical to development of efficacious therapies for neurotrauma 10,11 .
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