Enhance Cell Engraftment Research Articles

Reduced glutathione enhances adipose tissue‐derived mesenchymal stem cell engraftment efficiency for liver fibrosis by targeting TGFβ1/SMAD3/NOX4 pathway

AbstractReduced glutathione (GSH) could reduce oxidative stress to improve adipose tissue‐derived mesenchymal stem cell (ADSC) engraftment efficiency in vivo. However, the underlying mechanisms remain unclear. Our goal is to investigate whether GSH enhances ADSC engraftment through targeting the TGFβ/SMAD3/NOX4 pathway. Liver fibrotic male mice were administrated GSH, setanaxib (STX), and SIS3 during ADSC transplantation. ADSC engraftment efficiency and reactive oxygen species (ROS) level were detected both in vivo and ex vivo. Biochemical analysis was used to analyze the content of superoxide and nicotinamide adenine dinucleotide phosphate oxidases (NOXs) in liver tissues. Immunohistochemistry and western blotting were used to examine the protein level of NOX1, NOX2, NOX4, transforming growth factor‐β1 (TGFβ1), SMAD3, and p‐SMAD3 in liver tissues. Additionally, the therapeutic efficacy of the ADSC transplantation was further investigated. We found that GSH significantly improved ADSC engraftment efficiency, which was closely related to the reduced ROS generation in liver tissues. However, the enhanced cell engraftment was abolished after the combined treatment with STX or SIS3. GSH could effectively reduce superoxide and NOXs content, and selectively inhibit NOX4 expression in liver tissues. The co‐localization results showed that GSH could reduce NOX4 expressed in activated hepatic stellate cells. Mechanistically, GSH down‐regulated TGFβ/SMAD3 signaling. More importantly, GSH enhanced the therapeutic efficacy of ADSC therapy in liver fibrotic mice. Taken together, GSH could improve the engraftment efficiency of ADSCs in liver fibrosis by targeting TGFβ1/SMAD3/NOX4 signaling pathway, which provides a new theoretical basis for GSH enhancing ADSC engraftment efficiency in liver diseases.

Combined use of magnetic microbeads for endothelial cell isolation and enhanced cell engraftment in myocardial repair.

Background: The regenerative potential of the heart after injury is limited. Therefore, cell replacement strategies have been developed. However, the engraftment of transplanted cells in the myocardium is very inefficient. In addition, the use of heterogeneous cell populations precludes the reproducibility of the outcome. Methods: To address both issues, in this proof of principle study, we applied magnetic microbeads for combined isolation of eGFP+ embryonic cardiac endothelial cells (CECs) by antigen-specific magnet-associated cell sorting (MACS) and improved engraftment of these cells in myocardial infarction by magnetic fields. Results: MACS provided CECs of high purity decorated with magnetic microbeads. In vitro experiments revealed that the angiogenic potential of microbead-labeled CECs was preserved and the magnetic moment of the cells was strong enough for site-specific positioning by a magnetic field. After myocardial infarction in mice, intramyocardial CEC injection in the presence of a magnet resulted in a strong improvement of cell engraftment and eGFP+ vascular network formation in the hearts. Hemodynamic and morphometric analysis demonstrated augmented heart function and reduced infarct size only when a magnetic field was applied. Conclusion: Thus, the combined use of magnetic microbeads for cell isolation and enhanced cell engraftment in the presence of a magnetic field is a powerful approach to improve cell transplantation strategies in the heart.

Angiogenic stem cell delivery platform to augment post-infarction neovasculature and reverse ventricular remodeling

Many cell-based therapies are challenged by the poor localization of introduced cells and the use of biomaterial scaffolds with questionable biocompatibility or bio-functionality. Endothelial progenitor cells (EPCs), a popular cell type used in cell-based therapies due to their robust angiogenic potential, are limited in their therapeutic capacity to develop into mature vasculature. Here, we demonstrate a joint delivery of human-derived endothelial progenitor cells (EPC) and smooth muscle cells (SMC) as a scaffold-free, bi-level cell sheet platform to improve ventricular remodeling and function in an athymic rat model of myocardial infarction. The transplanted bi-level cell sheet on the ischemic heart provides a biomimetic microenvironment and improved cell–cell communication, enhancing cell engraftment and angiogenesis, thereby improving ventricular remodeling. Notably, the increased density of vessel-like structures and upregulation of biological adhesion and vasculature developmental genes, such as Cxcl12 and Notch3, particularly in the ischemic border zone myocardium, were observed following cell sheet transplantation. We provide compelling evidence that this SMC-EPC bi-level cell sheet construct can be a promising therapy to repair ischemic cardiomyopathy.

Co-administration of human MSC overexpressing HIF-1\u03b1 increases human CD34+ cell engraftment in vivo

BackgroundPoor graft function or graft failure after allogeneic stem cell transplantation is an unmet medical need, in which mesenchymal stromal cells (MSC) constitute an attractive potential therapeutic approach. Hypoxia-inducible factor-1α (HIF-1α) overexpression in MSC (HIF-MSC) potentiates the angiogenic and immunomodulatory properties of these cells, so we hypothesized that co-transplantation of MSC-HIF with CD34+ human cord blood cells would also enhance hematopoietic stem cell engraftment and function both in vitro and in vivo.MethodsHuman MSC were obtained from dental pulp. Lentiviral overexpression of HIF-1α was performed transducing cells with pWPI-green fluorescent protein (GFP) (MSC WT) or pWPI-HIF-1α-GFP (HIF-MSC) expression vectors. Human cord blood CD34+ cells were co-cultured with MSC WT or HIF-MSC (4:1) for 72 h. Then, viability (Annexin V and 7-AAD), cell cycle, ROS expression and immunophenotyping of key molecules involved in engraftment (CXCR4, CD34, ITGA4, c-KIT) were evaluated by flow cytometry in CD34+ cells. In addition, CD34+ cells clonal expansion was analyzed by clonogenic assays. Finally, in vivo engraftment was measured by flow cytometry 4-weeks after CD34+ cell transplantation with or without intrabone MSC WT or HIF-MSC in NOD/SCID mice.ResultsWe did not observe significant differences in viability, cell cycle and ROS expression between CD34+ cells co-cultured with MSC WT or HIF-MSC. Nevertheless, a significant increase in CD34, CXCR4 and ITGA4 expression (p = 0.009; p = 0.001; p = 0.013, respectively) was observed in CD34+ cells co-cultured with HIF-MSC compared to MSC WT. In addition, CD34+ cells cultured with HIF-MSC displayed a higher CFU-GM clonogenic potential than those cultured with MSC WT (p = 0.048). We also observed a significant increase in CD34+ cells engraftment ability when they were co-transplanted with HIF-MSC compared to CD34+ co-transplanted with MSC WT (p = 0.016) or alone (p = 0.015) in both the injected and contralateral femurs (p = 0.024, p = 0.008 respectively).ConclusionsCo-transplantation of human CD34+ cells with HIF-MSC enhances cell engraftment in vivo. This is probably due to the ability of HIF-MSC to increase clonogenic capacity of hematopoietic cells and to induce the expression of adhesion molecules involved in graft survival in the hematopoietic niche.

Bidirectional Relationship Between Cardiac Extracellular Matrix and Cardiac Cells in Ischemic Heart Disease

Ischemic heart diseases (IHDs), including myocardial infarction and cardiomyopathies, are a leading cause of mortality and morbidity worldwide. Cardiac-derived stem and progenitor cells have shown promise as a therapeutic for IHD but are limited by poor cell survival, limited retention, and rapid washout. One mechanism to address this is to encapsulate the cells in a matrix or three-dimensional construct, so as to provide structural support and better mimic the cells' physiological microenvironment during administration. More specifically, the extracellular matrix (ECM), the native cellular support network, has been a strong candidate for this purpose. Moreover, there is a strong consensus that the ECM and its residing cells, including cardiac stem cells, have a constant interplay in response to tissue development, aging, disease progression, and repair. When externally stimulated, the cells and ECM work together to mutually maintain the local homeostasis by initially altering the ECM composition and stiffness, which in turn alters the cellular response and behavior. Given this constant interplay, understanding the mechanism of bidirectional cell-ECM interaction is essential to develop better cell implantation matrices to enhance cell engraftment and cardiac tissue repair. This review summarizes current understanding in the field, elucidating the signaling mechanisms between cardiac ECM and residing cells in response to IHD onset. Furthermore, this review highlights recent advances in native ECM-mimicking cardiac matrices as a platform for modulating cardiac cell behavior and inducing cardiac repair.

Local Preirradiation of Infarcted Cardiac Tissue Substantially Enhances Cell Engraftment.

The success of cell therapy for the treatment of myocardial infarction depends on finding novel approaches that can substantially implement the engraftment of the transplanted cells. In order to enhance cell engraftment, most studies have focused on the pretreatment of transplantable cells. Here we have considered an alternative approach that involves the preconditioning of infarcted heart tissue to reduce endogenous cell activity and thus provide an advantage to our exogenous cells. This treatment is routinely used in other tissues such as bone marrow and skeletal muscle to improve cell engraftment, but it has never been taken in cardiac tissue. To avoid long-term cardiotoxicity induced by full heart irradiation we developed a rat model of a catheter-based heart irradiation system to locally impact a delimited region of the infarcted cardiac tissue. As proof of concept, we transferred ZsGreen+ iPSCs in the infarcted heart, due to their ease of use and detection. We found a very significant increase in cell engraftment in preirradiated rats. In this study, we demonstrate for the first time that preconditioning the infarcted cardiac tissue with local irradiation can substantially enhance cell engraftment.

A rationally designed self-immolative linker enhances the synergism between a polymer-rock inhibitor conjugate and neural progenitor cells in the treatment of spinal cord injury

Rho/ROCK signaling induced after spinal cord injury (SCI) contributes to secondary damage by promoting apoptosis, inflammation, and axon growth inhibition. The specific Rho-kinase inhibitor fasudil can contribute to functional regeneration after SCI, although inherent low stability has hampered its use. To improve the therapeutic potential of fasudil, we now describe a family of rationally-designed bioresponsive polymer-fasudil conjugates based on an understanding of the conditions after SCI, such as low pH, enhanced expression of specific proteases, and a reductive environment. Fasudil conjugated to poly-l-glutamate via a self-immolative redox-sensitive linker (PGA-SS-F) displays optimal release kinetics and, consequently, treatment with PGA-SS-F significantly induces neurite elongation and axon growth in dorsal root ganglia explants, spinal cord organotypic cultures, and neural precursor cells (NPCs). The intrathecal administration of PGA-SS-F after SCI in a rat model prevents early apoptosis and induces the expression of axonal growth- and neuroplasticity-associated markers to a higher extent than the free form of fasudil. Moreover, a combination treatment comprising the acute transplantation of NPCs pre-treated with PGA-SS-F leads to enhanced cell engraftment and reduced cyst formation after SCI. In chronic SCI, combinatory treatment increases the preservation of neuronal fibers. Overall, this synergistic combinatorial strategy may represent a potentially efficient clinical approach to SCI treatment.

Intramyocardial delivery of human cardiac stem cell spheroids with enhanced cell engraftment ability and cardiomyogenic potential for myocardial infarct repair

Strategies for stem cell-based cardiac regeneration and repair are key issues for the ischemic heart disease (IHD) patients with chronic complications related to ischemic necrosis. Cardiac stem cells (CSCs) have demonstrated high therapeutic efficacy for IHD treatment owing to their specific cardiac-lineage commitment. The therapeutic potential of CSCs could be further enhanced by designing a cellular spheroid formulation. The spheroid culture condition of CSCs was optimized to ensure regulated size and minimal core necrosis in the spheroids. The CSC spheroids revealed mRNA profiles of the factors related to cardiac regeneration, angiogenesis, anti-inflammatory, and cardiomyocyte differentiation with a higher expression level than the CSCs. Intramyocardially delivered CSC spheroids in the rat IHD model resulted in a significant increase in retention rate by 1.82-fold (day 3) and 1.98-fold (day 14) compared to CSCs. Endothelial cell differentiation and neovascularization of the engrafted CSC spheroids were noted in the infarcted myocardium. CSC spheroids significantly promoted cardiac regeneration: i.e., decreased infarction and fibrotic area (11.22% and 4.18%) and increased left ventricle thickness (0.62 mm) compared to the untreated group. Cardiac performance was also improved by 2.04-fold and 1.44-fold increase in the ejection fraction and fractional shortening, respectively. Intramyocardial administration of CSC spheroids might serve as an advanced therapeutic modality with enhanced cell engraftment and regenerative abilities for cardiac repair after myocardial infarction.

Polymer Cell Surface Coating Enhances Mesenchymal Stem Cell Retention and Cardiac Protection.

Mesenchymal stem cell (MSC) therapy has been widely tested in clinical trials to promote healing post-myocardial infarction. However, low cell retention and the need for a large donor cell number in human studies remain a key challenge for clinical translation. Natural biomaterials such as gelatin are ideally suited as scaffolds to deliver and enhance cell engraftment after transplantation. A potential drawback of MSC encapsulation in the hydrogel is that the bulky matrix may limit their biological function and interaction with the surrounding tissue microenvironment that conveys important injury signals. To overcome this limitation, we adopted a gelatin methacrylate (gelMA) cell-coating technique that photocross-links gelatin on the individual cell surface at the nanoscale. The present study investigated the cardiac protection of gelMA coated, hypoxia preconditioned MSCs (gelMA-MSCs) in a murine myocardial infarction (MI) model. We demonstrate that the direct injection of gelMA-MSC results in significantly higher myocardial engraftment 7 days after MI compared to uncoated MSCs. GelMA-MSC further amplified MSC benefits resulting in enhanced cardioprotection as measured by cardiac function, scar size, and angiogenesis. Improved MSC cardiac retention also led to a greater cardiac immunomodulatory function after injury. Taken together, this study demonstrated the efficacy of gelMA-MSCs in treating cardiac injury with a promising potential to reduce the need for donor MSCs through enhanced myocardial engraftment.

Vascular endothelial growth factor sustained delivery augmented cell therapy outcomes of cardiac progenitor cells for myocardial infarction.

Cell therapy has become a novel promising approach for improvement of cardiac functional capacity in the instances of ventricular remodeling and fibrosis caused by episodes of coronary artery occlusion and hypoxia. The challenge toward enhancing cell engraftment as well as formation of functional tissue, however, necessitated combinatorial approaches. Here, we complemented human embryonic stem cell-derived cardiac progenitor cell (hESC-CPC) therapy by heparin-conjugated, vascular endothelial growth factor (VEGF)-loaded fibrin hydrogel as VEGF delivery system. Transplantation of these cardiac committed cells along with sustained VEGF release could surpass the cardiac repair effects of each constituent alone in a rat model of acute myocardial infarction. The histological sections of rat hearts revealed improved vascularization as well as inclusion of hESC-CPC-derived cardiomyocytes, endothelial, and smooth muscle cells in host myocardium. Thus, co-transplantation of hESC-CPC and proangiogenic factor by a suitable delivery rate may resolve the shortcomings of conventional cell therapy.

Concise Review: Reduction of Adverse Cardiac Scarring Facilitates Pluripotent Stem Cell-Based Therapy for Myocardial Infarction.

Pluripotent stem cells (PSCs) are an attractive, reliable source for generating functional cardiomyocytes for regeneration of infarcted heart. However, inefficient cell engraftment into host tissue remains a notable challenge to therapeutic success due to mechanical damage or relatively inhospitable microenvironment. Evidence has shown that excessively formed scar tissues around cell delivery sites present as mechanical and biological barriers that inhibit migration and engraftment of implanted cells. In this review, we focus on the functional responses of stem cells and cardiomyocytes during the process of cardiac fibrosis and scar formation. Survival, migration, contraction, and coupling function of implanted cells may be affected by matrix remodeling, inflammatory factors, altered tissue stiffness, and presence of electroactive myofibroblasts in the fibrotic microenvironment. Although paracrine factors from implanted cells can improve cardiac fibrosis, the transient effect is insufficient for complete repair of an infarcted heart. Furthermore, investigation of interactions between implanted cells and fibroblasts including myofibroblasts helps the identification of new targets to optimize the host substrate environment for facilitating cell engraftment and functional integration. Several antifibrotic approaches, including the use of pharmacological agents, gene therapies, microRNAs, and modified biomaterials, can prevent progression of heart failure and have been developed as adjunct therapies for stem cell‐based regeneration. Investigation and optimization of new biomaterials is also required to enhance cell engraftment of engineered cardiac tissue and move PSCs from a laboratory setting into translational medicine.

Multifunctionalization of Cells with a Self-Assembling Molecule to Enhance Cell Engraftment.

Cell-based therapy is a promising approach to restoring lost functions to compromised organs. However, the issue of inefficient cell engraftment remains to be resolved. Herein, we take a chemical approach to facilitate cell engraftment by using self-assembling molecules which modify two cellular traits: cell survival and invasiveness. In this system, the self-assembling molecule induces syndecan-4 clusters on the cellular surface, leading to enhanced cell viability. Further integration with Halo-tag technology provided this self-assembly structure with matrix metalloproteinase-2 to functionalize cells with cell-invasion activity. In vivo experiments showed that the pretreated cells were able to survive injection and then penetrate and engraft into the host tissue, demonstrating that the system enhances cell engraftment. Therefore, cell-surface modification via an alliance between self-assembling molecules and ligation technologies may prove to be a promising method for cell engraftment.

Development of perfusion bioreactor for whole organ engineering — a culture system that enhances cellular engraftment, survival and phenotype of repopulated pancreas

Whole organ engineering has emerged as a promising alternative avenue to fill the gap of donor organ shortage in organ transplantation. Recent breakthroughs in the decellularization of solid organs and repopulation with desired cell populations have generated neo-organ constructs with promising functional outcomes. The realization of this goal requires engineering advancement in the perfusion-based bioreactors to (i) efficiently deliver decellularization agents, followed by (ii) its reconstruction with relevant cell types and (iii) maintenance of viability and function of the repopulated organ. In this study, we report the development and assembly of a perfusion bioreactor with the potential to enable regenerative reconstruction of pancreas. The assembled bioreactor is versatile to efficiently decellularize multiple organs, as demonstrated by complete decellularization of pancreas, liver and heart in the same set-up. Further, the same system is amenable to support organ repopulation with diverse cell types. Using our in-house bioreactor system, we demonstrate pancreas repopulation with both immortalized MIN-6 beta cells and differentiating human pluripotent stem cells. Importantly, we show the significant advantage of perfusion culture over static culture in enhancing cell engraftment, viability and phenotypic maintenance of the repopulated pancreas. In addition, this study is a significant step forward for whole organ engineering as it will facilitate cost-effective and easy assembly of perfusion bioreactors to enable rapid advancement in regenerative organ reconstruction.

Characterizing Exogenous Cell Engraftment for Cystic Fibrosis Cell Therapy

Cell therapy is a potential method for treating cystic fibrosis (CF), although cell engraftment into the highly resistive, pseudostratified human bronchial epithelium (HBE) is a major challenge. Transient epithelial injury is an approach to improve cell uptake, but the extent of injury required and the ability of cells grown by alternative methods to engraft are poorly understood. Our overarching hypothesis is that compounds such as polidocanol, an FDA approved drug used to sclerose varicose veins, can increase cell engraftment by targeting luminal barrier cells. To test this hypothesis, we engrafted exogenous, adenovirus‐EGFP transduced primary human airway epithelial cells into well‐differentiated air‐liquid interface (ALI) HBE cell cultures following treatment with varying doses of polidocanol. Quantitation of cell engraftment demonstrated that 0.125% polidocanol increased engraftment without causing overall ALI cell culture lysis. Further confocal microscopy characterization of the polidocanol injury indicates that engraftment does not require epithelial denudation to the level of the basal lamina. Primary HBE ALI cultures were then injured with polidocanol and the recovery of transepithelial electrical resistance was tracked over time after addition of no cells, conventionally‐grown cells, or cells grown with the conditionally reprogrammed cell (CRC) method. Cell engraftment expedites epithelial restoration, and CRC‐grown cells encourage recovery sooner than conventionally‐grown cells. CF ALI HBE cell cultures engrafted with non‐CF cells were tested for functional CFTR recovery in Ussing chambers. CRC HBE cells engraft, persist and recapitulate CFTR function more effectively than conventionally‐grown cells. Our results suggest that transient polidocanol injury and the CRC culture method may be a viable approach to enhance cell engraftment for CF cell therapy.Support or Funding InformationSupported by CFF grants RANDELXX015 and BOUCHE15R0CF2015, and NIH grants U01HL111018 and P30DK065988.This abstract is from the Experimental Biology 2018 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Abstract 355: CardioClusters: Harnessing the Power of Multi-lineage Cardiac Stem Cells

Existing approaches to modify stem cells for myocardial regeneration desperately need innovative solutions that enhance cell engraftment and persistence. Although this deficiency has been attacked through combinatorial stem cell delivery, there is no evidence that these stem cell injections provide for direct cellular crosstalk to promote stem cell survival and proliferation. Therefore, we created a CardioCluster, a 3D microenvironment consisting of three defined cell populations from the human heart: c-kit + cardiac progenitor cells (CPCs), CD90 + /CD105 + mesenchymal stem cells (MSCs) and CD133 + endothelial progenitor cells (EPCs). The size of the CardioCluster can be controlled by the quantity of cells used to create the cluster, allowing them to be infused into the heart without being reduced to single cell suspensions as is the case for cardiosphere-derived cells where the structural and cell-cell contact information is lost when delivered. Unlike cardiospheres, these cardiac cells are combined into a rationally designed cluster with MSCs and CPCs in the central core and EPCs forming the outer layer. EPCs play a vital role in forming neovasculature that will connect the CardioClusters to living heart tissue not damaged by ischemia and allow for revascularization of the damaged myocardium. In vitro we have shown that EPCs are better able to form tubular networks on matrigel-coated plates compared to either CPCs or MSCs. MSCs reinforce the 3D structure by releasing growth factors that attract and maintain cells within the cluster, as well as release immunomodulatory signaling factors. Upon induction of an oxidative stress by hydrogen peroxide CardioClusters show improved cell survival with a lower percentage of apoptotic and/or necrotic cell populations compared to the three populations individually. Upon myocardial injection CardioClusters have been shown to maintain their 3D structural integrity. Future directions will be to assess long-term engraftment and regenerative potential in a mouse model of myocardial infarction.

Minimally Invasive Liver Preconditioning for Hepatocyte Transplantation in Rats.

In the context of cell transplantation in the liver parenchyma, preconditioning is essential to enhance cell engraftment and liver repopulation. The authors have developed a minimally invasive technique of temporary portal embolization using an absorbable material, called reversible portal vein embolization. We hereby describe the method for isolating hepatocytes from a donor rat before transplanting hepatocytes after reversible portal vein embolization in the recipient.

Fibers for hearts: A critical review on electrospinning for cardiac tissue engineering.

Cardiac cell therapy holds a real promise for improving heart function and especially of the chronically failing myocardium. Embedding cells into 3D biodegradable scaffolds may better preserve cell survival and enhance cell engraftment after transplantation, consequently improving cardiac cell therapy compared with direct intramyocardial injection of isolated cells. The primary objective of a scaffold used in tissue engineering is the recreation of the natural 3D environment most suitable for an adequate tissue growth. An important aspect of this commitment is to mimic the fibrillar structure of the extracellular matrix, which provides essential guidance for cell organization, survival, and function. Recent advances in nanotechnology have significantly improved our capacities to mimic the extracellular matrix. Among them, electrospinning is well known for being easy to process and cost effective. Consequently, it is becoming increasingly popular for biomedical applications and it is most definitely the cutting edge technique to make scaffolds that mimic the extracellular matrix for industrial applications. Here, the desirable physico-chemical properties of the electrospun scaffolds for cardiac therapy are described, and polymers are categorized to natural and synthetic.Moreover, the methods used for improving functionalities by providing cells with the necessary chemical cues and a more in vivo-like environment are reported.

Editorial: "How to Improve Cord Blood Transplantation: By Enhancing Cell Counts or Engraftment?".

Editorial: "How to Improve Cord Blood Transplantation: By Enhancing Cell Counts or Engraftment?".

Gelatin Microspheres as Vehicle for Cardiac Progenitor Cells Delivery to the Myocardium

Inadequate cell retention and survival in cardiac stem cell therapy seems to be reducing the therapeutic effect of the injected stem cells. In order to ameliorate their regenerative effects, various biomaterials are being investigated for their potential supportive properties. Here, gelatin microspheres (MS) are utilized as microcarriers to improve the delivery and therapeutic efficacy of cardiac progenitor cells (CPCs) in the ischemic myocardium. The gelatin MS, generated from a water-in-oil emulsion, are able to accommodate the attachment of CPCs, thereby maintaining their cardiogenic potential. In a mouse model of myocardial infarction, we demonstrated the ability of these microcarriers to substantially enhance cell engraftment in the myocardium as indicated by bioluminescent imaging and histological analysis. However, despite an observed tenfold increase in CPC numbers in the myocardium, echocardiography, and histology reveals that mice treated with MS-CPCs show marginal improvement in cardiac function compared to CPCs only. Overall, a straightforward and translational approach is developed to increase the retention of stem cells in the ischemic myocardium. Even though the current biomaterial setup with CPCs as cell source does not translate into improved therapeutic action, coupling this developed technology with stem cell-derived cardiomyocytes can lead to an effective remuscularization therapy.

Blockade of cell adhesion molecules enhances cell engraftment in a murine model of liver cell transplantation

AimOLT is the best alternative for patients with end-stage liver diseases. However, as the need for organs surpasses donor availability, alternatives to OLT are required. LCT could be a useful option versus OLT in several patients even though its low cell-engraftment hampers its efficiency. Endothelial cell barrier is the main obstacle for the implantation of cells into the parenchyma. Our study has focused on the modification of the endothelial barrier with monoclonal antibodies against adhesion molecules in order to increase cell engraftment in a mouse model of liver cell transplantation. MethodsAnti-mouse CD54 and anti-mouse CD61 antibodies were administered intrasplenically to healthy mice within 60min prior to stem cell transplantation. Animals were sacrificed either short term at 2h or middle term seven days after transplantation. Immunohistochemical techniques to detect alkaline phosphatase activity were used to identify the transplanted cells within the liver parenchyma. ResultsAnti-CD54 and anti-CD61 administration increases vascular patency and cell engraftment. This represents a 32% and 45% increase, respectively, of engrafted cells compared to the control (p<0.05). ConclusionModification of the vascular wall with monoclonal antibodies against endothelial adhesion molecules before cell transplantation enhances cell engraftment into the mouse liver.