In vivo visualization and portally repeated transplantation of bone marrow cells in rats with liver damage

Role of granulocyte colony stimulating factor in the treatment of cirrhosis of liver: a systematic review

OBJECTIVE

We performed a systematic review to analyze the benefits of and risk factors associated with granulocyte colony stimulating factor (GCSF) in patients with liver cirrhosis.

METHODS

PubMed, Scopus, and Embase were searched for randomized controlled trials and case-control studies that compared the use of GCSF with another treatment or control group. The Jadad and Newcastle-Ottawa scales were used to assess the risk of bias in the included studies. The primary outcome studied was mortality; and the secondary outcomes were the disease severity score, liver transplantation criteria, complications, CD34+ cell count, adverse events, and health-related quality of life (HRQOL). PROSPERO registration number CRD42023416014.

RESULTS

The initial search yielded 2,235 studies, of which seven studies of 670 patients with liver cirrhosis were included. Multiple cycles of GCSF significantly improved the survival rate, disease severity score, CD34+ cell count, and HRQOL; and significantly reduced the incidences of liver transplantation, ascites, infection, and hepatic encephalopathy. Fatigue and backache were the most commonly reported adverse events.

CONCLUSION

GCSF significantly improves the survival rate and disease severity scores, and reduces the incidence of complications in patients with liver cirrhosis. The administration of GCSF is likely to be effective in patients awaiting liver transplantation.

Mesenchymal Stem Cells and Induced Bone Marrow-Derived Macrophages Synergistically Improve Liver Fibrosis in Mice

We describe a novel therapeutic approach for cirrhosis using mesenchymal stem cells (MSCs) and colony-stimulating factor-1-induced bone marrow-derived macrophages (id-BMMs) and analyze the mechanisms underlying fibrosis improvement and regeneration. Mouse MSCs and id-BMMs were cultured from mouse bone marrow and their interactions analyzed in vitro. MSCs, id-BMMs, and a combination therapy using MSCs and id-BMMs were administered to mice with CCl₄ -induced cirrhosis. Fibrosis regression, liver regeneration, and liver-migrating host cells were evaluated. Administered cell behavior was also tracked by intravital imaging. In coculture, MSCs induced switching of id-BMMs toward the M2 phenotype with high phagocytic activity. In vivo, the combination therapy reduced liver fibrosis (associated with increased matrix metalloproteinases expression), increased hepatocyte proliferation (associated with increased hepatocyte growth factor, vascular endothelial growth factor, and oncostatin M in the liver), and reduced blood levels of liver enzymes, more effectively than MSCs or id-BMMs monotherapy. Intravital imaging showed that after combination cell administration, a large number of id-BMMs, which phagocytosed hepatocyte debris and were retained in the liver for more than 7 days, along with a few MSCs, the majority of which were trapped in the lung, migrated to the fibrotic area in the liver. Host macrophages and neutrophils infiltrated after combination therapy and contributed to liver fibrosis regression and promoted regeneration along with administered cells. Indirect effector MSCs and direct effector id-BMMs synergistically improved cirrhosis along with host cells in mice. These studies pave the way for new treatments for cirrhosis. Stem Cells Translational Medicine 2019;8:271&284.

Engineering molecular imaging strategies for regenerative medicine

The reshaping of the world's aging population has created an urgent need for therapies for chronic diseases. Regenerative medicine offers a ray of hope, and its complex solutions include material, cellular, or tissue systems. We review basics of regenerative medicine/stem cells and describe how the field of molecular imaging, which is based on quantitative, noninvasive, imaging of biological events in living subjects, can be applied to regenerative medicine in order to interrogate tissues in innovative, informative, and personalized ways. We consider aspects of regenerative medicine for which molecular imaging will benefit. Next, genetic and nanoparticle-based cell imaging strategies are discussed in detail, with modalities like magnetic resonance imaging, optical imaging (near infra-red, bioluminescence), raman microscopy, and photoacoustic microscopy), ultrasound, computed tomography, single-photon computed tomography, and positron emission tomography. We conclude with a discussion of "next generation" molecular imaging strategies, including imaging host tissues prior to cell/tissue transplantation.

Cell Therapy for Liver Disease Using Bioimaging Rats

Advances in stem cell research suggest that cell therapy is a potential alternative to liver transplantation. The use of individualized and minimally invasive cell therapy is desirable to avoid rejection and reduce patient burden. While allo-hepatocyte transplantation has been performed for metabolic hepatic disease, auto-bone marrow transplantation (BMT) has shifted toward mesenchymal stem cells (MSCs) transplantation for liver cirrhosis. In this article, an overview of cell transplantation research for liver disease is provided through our recent rat studies. We have developed various kinds of rat imaging models and have evaluated the effect of cell therapy for liver disease. Bone marrow cells (BMCs) of the Alb-DsRed2 rat were transplanted via the portal vein (PV) in acute and chronic liver damage models. The number of Alb-DsRed2⁺ albumin-producing cells increased, and the size of the cells increased in the chronic liver damage model as well as in the acute liver damage model. Luciferase transgenic (luc-Tg) rat hepatocytes were transplanted into the hepatectomized LEW rat via the PV. Luminescence intensity lasted for 2 months in the hepatectomized rat. BMCs obtained from green fluorescent protein (GFP) Tg rats were transplanted repeatedly via the PV using an implanted catheter with a port. Repeated BMT via the PV reduced the liver fibrosis. Adipocyte-derived MSCs from the luc-Tg rat were transplanted into the hepatectomized rat model via the PV after ischemic reperfusion. MSCs inhibited hepatocyte apoptosis and promoted liver regeneration. Transplanting the optimal number of cells by an effective and safe way is important for clinical application. Bioimaging rats are a powerful tool for cell transplantation research because it makes observation of the in vivo kinetics of transplanted cells possible. Cell transplantation research using bioimaging rats contributes greatly to evaluating effective methods of cell therapy.

Repeated versus single transplantation of mesenchymal stem cells in carbon tetrachloride-induced liver injury in mice

Despite its numerous limitations, liver transplants are the only definite cure for end-stage liver disease. Various stem cell populations may contribute to liver regeneration, of which there is accumulating evidence of the contribution of mesenchymal stem cells (MSCs). This study examines the hypothesis that repeated infusions of human bone marrow-derived MSCs (hBMMSCs)can improve liver injury in an experimental model. MSCs were intravenously transplanted into immunosuppressed mice with carbon tetrachloride (CCl(4))-induced liver fibrosis. Transplanting 3x10(6) MSCs in three divided doses improved survival,liver fibrosis and necrosis compared with injection of the same number of MSCs in a single dose. This was accompanied by increased influence on the expression of the fibrogenic/fibrolytic related genes Col1a1, Timp1 and Mmp13 in the repeated transplant group. Repeat administration of MSCs was three times more effective in homing of PKH-tagged transplanted cells 3 weeks post-transplant compared with the single transplant group. The benefits of repeated transplants may be of considerable significance in clinical trials on liver failure.

Multiple courses of G-CSF in patients with decompensated cirrhosis: consistent mobilization of immature cells expressing hepatocyte markers and exploratory clinical evaluation

INTRODUCTION

Bone marrow-derived cells (BMCs) include stem cells capable of self-renewal and differentiation into a variety of cell types. Administration of granulocyte colony-stimulating factor (G-CSF) induces the circulation of BMCs in the peripheral blood. A phase II prospective trial was carried out for evaluation of BMC mobilization induced by multiple courses of G-CSF in cirrhotic patients.

PATIENTS AND METHODS

Fifteen patients with advanced liver cirrhosis (Child-Pugh score ≥6 points) were enrolled and treated with a 3-day G-CSF course, administered at 3-month intervals for a total of four courses. BMC mobilization was assessed by evaluating CD34+ve cells using flow cytometry. Expressions of multiple hepatic and stem markers were assessed on mobilized CD34+ve cells. Feasibility and safety were explored; clinical and adverse events were compared to those of a control group. Telomere length was monitored to rule out early cell aging caused by G-CSF.

RESULTS

A significant increase in G-CSF-induced circulating CD34+ve cells was consistently observed, although a progressive reduction of peak values was documented from cycle I to IV (p < 0.005). Mobilized CD34+ve cells expressed both stem and multiple hepatocyte markers, including mRNA of albumin and CYP2B6 (cytochrome P2 B6). Treatment was well tolerated, with no severe adverse events and no significant telomere length shortening following G-CSF. The procedure was safe. Overall, ten patients had either improved or had stable liver function tests (such as the Child-Pugh score), whereas five worsened and died from liver-related causes.

CONCLUSION

This study demonstrates that G-CSF can be safely administrated up to four times over a 1-year period in decompensated cirrhotic patients. The repeated BMC mobilization favors the circulation of stem cells coexpressing hepatic markers and mRNA of liver-related genes.

Transplantation of umbilical cord blood-derived mesenchymal stem cells for treatment of liver cirrhosis: Research progress

Cirrhosis is a serious threat to human health. Currently, there have been no available radical measures that can effectively block the process of this disease. The research progress in the field of stem cells brings an opportunity for the treatment of cirrhosis. Having a wide variety of sources, weak immunogenicity, and strong proliferation and differentiation ability, human umbilical cord blood-derived mesenchymal stem cells have been demonstrated to be promising in the treatment of liver cirrhosis. This article reviews the biological characteristics of human umbilical cord blood mesenchymal stem cells and their application in the treatment of cirrhosis.

Successful transplantation of reduced-sized rat alcoholic fatty livers made possible by mobilization of host stem cells

Livers from Lewis rats fed with 7% alcohol for 5 weeks were used for transplantation. Reduced sized (50%) livers or whole livers were transplanted into normal DA recipients, which, in this strain combination, survive indefinitely when the donor has not been fed alcohol. However, none of the rats survived a whole fatty liver transplant while six of seven recipients of reduced sized alcoholic liver grafts survived long term. SDF-1 and HGF were significantly increased in reduced size liver grafts compared to whole liver grafts. Lineage-negative Thy-1+CXCR4+CD133+ stem cells were significantly increased in the peripheral blood and in allografts after reduced size fatty liver transplantation. In contrast, there were meager increases in cells reactive with anti Thy-1, CXCR4 and CD133 in peripheral blood and allografts in whole alcoholic liver recipients. The provision of plerixafor, a stem cell mobilizer, salvaged 5 of 10 whole fatty liver grafts. Conversely, blocking SDF-1 activity with neutralizing antibodies diminished stem cell recruitment and four of five reduced sized fatty liver recipients died. Thus chemokine insufficiency was associated with transplant failure of whole grafts, which was overcome by the increased regenerative requirements promoted by the small grafts and mediated by SDF-1 resulting in stem cell influx.

Immediate intraportal transplantation of human bone marrow mesenchymal stem cells prevents death from fulminant hepatic failure in pigs

The effectiveness of human bone marrow mesenchymal stem cell (hBMSC) transplantation to treat acute and chronic liver injury has been demonstrated in animal models and in a few nonrandomized clinical trials. However, no studies have investigated hBMSC transplantation in the treatment of fulminant hepatic failure (FHF), especially in large animal (pig) models. The aim of this study was to demonstrate the safety, effectiveness, and underlying mechanism of hBMSC transplantation for treating FHF in pigs through the intraportal route. Human BMSCs (3 × 10(7) ) were transplanted into pigs with FHF via the intraportal route or peripheral vein immediately after D-galactosamine injection, and a sham group underwent intraportal transplantation (IPT) without cells (IPT, peripheral vein transplantation [PVT], and control groups, respectively, n = 15 per group). All of the animals in the PVT and control groups died of FHF within 96 hours. In contrast, 13 of 15 animals in the IPT group achieved long-term survival (>6 months). Immunohistochemistry demonstrated that transplanted hBMSC-derived hepatocytes in surviving animals were widely distributed in the hepatic lobules and the liver parenchyma from weeks 2 to 10. Thirty percent of the hepatocytes were hBMSC-derived. However, the number of transplanted cells decreased significantly at week 15. Only a few single cells were scattered in the regenerated liver lobules at week 20, and the liver tissues exhibited a nearly normal structure.

CONCLUSION

Immediate IPT of hBMSCs is a safe and effective treatment for FHF. The transplanted hBMSCs may quickly participate in liver regeneration via proliferation and transdifferentiation into hepatocytes during the initial stage of FHF. This method can possibly be used in future clinical therapy.

In Vivo Bioimaging Rats for Translational Research in Cell and Tissue Transplantation

The rat is an excellent cell transplantation model. In accordance with the innovative development of in vivo bioimaging technology, over the last decade we have been developing an engineered rat system based on transgenic technology and have been demonstrating the usefulness of the system with genetically encoded imaging probes such as fluorescent and luminescent proteins. In cooperation with the Japan Society for Organ Preservation and Medical Biology (President: Professor T. Asano), we have also been using luciferase-Tg rats for research into organ preservation and cell transplantation. In this minireview, we introduce the results obtained recently by using these powerful experimental tools during international collaboration in cell transplantation research.

Transcriptional profiling and hepatogenic potential of acute hepatic failure-derived bone marrow mesenchymal stem cells

Liver stem cell (LSC) transplantation is a promising alternate approach to liver transplantation for patients with end-stage liver disease. However, the precise origin of LSCs remains unclear. Herein we determine if bone marrow mesenchymal stem cells (BMSCs) isolated from rats in acute hepatic failure (AHF) possess hepatic characteristics and have differentiation potential. BMSCs were isolated from AHF and sham-operated rats, and primary hepatocytes were isolated from normal rats for comparison. The transcriptomic profile of BMSCs and primary hepatocytes was analyzed using the Affymetrix GeneChip Rat Genome 230 2.0 Array. BMSCs isolated from AHF and normal rats were induced to differentiate into hepatocytes in vitro and the degree of hepatic differentiation was assessed using quantitative real time RT-PCR, immunohistochemistry, and biochemical assays. AHF-derived BMSCs had a significantly different gene expression profile compared to control BMSCs. Thirty-four gene/probe sets were expressed in both AHF-derived BMSCs and primary hepatocytes, but were absent in control-derived BMSCs, including 3 hepatocyte-specific genes. Forty-four genes were up-regulated more than 2-fold in AHF-derived BMSCs compared to controls, including 3 genes involved in hepatocyte metabolism and development. Furthermore, AHF-derived BMSCs expressed more hepatocyte related genes than control BMSCs. Additional experiments to validate the differentiation of AHF-derived BMSCs, compared to control-derived BMSCs, showed that several hepatocyte-specific genes and proteins [such as albumin (ALB) and alpha fetoprotein (AFP)] were expressed earlier, and at higher levels, after 1 week of differentiation. Hepatocyte-specific metabolic functions were also significantly higher in the AHF group compared to control cells.

CONCLUSION

AHF-derived BMSCs had a hepatic transcriptional profile and expressed hepatocyte specific genes early during differentiation, and possessed greater hepatogenic potency in vitro compared to cells isolated from control animals, further confirming their potential as a stem cell-based therapy for end-stage liver disease.

Role of bone marrow stem cells in hepatic fibrosis

Differentiation of bone marrow stem cells into hepatocytes and their curative roles in liver fibrosis have gained increasing popularity recently. However, further investigation has shown a opposite idea that the bone marrow stem cells don't have this ability. Some researchers have proposed that bone marrow stem cells can differentiate into stellate cells or fibroblasts, hence serving as a participator of hepatic fibrosis. This article aims to review the role of bone marrow cells in hepatic fibrosis.

In vivo bioimaging using photogenic rats: fate of injected bone marrow-derived mesenchymal stromal cells

Mesenchymal stromal cells (MSCs) derived from bone marrow have the capacity for self-renewal and differentiation, and can give rise to cells of a muscle, bone, fat or cartilage lineage. Based on this potential and feasibility, MSCs are expected to be used in cell therapy for human diseases. Intriguingly, MSCs migrate to various in vivo locations, including injury and tumor sites. However, their cellular fate and distribution remain unclear. In this review, we first describe the potential of a photogenic transgenic rat that expresses fluorescent and/or luminescent proteins (e.g., green fluorescent protein and luciferase), and then focus on the characteristic migration of MSCs to injury and tumor sites. In addition, we will discuss an efficient delivery method for targeting the injured site. Synergized with modern advances in optical imaging, the photogenic rat system provides innovative preclinical tools and a new platform on which to further our understanding of matters concerning stem cell biology.