Liver cirrhosis: An overview of experimental models in rodents.

The liver, a component of the gastrointestinal tract, is one of the most important organs in the human body. The liver performs over 500 functions to promote physiological homeostasis. In addition, the liver acts as a screen, by metabolizing substances carried by blood coming from the digestive tract before they enter the systemic circulation. This vital function exposes the hepatic tissue to hepatotoxic agents, which can lead to liver damage if the organ's repair and regenerative capacity is insufficient. Several conditions such as persistent exposure to hepatitis C and B viruses, alcohol, and drugs can provoke this disbalance, eventually leading to liver cirrhosis, which is an irreversible and life-threatening condition. This paradigm of irreversibility began to be reconsidered when several studies showed that hepatic fibrosis is potentially reversible after cessation of exposure to the hepatotoxic agent or eradication of the primary disease. In the context of basic research in liver fibrosis and cirrhosis, it is essential to keep in mind that the capacity of the organ to recover spontaneously might be a significant limitation to long-term studies that use experimental models of liver cirrhosis. Here, we review animal models where liver cirrhosis is experimentally induced. We focus on a surgery-based model, i.e., bile duct ligation (BDL), and hepatotoxic drugs such as carbon tetrachloride (CCl4), thioacetamide (TAA), and dimethylnitrosamine (DMN) administrated alone or in association with alcohol, the latter to potentialize the hepatotoxic effect of these agents. Also, we analyze the effects of these approaches, emphasizing the risks, spontaneous reversibility, and outcomes on animal health.

Improving hemocompatibility of decellularized liver scaffold using Custodiol solution.

Organ decellularization is one of the most promising approaches of tissue engineering to overcome the shortage of organs available for transplantation. However, there are key hurdles that still hinder its clinical application, and the lack of hemocompatibility of decellularized materials is a central one. In this work, we demonstrate that Custodiol (HTK solution), a common solution used in organ transplantation, increased the hemocompatibility of acellular scaffolds obtained from rat livers. We showed that Custodiol inhibited ex vivo, in vitro, and in vivo blood coagulation to such extent that allowed successful transplantation of whole-liver scaffolds into recipient animals. Scaffolds previously perfused with Custodiol showed no signs of platelet aggregation and maintained in vitro and in vivo cellular compatibility. Proteomic analysis revealed that proteins related to platelet aggregation were reduced in Custodiol samples while control samples were enriched with thrombogenicity-related proteins. We also identified distinct components that could potentially be involved with this anti-thrombogenic effect and thus require further investigation. Therefore, Custodiol perfusion emerge as a promising strategy to reduce the thrombogenicity of decellularized biomaterials and could benefit several applications of whole-organ tissue engineering.

Optimizing the Decellularized Porcine Liver Scaffold Protocol.

There are few existing methods for shortening the decellularization period for a human-sized whole-liver scaffold. Here, we describe a protocol that enables effective decellularization of the liver obtained from pigs weigh 120 ± 4.2 kg within 72 h. Porcine livers (approx. 1.5 kg) were decellularized for 3 days using a combination of chemical and enzymatic decellularization agents. After trypsin, sodium deoxycholate, and Triton X-100 perfusion, the porcine livers were completely translucent. Our protocol was efficient to promote cell removal, the preservation of extracellular matrix (ECM) components, and vascular tree integrity. In conclusion, our protocol is efficient to promote human-sized whole-liver scaffold decellularization and thus useful to generate bioengineered livers to overcome the shortage of organs.

Safety of Allogeneic Canine Adipose Tissue-Derived Mesenchymal Stem Cell Intraspinal Transplantation in Dogs with Chronic Spinal Cord Injury.

This is a pilot clinical study primarily designed to assess the feasibility and safety of X-ray-guided percutaneous intraspinal injection of allogeneic canine adipose tissue-derived mesenchymal stem cells in dogs with chronic spinal cord injury. Six dogs with chronic paraplegia (≥six months) were intraparenchymally injected with allogeneic cells in the site of lesion. Cells were obtained from subcutaneous adipose tissue of a healthy dog, cultured to passage 3, labeled with 99mTechnetium, and transplanted into the lesion by percutaneous X-ray-guided injection. Digital X-ray efficiently guided cell injection as 99mTechnetium-labeled cells remained in the injection site for at least 24 hours after transplantation. No adverse effects or complications (infection, neuropathic pain, or worsening of neurological function) were observed during the 16-week follow-up period after transplantation. Three animals improved locomotion as assessed by the Olby scale. One animal walked without support, but no changes in deep pain perception were observed. We conclude that X-ray-guided percutaneous intraspinal transplantation of allogeneic cells in dogs with chronic spinal cord injury is feasible and safe. The efficacy of the treatment will be assessed in a new study involving a larger number of animals.

99m-Technetium binding site in bone marrow mononuclear cells.

INTRODUCTION: The increasing interest in 99m-technetium ((99m)Tc)-labeled stem cells encouraged us to study the (99m)Tc binding sites in stem cell compartments. METHODS: Bone marrow mononuclear cells were collected from femurs and tibia of rats. Cells were labeled with (99m)Tc by a direct method, in which reduced molecules react with (99m)Tc with the use of chelating agents, and lysed carefully in an ultrasonic apparatus. The organelles were separated by means of differential centrifugation. At the end of this procedure, supernatants and pellets were counted, and the percentages of radioactivity (in megabecquerels) bound to the different cellular fractions were determined. Percentages were calculated by dividing the radioactivity in each fraction by total radioactivity in the sample. The pellets were separated and characterized by their morphology on electron microscopy. RESULTS: The labeling procedure did not affect viability of bone marrow mononuclear cells. Radioactivity distributions in bone marrow mononuclear cell organelles, obtained in five independent experiments, were approximately 38.5 % in the nuclei-rich fraction, 5.3 % in the mitochondria-rich fraction, 2.2 % in microsomes, and 54 % in the cytosol. Our results showed that most of the radioactivity remained in the cytosol; therefore, this is an intracellular labeling procedure that has ribosomes unbound to membrane and soluble molecules as targets. However, approximately 39 % of the radioactivity remained bound to the nuclei-rich fraction. To confirm that cell disruption and organelle separation were efficient, transmission electron microscopy assays of all pellets were performed. CONCLUSIONS: Our results showed that most of the radioactivity was present in the cytosol fraction. More studies to elucidate the mechanisms involved in the cellular uptake of (99m)Tc in bone marrow cells are ongoing.

Bone marrow cells obtained from cirrhotic rats do not improve function or reduce fibrosis in a chronic liver disease model.

BACKGROUND: The objective of this study was to evaluate the therapeutic potential of bone marrow cells (BMCs) obtained from cirrhotic donors in a model of chronic liver disease. METHODS: Chronic liver injury was induced in female Wistar rats by the association of an alcoholic diet with intraperitoneal injections of carbon tetrachloride. BMCs obtained from cirrhotic donors or placebo were injected through the portal vein. Blood analysis of alanine aminotransferase (ALT) and albumin levels, ultrasound assessment including the measurement of the portal vein diameter (PVD) and liver echogenicity, histologic evaluation with hematoxylin and eosin and Sirius red staining, and quantification of collagen deposition were performed. RESULTS: ALT and albumin blood levels showed no significant differences between the experimental groups two months after injection. Additionally, no significant variation in PVD and liver echogenicity was found. Histological analysis also showed no significant variation in collagen deposition two months after placebo or BMC injection. CONCLUSION: This study suggests that, even though BMC therapy using cells from healthy donors has previously shown to be effective, this is not the case when BMCs are obtained from cirrhotic animals. This result has major clinical implications when considering the use of autologous BMCs from patients with chronic liver diseases.

Expression of c-kit and Sca-1 and their relationship with multidrug resistance protein 1 in mouse bone marrow mononuclear cells.

P-glycoprotein (Pgp) and multidrug resistance protein 1 (MRP1) are members of the ATP-binding cassette (ABC) family of transporter proteins. Both molecules are membrane-associated, energy-dependent efflux pumps with different substrate selectivity and they may play a role in the activation, differentiation and function of haematopoietic cells. Mouse haematopoietic cells are characterized by the expression of the cell surface molecules c-kit and Sca-1. Herein, the presence and activities of Pgp and MRP1 in mouse bone marrow mononuclear cells (BMMC) and their relationship with the proteins c-kit and Sca-1 were evaluated. Pgp and MRP activities were measured based on the extrusion of rhodamine 123 (for Pgp) and Fluo-3 (for MRP). Cell populations were assessed by cytometry using anti-c-kit and anti-Sca1 antibodies. Pgp activity was present in 5% of BMMC while 50% of BMMC cells showed MRP activity. These findings agreed with the proportion of cells expressing the MRP1 surface molecule (51.3 +/- 4.17%). About 14% of BMMC were positive for c-kit and/or Sca-1 (9.3% c-kit- Sca-1+, 4.2% c-kit+ Sca-1- and 0.9% c-kit+ Sca-1+). Among these subpopulations only c-kit- Sca-1+ cells presented Pgp activity (21.36%). On the other hand, MRP activity was present in all three subpopulations. Most cells (82.5%) of the c-kit+ Sca-1- subpopulation presented MRP1 activity compared to only 54.1% of c-kit+ Sca-1+ and 38.8% of c-kit- Sca-1+. This study demonstrates the expression and activity of MRP1 in BMMC. While only a small proportion of precursor cells had Pgp activity, MRP1 activity was present among different subpopulations of precursor cells. Further studies are necessary to establish the role of these transporters in haematopoietic cells.

G-CSF does not improve systolic function in a rat model of acute myocardial infarction.

OBJECTIVE: Granulocyte colony-stimulating factor (G-CSF) has been reported to improve cardiac performance by increasing the number of bone marrow stem cell in the peripheral circulation. The aim of this study was to investigate the impact of G-CSF administration on cardiac function in a rat model of acute myocardial infarction. METHODS: Recombinant human G-CSF (Filgrastim, 100 microg/kg, sc) twice a day during seven consecutive days (G-CSF group, n=13) or vehicle (control group, n=10) was administrated three hours after left anterior coronary artery ligation. Cardiac performance was evaluated 19-21 days after myocardial infarction by electro- and echocardiography, hemodynamic and treadmill exercise test. RESULTS: Both infarcted groups exhibit impaired cardiac function compared to sham-operated rats. Moreover, all cardiac functional parameters were not statistically different between G-CSF and infarcted group at resting conditions as well as after treadmill exercise stress test. There was no sign of cardiac regeneration and infarct size was not different on histological analysis between groups. CONCLUSIONS: These data clearly shows that G-CSF treatment was unable to prevent cardiac remodeling or to improve cardiovascular function in a rat model of acute myocardial infarction, by permanent LAD ligation, despite bone marrow stem cell mobilization.

Ectopic Ossification in the Scar Tissue of Rats with Myocardial Infarction.

We describe the occurrence of bone-like formations in the left ventricular wall of infarcted rats treated or not with bone marrow cells injected systemically or locally into the myocardium. The incidence of ectopic calcification in hearts has been reported in rare cases in children with infarcts without previous coronary artery disease. Recently, ventricular calcification has been correlated with unselected bone marrow cell transplantation into infarcted rat hearts. Echocardiographic analysis of large infarction in rats frequently reveals the presence of echogenic structures in the left ventricular wall, sometimes projecting to the lumen of the chamber. The histological examination of these echogenic structures exhibited bone, cartilage, and marrowlike formations extending from the collagen-rich matrix of the ventricle wall. Microanalytical techniques verified the presence of hydroxyapatite in the mineral phase. Ossification was found in 25 out of 30 hearts evaluated 90 days postinfarct, being observed in 14 out of 17 animals submitted to cell therapy and in 11 out of 13 infarcted rats not submitted to cell therapy. Our study indicates that chondro-osteogenic differentiation can take place in the pathological rat heart independent of animal treatment with marrow cells.