Human Chondrocytes, Metabolism of Articular Cartilage, and Strategies for Application to Tissue Engineering.

Hyaline cartilage, which is characterized by the absence of vascularization and innervation, has minimal self-repair potential in case of damage and defect formation in the chondral layer. Chondrocytes are specialized cells that ensure the synthesis of extracellular matrix components, namely type II collagen and aggregen. On their surface, they express integrins CD44, α1ß1, α3ß1, α5ß1, α10ß1, αVß1, αVß3, and αVß5, which are also collagen-binding components of the extracellular matrix. This article aims to contribute to solving the problem of the possible repair of chondral defects through unique methods of tissue engineering, as well as the process of pathological events in articular cartilage. In vitro cell culture models used for hyaline cartilage repair could bring about advanced possibilities. Currently, there are several variants of the combination of natural and synthetic polymers and chondrocytes. In a three-dimensional environment, chondrocytes retain their production capacity. In the case of mesenchymal stromal cells, their favorable ability is to differentiate into a chondrogenic lineage in a three-dimensional culture.

Evaluation of Biocompatibility of PLA/PHB/TPS Polymer Scaffolds with Different Additives of ATBC and OLA Plasticizers.

One of the blends that is usable for 3D printing while not being toxic to cell cultures is the lactic acid (PLA)/polyhydroxybutyrate (PHB)/thermoplastic starch (TPS) blend. The addition of plasticizers can change the rate of biodegradation and the biological behavior of the material. In order to evaluate the potential of the PLA/PHB/TPS material in combination with additives (plasticizers: acetyl tributyl citrate (ATBC) and oligomeric lactic acid (OLA)), for use in the field of biomedical tissue engineering, we performed a comprehensive in vitro characterization of selected mixture materials. Three types of materials were tested: I: PLA/PHB/TPS + 25% OLA, II: PLA/PHB/TPS + 30% ATBC, and III: PLA/PHB/TPS + 30% OLA. The assessment of the biocompatibility of the materials included cytotoxicity tests, such as monitoring the viability, proliferation and morphology of cells and their deposition on the surface of the materials. The cell line 7F2 osteoblasts (Mus musculus) was used in the experiments. Based on the test results, the significant influence of plasticizers on the material was confirmed, with their specific proportions in the mixtures. PLA/PHB/TPS + 25% OLA was evaluated as the optimal material for biocompatibility with 7F2 osteoblasts. The tested biomaterials have the potential for further investigation with a possible change in the proportion of plasticizers, which can have a fundamental impact on their biological properties.

Impact of In Vitro Degradation on the Properties of Samples Produced by Additive Production from PLA/PHB-Based Material and Ceramics.

The present study deals with preparing a polymer-based material with incorporated ceramics and monitoring changes in properties after in vitro natural degradation. The developed material is a mixture of polymers of polylactic acid and polyhydroxybutyrate in a ratio of 85:15. Ceramic was incorporated into the prepared material, namely 10% hydroxyapatite and 10% tricalcium phosphate of the total volume. The material was processed into a filament form, and types of solid and porous samples were prepared using additive technology. These samples were immersed in three different solutions: physiological solution, phosphate-buffered saline, and Hanks' solution. Under constant laboratory conditions, changes in solution pH, material absorption, weight loss, changes in mechanical properties, and surface morphology were monitored for 170 days. The average value of the absorption of the solid sample was 7.07%, and the absorption of the porous samples was recorded at 8.33%, which means a difference of 1.26%. The least change in pH from the reference value of 7.4 was noted with the phosphate-buffered saline solution. Computed tomography was used to determine the cross-section of the samples. The obtained data were used to calculate the mechanical properties of materials after degradation. The elasticity modulus for both the full and porous samples degraded in Hanks' solution (524.53 ± 13.4 MPa) has the smallest deviation from the non-degraded reference sample (536.21 ± 22.69 MPa).

Interaction between Mesenchymal Stem Cells and the Immune System in Rheumatoid Arthritis.

Rheumatoid arthritis (RA) is an autoimmune disease that causes damage to joints. This review focuses on the possibility of influencing the disease through immunomodulation by mesenchymal stem cells (MSCs). There is an occurrence of rheumatoid factor and RA-specific autoantibodies to citrullinated proteins in most patients. Citrulline proteins have been identified in the joints of RA patients, and are considered to be the most suitable candidates for the stimulation of anti-citrulline protein antibodies production. Fibroblast-like proliferating active synoviocytes actively promote inflammation and destruction in the RA joint, in association with pro-inflammatory cells. The inflammatory process may be suppressed by MSCs, which are a population of adherent cells with the following characteristic phenotype: CD105+, CD73+, CD90+, CD45-, CD34- and HLA DR-. Following the stimulation process, MSCs are capable of immunomodulatory action through the release of bioactive molecules, as well as direct contact with the cells of the immune system. Furthermore, MSCs show the ability to suppress natural killer cell activation and dendritic cells maturation, inhibit T cell proliferation and function, and induce T regulatory cell formation. MSCs produce factors that suppress inflammatory processes, such as PGE2, TGF-ß, HLA-G5, IDO, and IL-10. These properties suggest that MSCs may affect and suppress the excessive inflammation that occurs in RA. The effect of MSCs on rheumatoid arthritis has been proven to be a suitable alternative treatment thanks to successful experiments and clinical studies.

In Vitro Model of Human Trophoblast in Early Placentation.

The complex process of placental implantation and development affects trophoblast progenitors and uterine cells through the regulation of transcription factors, cytokines, adhesion receptors and their ligands. Differentiation of trophoblast precursors in the trophectoderm of early ontogenesis, caused by the transcription factors, such as CDX2, TEAD4, Eomes and GATA3, leads to the formation of cytotrophoblast and syncytiotrophoblast populations. The molecular mechanisms involved in placental formation inside the human body along with the specification and differentiation of trophoblast cell lines are, mostly due to the lack of suitable cell models, not sufficiently elucidated. This review is an evaluation of current technologies, which are used to study the behavior of human trophoblasts and other placental cells, as well as their ability to represent physiological conditions both in vivo and in vitro. An in vitro 3D model with a characteristic phenotype is of great benefit for the study of placental physiology. At the same time, it provides great support for future modeling of placental disease.

Activation, homing, and role of the mesenchymal stem cells in the inflammatory environment.

Human mesenchymal stem cells (MSCs) are considered to be a promising source of cells in regenerative medicine. They have large potential to differentiate into various tissue-specific populations and may be isolated from diverse tissues in desired quantities. As cells of potential autologous origin, they allow recipients to avoid the alloantigen responses. They also have the ability to create immunomodulatory microenvironment, and thus help to minimize organ damage caused by the inflammation and cells activated by the immune system. Our knowledge about the reparative, regenerative, and immunomodulatory properties of MSCs is advancing. At present, there is a very comprehensible idea on how MSCs affect the immune system, particularly in relation to the tissue and organ damage on immunological basis. Hitherto a number of effective mechanisms have been described by which MSCs influence the immune responses. These mechanisms include a secretion of soluble bioactive agents, an induction of regulatory T cells, modulation of tolerogenic dendritic cells, as well as induction of anergy and apoptosis. MSCs are thus able to influence both innate and adaptive immune responses. Soluble factors that are released into local microenvironment with their subsequent paracrine effects are keys to the activation. As a result, activated MSCs contribute to the restoration of damaged tissues or organs through various mechanisms facilitating reparative and regenerative processes as well as through immunomodulation itself and differentiation into the cells of the target tissue.

Impact of different pancreatic microenvironments on improvement in hyperglycemia and insulin deficiency in diabetic rats after transplantation of allogeneic mesenchymal stromal cells.

BACKGROUND: Mesenchymal stromal cells (MSCs) in the pancreatic microenvironment can improve diabetes mellitus (DM). The aim of the present study was to determine whether different pancreatic microenvironments influence the improvement of hyperglycemia and insulin deficiency. METHODS: MSCs isolated from rat bone marrow were transplanted directly into different pancreatic microenvironments in male DM rats. DM was induced in the rats by streptozotocin injection. The rats were divided into 5 groups: normal control rats, DM control rats, and 3 experimental groups (DM rats plus MSCs injected into the head of the pancreas, the tail of the pancreas, or the whole pancreas). The body weight and blood glucose of the rats were monitored during the experiment after transplantation of the MSCs. Histopathologic and immunohistochemical analyses were used to detect the presence and number of islets and insulin production in the pancreatic tissue of the rats after MSC transplantation. RESULTS: At 28 days after MSC transplantation, we observed a statistically significant decrease in the blood glucose level and an increase in weight in DM rats compared with DM control rats (P < 0.0001 and P < 0.03, respectively). A comparison of each of the DM rat groups treated with MSCs showed no significant differences in the blood glucose levels or body weight. CONCLUSION: Our results suggest that transplantation of MSCs could improve DM in the pancreatic microenvironment in an animal model with streptozotocin-induced DM. The different pancreatic areas into which the MSCs were implanted had no significant influence on the improvement in hyperglycemia and insulin deficiency.

Isolation and basic characterization of human term amnion and chorion mesenchymal stromal cells.

BACKGROUND AIMS: Emerging evidence suggests human placental membrane is a valuable source of mesenchymal stromal cells (MSC). Amnion and chorion are tissues of early embryologic origin that may entail progenitor potential. These tissues are abundantly available and ethically unobjectionable and, because they are discarded post-partum, they can be widely used for extensive research and eventually for therapeutic studies. METHODS: We looked at the cells isolated from the six amnions and chorions of term placentas of gestational weeks 39 ± 1. Isolated cells were characterized by morphologic and immunophenotypic analysis. RESULTS: With flow cytometry immunophenotype analysis, amnion- and chorion-derived cells were positive for MSC markers, and negative for hematopoietic markers. Immunocytochemical staining was positive for the embryonic cell markers Oct-3/4 and Rex-1. Oct-3/4 is a POU transcription factor that is expressed in embryonic stem (ES) cells and germ cells, and its expression is required to sustain cell self-renewal and pluripotency. Oct-3/4 is the most recognized marker for totipotent ES cells. Rex-1 is a zinc finger family transcription factor that is highly expressed in embryonic stem cells. It is one of several gene markers used to identify undifferentiated stem cells, and its expression is downregulated upon stem cell differentiation. Amnion- and chorion-derived cells were capable, under differentiation conditions, to differentiate into to mesoderm lineages. CONCLUSIONS: Phenotypic studies indicate MSC-like profiles in both amnion- and chorion-derived cells. Cells in vitro had fibroblastoid morphology. The in vitro growth behavior of such placenta-derived progenitor cells was similar to that of bone marrow MSC. Our results indicate that MSC can be easily isolated from the human term placenta. The human amniotic and chorion MSC maintained a marker profile similar to the mesenchymal progenitors and could be used for studies as an alternative source of MSC for further application in cellular therapy.

Preliminary clinical experience with the preparation and therapeutic use of autologous osteoblasts and chondrocytes.

Particular results of autologous osteoblasts preparation from patient's bone marrow and autologous chondrocytes from cartilage, both for therapeutic application are given. Osteoblastic cells were cultivated from fresh bone marrow in the presence of dexamethasone in alpha MEM medium containing 10% of patient's and 10% of fetal bovine sera and other necessary additives without any cytokine stimuli. Alkaline phosphatase cell surface activity was used as a marker for quick osteoblastic phenotype confirmation. Autologous chondrocytes were enzymatically separated from fresh knee cartilage. Pieces of cartilage, 2 mm(3) in volume, were sufficient for live cellular graft preparation. Viability of chondrocytes obtained by this approach was more than 90%. In both cases, in osteoblasts as well as in chondrocytes, the amount of cells obtained during the 4 week culture, was sufficient for clinical use.