The use of mesenchymal stromal cells (MSCs) in regenerative medicine and tissue engineering is well established, given their properties of self-renewal and differentiation. However, several studies have shown that these properties diminish with age, and understanding the pathways involved are important to provide regenerative therapies in an ageing population. In this PRISMA systematic review, we investigated the effects of chronological donor ageing on the senescence of MSCs. We identified 3023 studies after searching four databases including PubMed, Web of Science, Cochrane, and Medline. Nine studies met the inclusion and exclusion criteria and were included in the final analyses. These studies showed an increase in the expression of p21, p53, p16, ROS, and NF- B with chronological age. This implies an activated DNA damage response (DDR), as well as increased levels of stress and inflammation in the MSCs of older donors. Additionally, highlighting the effects of an activated DDR in cells from older donors, a decrease in the expression of proliferative markers including Ki67, MAPK pathway elements, and Wnt/ -catenin pathway elements was observed. Furthermore, we found an increase in the levels of SA- -galactosidase, a specific marker of cellular senescence. Together, these findings support an association between chronological age and
Fracture nonunion is a severe clinical problem for the patient, as well as for the clinician. About 5-20% of fractures does not heal properly after more than six months, with a 19% nonunion rate for tibia, 12% for femur and 13% for humerus, leading to patient morbidity, prolonged hospitalization, and high costs. The standard treatment with iliac crest-derived autologous bone filling the nonunion site may cause pain or hematoma to the patient, as well as major complications such as infection. The application of mesenchymal autologous cells (MSC) to improve bone formation calls for randomized, open, two-arm clinical studies to verify safety and efficacy. The ORTHOUNION * project (ORTHOpedic randomized clinical trial with expanded bone marrow
Bone healing outcome is highly dependent on the initial mechanical fracture environment [1]. In vivo, direct bone healing requires absolute stability and an interfragmentary strain (IFS) below 2% [2]. In the majority of cases, however, endochondral ossification is engaged where frequency and amplitude of IFS are key factors. Still, at the cellular level, the influence of those parameters remains unknown. Understanding the regulation of naïve hMSC differentiation is essential for developing effective bone healing strategies. Human bone-marrow-derived
Background. Stem cell based intervertebral disc (IVD) regeneration is quickly moving towards clinical applications. However, many aspects need to be investigated to routinely translate this therapy to clinical applications, in particular, the most efficient way to deliver cell to the IVD. Cells are commonly delivered to the IVD through the annulus fibrosus (AF) injection. However, recent studies have shown serious drawbacks of this approach. As an alternative we have described and tested a new surgical approach to the IVD via the endplate-pedicles (transpedicular approach). The Purpose of the study was to test MSCs/hydrogel transplantation for IVD regeneration in a grade IV preclinical model of IDD on large size animals via the transpeducular approach with cell dose escalation. Methods. Adult sheep (n=18) underwent bone marrow aspiration for autologous
While mesenchymal stromal cells (MSCs) are a very attractive cell source for cartilage regeneration, an inherent tendency to undergo hypertrophic maturation and endochondral ossification; as well as insufficient extracellular matrix production still prevent their clinical application in cell –based cartilage repair therapies. We recently demonstrated that intermittent treatment of
Objectives. The aim of this study was to investigate the effect of granulocyte-colony stimulating factor (G-CSF) on mesenchymal stem cell (MSC) proliferation in vitro and to determine whether pre-microfracture systemic administration of G-CSF (a bone marrow stimulant) could improve the quality of repaired tissue of a full-thickness cartilage defect in a rabbit model. Methods. MSCs from rabbits were cultured in a control medium and medium with G-CSF (low-dose: 4 μg, high-dose: 40 μg). At one, three, and five days after culturing, cells were counted. Differential potential of cultured cells were examined by stimulating them with a osteogenic, adipogenic and chondrogenic medium. A total of 30 rabbits were divided into three groups. The low-dose group (n = 10) received 10 μg/kg of G-CSF daily, the high-dose group (n = 10) received 50 μg/kg daily by subcutaneous injection for three days prior to creating cartilage defects. The control group (n = 10) was administered saline for three days. At 48 hours after the first injection, a 5.2 mm diameter cylindrical osteochondral defect was created in the femoral trochlea. At four and 12 weeks post-operatively, repaired tissue was evaluated macroscopically and microscopically. Results. The cell count in the low-dose G-CSF medium was significantly higher than that in the control medium. The differentiation potential of MSCs was preserved after culturing them with G-CSF. Macroscopically, defects were filled and surfaces were smoother in the G-CSF groups than in the control group at four weeks. At 12 weeks, the quality of repaired cartilage improved further, and defects were almost completely filled in all groups. Microscopically, at four weeks, defects were partially filled with hyaline-like cartilage in the G-CSF groups. At 12 weeks, defects were repaired with hyaline-like cartilage in all groups. Conclusions. G-CSF promoted proliferation of MSCs in vitro. The systemic administration of G-CSF promoted the repair of damaged cartilage possibly through increasing the number of MSCs in a rabbit model. Cite this article: T. Sasaki, R. Akagi, Y. Akatsu, T. Fukawa, H. Hoshi, Y. Yamamoto, T. Enomoto, Y. Sato, R. Nakagawa, K. Takahashi, S. Yamaguchi, T. Sasho. The effect of systemic administration of G-CSF on a full-thickness cartilage defect in a rabbit model
Human mesenchymal stem cells (hMSC), residing in the bone marrow, can be purified, expanded in cell culture and under appropriate stimuli may differentiate along the osteogenic, chondrogenic and adipogenic lineages. The aim of this study was to investigate the expansion capability and differentiation potential of MSCs obtained from femur, pelvis and acetabular cancellous bone of aged patients in order to establish whether these cells, isolated and expanded in vitro, can be used in a new approach in orthopaedic revision surgery. In this preliminary study we enrolled 33 patients undergoing hip arthroplasty in order to investigate CFU-F frequency, expansion ability and differentiation potential of hMSC derived from three different anatomical sites: femural, pelvic and acetabular cancellous bone (ACB). CFU-F frequency (CFU-F/10 . 6. MNC) was 63 for pelvis (range 7–122), 90 for bone (39–132) and 47.5 for femur (7–124).CFU-F frequency was higher in ACB than in either pelvis (p=0.04) or femur (p=0.001). The patients were divided into three age groups: G1 ≤50 years (n=6), G2 50 −65 years (n=11), and G3 ≥65 years (n=16); however, CFU-F frequency did not show any statistically significant difference, although the frequency was lower at higher age. We expanded in cell culture
Aims: Surface modification of biomaterials to be used as scaffolds in tissue engineering is a promising method to improve device multi-functionality and biological properties. Biomimetic surface treatments, such as changes in nano-structure and attachment of biomolecular signals, enhance material bioactivity and affinity for specific cells. In this study the functionalization of a titanium surface with vitronectin-derived nonapeptide(HVP) and RGD peptides was investigated. Bone forming cells were used to analyse the role of each surface modification in the initial steps of cell adhesion process and then proliferation and differentiation. Method: Smooth titanium samples were functionalized by different chemical treatments in order to obtain varying amount of peptide adhesion. Human marrow stro-mal cells (MSC) were seeded and cultured in osteogenic medium. Cell adhesion and morphology were assessed by fluorescence microscopy after 6 hours. Viability of
Low back pain (LBP) is a disorder strongly associated with intervertebral disc degeneration (IDD) with an important impact on the quality of life of affected people. To date, LBP treatment is based on conservative methods with the aim to reduce back pain without restoring the degenerative environment of the disc. The main cause of IDD is the drastic reduction of the proteoglycan content within the nucleus pulposus (NP), eventually leading to the loss of disc water content, micro-architecture, biochemical and mechanical properties. A promising approach for disc regeneration is represented by the transplantation of mesenchymal stromal cells (MSCs). The exact mechanism remains unknown. Growing evidence suggests that MSCs can influence cells and modulate cells’ behaviour by secreting a set of bioactive factors. MSCs secretome is composed of several molecules such as soluble protein, lipids, nucleic acids and extracellular vesicles (EVs) involved in inflammation, immunomodulation, cell survival and intercellular communication. The aim of this study was to evaluate the in vitro effects of MSCs secretome on human NP cells (hNPCs) in a 3D culture model with and without inflammatory stimulus. MSCs secretome was collected from bone marrow-MSCs (BM-MSCs) and adipose tissue-MSCs (ASCs) after centrifugation and obtained by culturing cells without fetal bovine serum (FBS) for 48 hours. hNPCs were isolated from surgical specimens through digestion with type II collagenase, culture expanded in vitro, encapsulated in alginate beads (three-dimensional culture system) and treated with growth medium (controls), BM-MSCs or ASCs secretome with or without interleukin-1 beta (IL-1b). After 7 days, total RNA was extracted and reverse-transcribed. Gene expression levels of catabolic and anabolic genes were analyzed through real time-polymerase chain reaction (qPCR). Cell proliferation and glycosaminoglycan (GAG) production was assessed by flow cytometry and 1,9-dimethylmethylene blue (DMMB), respectively. hNPCs in alginate beads were stained with Live/Dead assay and detected using confocal immunofluorescence microscopy. Data were analyzed using Graphpad prism 8 and expressed as mean ± S.D. One-way ANOVA analysis was used to compare differences among the groups under exam.Introduction and Objective
Materials and Methods
Bone tissue engineering attempts at substituting critical size bone defects with scaffolds that can be primed with osteogenic cells, usually mesenchymal stem cells (MSC) from the bone marrow. Although overlooked, peripheral blood is a valuable source of
The ability of mesenchymal stem cells (MSCs)
to differentiate in vitro into chondrocytes, osteocytes
and myocytes holds great promise for tissue engineering. Skeletal
defects are emerging as key targets for treatment using MSCs due
to the high responsiveness of bone to interventions in animal models.
Interest in MSCs has further expanded in recognition of their ability
to release growth factors and to adjust immune responses. Despite their increasing application in clinical trials, the
origin and role of MSCs in the development, repair and regeneration
of organs have remained unclear. Until recently, MSCs could only
be isolated in a process that requires culture in a laboratory;
these cells were being used for tissue engineering without understanding
their native location and function. MSCs isolated in this indirect
way have been used in clinical trials and remain the reference standard
cellular substrate for musculoskeletal engineering. The therapeutic
use of autologous MSCs is currently limited by the need for ex
vivo expansion and by heterogeneity within
hMSC cultures were prepared from osteoarthritic patients. Silicone elastomer (PDMS) culture surfaces of varying degrees of stiffness (1:10, 1:30 and 1:50 PDMS, tissue culture plastic and glass) were investigated in isolation and in combination with differentiation media. CD marker expressions of ‘stemness’ were investigated. RNA expression changes in OA-hMSCs and non-OA-hMSCs were also investigated for a panel of genes (inclusive of ‘stemness-’ and osteogenic-linked genes, FKBP5 and osteomodulin).
Mesenchymal stem cells (MSCs) are a potential source of cells for the repair of articular cartilage and osteochondral defects (OCD) in the ankle. Synovial tissue has been shown to be a rich source of MSCs with the ability to undergo chondrogenic differentiation. Although these cells represent a heterogenous population, clonal populations have not been previously studied. MSCs were isolated from synovial tissue of a patient undergoing joint arthroplasty and expanded in culture. Six clonal populations were also isolated and expanded. The cells from the mixed parent population and the derived clonal populations were characterised for stem cell surface epitopes, and then cultured in chondrogenic mediums. Various assays were determined to analyse for features of differentiation.Introduction
Methods
Osteoarthritis (OA) is a progressively debilitating disease that
affects mostly cartilage, with associated changes in the bone. The
increasing incidence of OA and an ageing population, coupled with
insufficient therapeutic choices, has led to focus on the potential
of stem cells as a novel strategy for cartilage repair. In this study, we used scaffold-free mesenchymal stem cells (MSCs)
obtained from bone marrow in an experimental animal model of OA
by direct intra-articular injection. MSCs were isolated from 2.8
kg white New Zealand rabbits. There were ten in the study group
and ten in the control group. OA was induced by unilateral transection
of the anterior cruciate ligament of the knee joint. At 12 weeks
post-operatively, a single dose of 1 million cells suspended in 1 ml
of medium was delivered to the injured knee by direct intra-articular
injection. The control group received 1 ml of medium without cells.
The knees were examined at 16 and 20 weeks following surgery. Repair
was investigated radiologically, grossly and histologically using
haematoxylin and eosin, Safranin-O and toluidine blue staining.Introduction
Methods
Aims. It has been established that mechanical stimulation benefits tendon-bone (T-B) healing, and macrophage phenotype can be regulated by mechanical cues; moreover, the interaction between macrophages and mesenchymal stem cells (MSCs) plays a fundamental role in tissue repair. This study aimed to investigate the role of macrophage-mediated
Mesenchymal stem cells (MSC) have potent immunomodulatory and regenerative effects via soluble factors. One approach to improve stem cell-based therapies is encapsulation of
Introduction. Fusion represents an effective treatment option in patients affected by end-stage arthritis. To minimise the risk of non-union following fusion, biological preparations such as bone marrow aspirate concentrate (BMAC) are commonly used intra-operatively. Mechanotransduction represents an emerging field of research whereby physical stimuli can be used to modulate the behaviour and differentiation of cells. Blast waves (a subtype of shock waves) are one such physical stimulus. The aim of this study was to investigate whether the osteogenic potential of BMAC can be enhanced using a blast wave, and thus improve its efficacy in fusion surgery. Methods. Human BMAC samples were obtained from three healthy patients and exposed to a single blast wave (peak overpressure= 50psi), before being placed in a suspension of mesenchymal stem cells, to represent the biological environment of the fusion site. Three test groups were used:
Recent studies suggested that both the soluble protein of the mesenchymal stromal cell (MSC) secretome, as well as the secreted extracellular vesicles (EVs) promote bone regeneration. However, there is limited knowledge of the changes in
Mesenchymal stromal cells (MSC) have been proposed as an emerging cell therapy for bone tissue engineering applications. However, the healing capacity of the bone tissue is often compromised by patient's age and comorbidities, such as osteoporosis. In this context, it is important to understand the impact of donor age on the therapeutic potential of
Osteochondral injuries are a recognised factor in the development of osteoarthritis (OA). Mesenchymal stromal cells (MSCs) represent a promising biological therapeutic option as an OA-modifying treatment, and they also secrete factors that may have an anti-catabolic effect and/or encourage endogenous repair. We aim to study the effects of (i) intra-articular injection of human bone-marrow-derived MSCs and (ii) their secretome on recovery in a murine knee osteochondral injury model. The