Viable Mesenchymal Stem Cells Research Articles

Bursal Tissue Harvested During Rotator Cuff Repair Contains Viable Mesenchymal Stem Cells

PurposeThe purpose of this study was to evaluate the effect of intra operative ablation on the viability, distribution, phenotype, and potential for culture expansion of bursal cells harvested during arthroscopic rotator cuff surgery. MethodsTissue was collected during primary arthroscopic rotator cuff repair on six healthy, randomly selected patients from a fellowship-trained surgeon’s practice between September 2020 and January 2021. There were 3 females (age 60 ± 8 years) and 3 males (age 61 ± 10 years). At the time of surgery, subacromial bursal tissue was subjected to no ablation, one second, or three seconds of ablation. Tissues were collected by an autograft harvesting system connected to an arthroscopic shaver and a pituitary grasper. Tissue fragments from each condition were sampled for viability testing or cell isolation. A viability kit with confocal microscopy was used to assess live and dead cells. Cell isolation consisted of collagenase digestion or placing tissue fragments onto tissue culture treated plates that induced migration of cells out of the tissue. Cell proliferation rates were monitored and surface markers for mesenchymal stem cells (MSC) and pericytes were analyzed via multi-color flow cytometry. ResultsIncreased ablation time significantly reduced cell viability. The mean percentage of live cells was 55.2 ± 27.2% (range 26-90% live) in the control group, 46.8 ± 23.8% (range 9.6-69.6% p = 0.045) in the short, and 35.5 ± 19% (range 11-54% p = 0.03) in the long ablation group. No significant differences in population doubling level (1.6 ± 0.5 days) and population doubling time (6.7 ± 2.4 days) were observed in cells from any treatment. The surface marker profile indicated an MSC phenotype with absence of a pericyte population. Ablation or cell isolation procedure had no significant effect on the surface marker profile of isolated cells. ConclusionRadiofrequency ablation significantly reduced the overall tissue viability, but had no significant effect on cell proliferation, or expression of surface markers on isolated subacromial bursal cells harvested arthroscopically. Clinical RelevanceAnalysis of the viability and performance of cells harvested after the use of ablation devices using mechanical surgical collection during RCR surgery could further our understanding of subacromial bursal tissue and its potential role in augmenting rotator cuff repair healing.

A Simple and Effective Mechanical Method for Adipose-Derived Stromal Vascular Fraction Isolation.

Over the last decades, there has been ongoing and evolving research concerning regenerative medicine, specifically, stem cells. The most common source of adult mesenchymal stem cells (MSCs) remains the adipose tissue and the easiest way to obtain such tissue is lipoaspirate. The fatty tissue obtained can be processed either in an enzymatic way, which is time-consuming and expensiveand carries several dangers for the viability of the stem cells included, or with mechanical means which are fast, inexpensive, yield enough viable cells, and can be readily used for autologous transplantation in one-stage procedures. Herein, we demonstrate our non-enzymatic method for obtaining adipose-derived stromal vascular fraction comprising MSCs. The stromal vascular fraction was isolated via centrifugation, and the characteristics and numbers of the cells isolated have been tested with flow cytometry assay, cell culture, and differentiation. Over 91% of viable MSCs were isolated using the mechanical method. The cells retained the ability to differentiate into osteocytes, adipocytes, and chondrocytes. The method presented is simple, requiring no special equipment, and yields a viable population of stem cells in large numbers. These cells can be readily used in several operations (orthopedic, dentistry, fistulas, etc.) making feasible "one-stage" procedures, thus proving their benefits for the patient and the health care system.

Vascular Cell Adhesion Molecule-1 Regulates Bone Marrow Mesenchymal Stem Cell Maintenance and Niche Function

Bone marrow (BM) mesenchymal stem cells (MSCs) are rare non-hematopoietic perivascular stromal cells characterized by their unique ability to self-renew and differentiate into bone, cartilage, and fat, ensuring proper skeletal development and maintenance. Different subsets of BM MSCs associate with arteriolar and sinusoidal vessels to form specialized niches that regulate hematopoietic stem cell (HSC) function by secreting high levels of niche factors such as CXC-chemokine ligand 12 (CXCL12), stem cell factor (SCF), and Vascular Cell Adhesion Molecule-1 (VCAM1). VCAM1 is classically expressed on endothelial and stromal cells where it acts as an adhesion molecule that preferentially binds to α4β1 integrin on HSCs and progenitor cells (HSPCs). Deletion of Vcam1 in endothelial and hematopoietic cells induces HSPC mobilization into the peripheral blood without affecting endothelial cells homeostasis. Recent work from our lab further demonstrated that VCAM1 expression on HSCs and leukemic stem cells confers innate immune tolerance ( Nat Cell Biol 2022). While the contribution of HSC and endothelial-derived VCAM1 to homeostasis has been well studied, the role of MSC-derived VCAM1 on HSC and MSC maintenance and multilineage potency remains unknown. Our supporting data suggest that MSCs are the BM's main source of Vcam1 (p<0.0001) and that VCAM1 is critical for the maintenance, survival, and function of MSCs. Using a mouse model in which Vcam1 can be conditionally deleted in BM MSCs by a tamoxifen-inducible N-Cadherin-Cre ER line (referred to as Vcam1 N-CadCreER), we found that deletion of Vcam1 significantly reduces the number (4-fold, p=0.0030), frequency (4-fold, p=0.0042), and viability (2-fold, p=0.0039) of BM MSCs. Previous findings in breast cancer revealed that VCAM1 promotes PI3K/Akt survival signaling via Akt phosphorylation. Accordingly, Vcam1 deletion in N-Cadherin-Cre ER MSCs, demonstrated a significant reduction in phospho-Akt (Ser473) (p<0.05), supporting the role of VCAM1 in mediating PI3K/Akt survival signaling in MSCs. Intriguingly, the remaining viable VCAM1-null MSCs isolated from Vcam1 N-CadCreER mice exhibited reduced clonogenic potential (determined by CFU-F assays; 3-fold, p=0.0001). Furthermore, micro-CT analysis of 6-month-old Vcam1 N-CadCreER mice presented an altered bone phenotype compared to the control as evidenced by their significantly increased bone thickness and volume (p<0.05), yet significantly decreased tissue mineral density and medullary cavity area (p<0.05). Bulk RNA sequencing (RNAseq) of sorted viable MSCs revealed distinct grouping between Control and Vcam1 N-CadCreER MSCs. Gene ontology analysis demonstrated that deletion of Vcam1 caused an upregulation of pathways associated with inflammation and cytokine release while pathways associated with ossification, extracellular matrix organization, and skeletal development were all downregulated. Surprisingly, both bulk RNAseq and qPCR analysis confirmed a significant reduction in the expression of HSC niche factors ( Vcam1 Cxcl12 and Scf) following Vcam1 deletion, indicative of reduced niche activity. As expected, Vcam1 deletion in N-Cadherin-Cre ER MSCs, caused significant mobilization of HSCs into the blood (p<0.0001) and BM homing defects (p<0.05), however the number and repopulation capacity of BM HSCs remained unaltered, as seen by BM transplantation experiments. Surprisingly, imaging analysis of whole-mount bone marrow sternum of phenotypic HSCs revealed no differences in HSC niche localization between Vcam1-null and Control mice. Accordingly, ELISA analysis of BM extracellular fluid revealed no differences in overall CXCL12 and SCF levels suggesting that there may be some local or systemic niche compensation at play. Single-cell (sc)RNAseq of pooled BM and compact bone sorted non-hematopoietic stromal cells (DAPI -Lineage -CD45 -Ter119 -CD19 -CD71 -)from Vcam1 N-CadCreERand Control mice further confirmed the downregulation of HSC niche factors in MSCs, and overall remodeling of the BM stromal cell composition following Vcam1 deletion. Interestingly, our scRNAseq analysis revealed increased expression of Cxcl12 and Scf in specific vascular and stromal cell populations, supporting the notion of HSC niche compensation. Overall, these findings demonstrate that MSC-derived Vcam1 is critical for BM MSC survival and their HSC niche function.

Bead-jet printing enabled sparse mesenchymal stem cell patterning augments skeletal muscle and hair follicle regeneration

Transplantation of mesenchymal stem cells (MSCs) holds promise to repair severe traumatic injuries. However, current transplantation practices limit the potential of this technique, either by losing the viable MSCs or reducing the performance of resident MSCs. Herein, we design a “bead-jet” printer, specialized for high-throughput intra-operative formulation and printing of MSCs-laden Matrigel beads. We show that high-density encapsulation of MSCs in Matrigel beads is able to augment MSC function, increasing MSC proliferation, migration, and extracellular vesicle production, compared with low-density bead or high-density bulk encapsulation of the equivalent number of MSCs. We find that the high-density MSCs-laden beads in sparse patterns demonstrate significantly improved therapeutic performance, by regenerating skeletal muscles approaching native-like cell density with reduced fibrosis, and regenerating skin with hair follicle growth and increased dermis thickness. MSC proliferation within 1-week post-transplantation and differentiation at 3 − 4 weeks post-transplantation are suggested to contribute therapy augmentation. We expect this “bead-jet” printing system to strengthen the potential of MSC transplantation.

Mesenchymal stem cells encapsulated in a reactive oxygen species-scavenging and O2-generating injectable hydrogel for myocardial infarction treatment

Stem cell especially mesenchymal stem cell (MSC) transplantation is a promising therapeutic strategy for myocardial infarction (MI) repair. However, major obstacles remain due to the poor retention and survival rate of transplanted MSCs in the harmful MI microenvironment (e.g., oxidative stress and hypoxia). Here, a novel injectable hydrogel (RCGel) with dual functions of reactive oxygen species (ROS)-scavenging and O2-generating was employed to encapsulate MSCs for MI treatment. The RCGel encapsulating exhibited anti-ROS protection through inhibiting JNK/p38 apoptosis signaling pathway to improve the viability of MSCs under oxidative stress conditions in vitro. The survival of cardiomyocytes was also improved both in the oxidative stress and hypoxia environments when being co-cultured with MSCs-encapsulated RCGel (MSC/RCGel). The RCGel encapsulating boosted the engraftment of transplanted MSCs in vivo. More viable MSCs endowed with regenerative abilities in the infarcted rat heart along with the ameliorated MI microenvironment (decreased oxidative stress and hypoxia) by the RCGel substantially inhibited cardiac apoptosis, enhanced cardiomyocyte viability, promoted angiogenesis and reduced fibrosis to improve the cardiac functions. The encapsulation of MSCs in RCGel, which exhibits beneficial effects in resisting harsh environments, provides a new way in MI repair and stem cell delivery, and has great potential in cell-based regenerative medicine.

Geranylgeraniol prevents zoledronic acid-mediated reduction of viable mesenchymal stem cells via induction of Rho-dependent YAP activation.

Long-term use of zoledronic acid (ZA) increases the risk of medication-related osteonecrosis of the jaw (MRONJ). This may be attributed to ZA-mediated reduction of viable mesenchymal stem cells (MSCs). ZA inhibits protein geranylgeranylation, thus suppressing cell viability and proliferation. Geranylgeraniol (GGOH), which is a naturally found intermediate compound in the mevalonate pathway, has positive effects against ZA. However, precise mechanisms by which GGOH may help preserve stem cell viability against ZA are not fully understood. The objective of this study was to investigate the cytoprotective mechanisms of GGOH against ZA. The results showed that while ZA dramatically decreased the number of viable MSCs, GGOH prevented this negative effect. GGOH-rescued ZA-exposed MSCs formed mineralization comparable to that produced by normal MSCs. Mechanistically, GGOH preserved the number of viable MSCs by its reversal of ZA-mediated Ki67+ MSC number reduction, cell cycle arrest and apoptosis. Moreover, GGOH prevented ZA-suppressed RhoA activity and YAP activation. The results also established the involvement of Rho-dependent YAP and YAP-mediated CDK6 in the cytoprotective ability of GGOH against ZA. In conclusion, GGOH preserves a pool of viable MSCs with osteogenic potency against ZA by rescuing the activity of Rho-dependent YAP activation, suggesting GGOH as a promising agent and YAP as a potential therapeutic target for MRONJ.

Effect of mesenchymal stromal cells encapsulated within polyethylene glycol-collagen hydrogels formed in situ on alkali-burned corneas in an ex vivo organ culture model

Background aimsCorneal inflammation after alkali burns often results in vision loss due to corneal opacification and neovascularization. Mesenchymal stem cells (MSCs) and their secreted factors (secretome) have been studied for their anti-inflammatory and anti-angiogenic properties with encouraging results. However, topical instillation of MSCs or their secretome is often accompanied by issues related to delivery or rapid washout. Polyethylene glycol (PEG) and collagen are well-known biomaterials used extensively in scaffolds for tissue engineering. To effectively suppress alkaline burn-induced corneal injury, the authors proposed encapsulating MSCs within collagen gels cross-linked with multi-functional PEG-succinimidyl esters as a means to deliver the secretome of immobilized MSCs. MethodsHuman MSCs were added to a neutralized collagen solution and mixed with a solution of four-arm PEG-N-hydroxysuccinimide. An ex vivo organ culture was conducted using rabbit corneas injured by alkali burn. MSCs were encapsulated within PEG-collagen hydrogels and injected onto the wounded cornea immediately following alkali burn and washing. Photographs of the ocular surface were taken over a period of 7 days after the alkali burn and processed for immunohistochemical evaluation. Samples were split into three groups: injury without treatment, MSCs alone, and MSCs encapsulated within PEG-collagen hydrogels. ResultsAll corneas in ex vivo organ culture lost their transparency immediately after alkali burn, and only the groups treated with MSCs and MSCs encapsulated within PEG-collagen hydrogels recovered some transparency after 7 days. Immunohistochemical analysis revealed increased expression of vimentin in the anterior corneal stroma of the group without treatment indicative of fibrotic healing, whereas less stromal vimentin was detected in the group containing MSCs encapsulated within the PEG-collagen hydrogels. ConclusionsPEG-collagen hydrogels enable the encapsulation of viable MSCs capable of releasing secreted factors onto the ocular surface. Encapsulating MSCs within PEG-collagen hydrogels may be a promising method for delivering their therapeutic benefits in cases of ocular inflammatory diseases, such as alkali burn injuries.

A protocol for umbilical cord tissue cryopreservation as a source of mesenchymal stem cells.

Mesenchymal stem cells (MSC) differentiate into different cell types and have immunomodulatory and paracrine effects. Cryopreservation of umbilical cord tissue as a source of MSC is very promising for regenerative medicine. We aim to evaluate a protocol for cryopreserving this tissue sectioned into small fragments with viable MSC. A total of 723 samples were frozen, thawed and cultured to obtain primary cultures of MSC. These were followed until 90-100% confluence and flow cytometric analysis were performed to confirm the mesenchymal phenotype. Samples in which protocol alterations at the collection of the samples were reported, were excluded for microbial contamination analysis leaving a total of 634 samples composed of 181 vaginal and 453 cesarean births. All cultures reach confluence with a media of 22.57days and 97% in 28 or fewer days. Evaluated cultures showed low percentage of CD45+ and high of CD73 and CD90. Eight samples were subcultured 4 or 5 times and differentiated to chondrocytes and osteocytes to test differentiation potential with positive results. Umbilical cord tissue collections showed similar microbial profile and risk factors to those reported of umbilical cord blood collections, but with higher contamination frequencies. Cryopreserved tissue samples had viable cells that can be expanded without losing differentiation potential. Higher contamination frequencies compared to umbilical cord blood collection are not surprising, however, microbial load and survival of microorganisms to cryopreservation are expected to be lower.

Apoptosis: A friend or foe in mesenchymal stem cell-based immunosuppression.

Mesenchymal stem cells (MSC) are adult stem cells which reside in almost all postnatal tissue where, in juxtacrine and paracrine manner, regulate phenotype and function of immune cells, maintain tissue homeostasis, attenuate on-going inflammation and promote repair and regeneration of injured tissues. Due to their capacity to suppress detrimental immune response, MSC have been considered as potentially new therapeutic agents in the treatment of autoimmune and inflammatory diseases. It was recently revealed that apoptosis may increase anti-inflammatory properties of MSC by enhancing their capacity to induce generation of immunosuppressive phenotype in macrophages and dendritic cells. Upon phagocytosis, apoptotic MSC induce generation of immunosuppressive phenotype in monocytes/macrophages and promote production of anti-inflammatory cytokines and growth factors that attenuate inflammation and facilitate repair and regeneration of injured tissues. Importantly, immunomodulation mediated by apoptotic MSC was either similar or even better than immunomodulation accomplished by viable MSC. In contrast to viable MSC, which obtain either pro- or anti-inflammatory phenotype upon engraftment in different tissue microenvironments, apoptotic MSC were not subject to changes in their immunomodulatory characteristics upon diverse stimuli, indicating their potential for clinical use. In this chapter, we summarized current knowledge about beneficial effects of apoptotic MSC in the suppression of detrimental local and systemic immune response, and we emphasized their therapeutic potential in the treatment of inflammatory diseases.

Highly effective fibrin biopolymer scaffold for stem cells upgrading bone regeneration.

Fibrin scaffold fits as a provisional platform promoting cell migration and proliferation, angiogenesis, connective tissue formation and growth factors stimulation. We evaluated a unique heterologous fibrin biopolymer as scaffold to mesenchymal stem cells (MSCs) to treat a critical-size bone defect. Femurs of 27 rats were treated with fibrin biopolymer (FBP); FBP + MSCs; and FBP + MSC differentiated in bone lineage (MSC-D). Bone repair was evaluated 03, 21 and 42 days later by radiographic, histological and scanning electron microscopy (SEM) imaging. The FBP + MSC-D association was the most effective treatment, since newly formed Bone was more abundant and early matured in just 21 days. We concluded that FBP is an excellent scaffold for MSCs and also use of differentiated cells should be encouraged in regenerative therapy researches. The FBP ability to maintain viable MSCs at Bone defect site has modified inflammatory environment and accelerating their regeneration.

Viability of Mesenchymal Stem Cells in an Ex Vivo Circulation System.

Extracorporeal membrane oxygenation (ECMO) is a well-known therapy for refractory cardiac and respiratory failure. Stem cell therapy has been investigated as an adjunctive treatment for use during ECMO, but little is known about the viability of stem cells during ECMO support. We evaluated the viability and activity of mesenchymal stem cells (MSCs) in ex vivo circulation (EVC) conditions. The experimental groups were divided into two subgroups: EVC with oxygenator (OXY group) and EVC without oxygenator (Non-OXY group). Mesenchymal stem cells (1.0 × 10) were injected into the EVC system. Cell counting, a lactate dehydrogenase (LDH) cytotoxicity assay, and the mitochondrial functions of viable MSCs were analyzed. The post-EVC oxygen consumption rate (OCR) was significantly lower than the pre-EVC OCR, regardless of whether the oxygenator was used. The LDH levels were significantly higher in the OXY group than in the Non-OXY group. The cellular loss was mainly due to lysis of the cells whereas the loss of cellular activity was attributed to the nonphysiologic condition itself, as well as the oxygenator. We concluded that direct infusion of MSCs during ECMO support did not serve as adjunctive therapy. Further studies are needed to improve the viability in an ECMO setting.

Hypothermia and nutrient deprivation alter viability of human adipose-derived mesenchymal stem cells

PurposeAdipose-derived mesenchymal stem cells (MSCs) are attractive biological agents in regenerative medicine. To optimize cell therapies, it is necessary to determine the most effective delivery method for MSCs. Therefore, we evaluated the biological properties of MSCs after exposure to various temperatures to define optimal storage conditions prior to therapeutic delivery of MSCs. DesignProspective observational study. Methods and materialsAdherent and non-adherent MSCs were incubated at multiple temperatures (i.e., 4, 23 and 37 °C) in Lactated Ringers (LR) solution lacking essential cell growth ingredients, or in culture media which is optimized for cell growth. Cells were assessed either after the temperature changes (4 h) or after recovery (24 h). Metabolic activity of MSCs, cell number and expression of representative mRNA biomarkers were evaluated to assess the biological effects of temperature. We monitored changes in mRNAs expression related to cytoprotective- or stress-related responses (e.g., FOS, JUN, ATF1, ATF4, EGR1, EGR2, MYC), proliferation (e.g., HIST2H4, CCNB2), and extracellular matrix production (ECM; e.g., COL3A1, COL1A1) by quantitative real time reverse-transcriptase polymerase chain reaction (RT-qPCR) analysis. ResultsOur study demonstrates that storing MSCs in Lactated Ringers (LR) solution for 4 h decreases cell number and metabolic activity. The number of viable MSCs decreased significantly when cultured at physiological temperature (37 °C) and severe hypothermia (4 °C), while cells grown at ambient temperature (23 °C) exhibited the least detrimental effects. There were no appreciable biological differences in mRNA markers for proliferation or ECM deposition at any of the temperatures. However, biomarkers related to cytoprotective- or stress-responses were selectively elevated depending on temperature or media type (i.e., LR versus standard media). ConclusionThe biological impact of nutrient-free media and temperature changes after 4 h exposure persists after a 24 h recovery period. Hence, storage temperature and media conditions should be optimized to improve effective dosing of MSCs.

A Novel Arthroscopic Technique for Intraoperative Mobilization of Synovial Mesenchymal Stem Cells

Background: Mesenchymal stem cells (MSCs) have emerged as a promising candidate for tissue regeneration and restoration of intra-articular structures such as cartilage, ligaments, and menisci. However, the routine use of MSCs is limited in part by their low numbers and the need for methods and procedures outside of the joint or surgical field. Purpose: To demonstrate feasibility of a technique in which minimally manipulated synovial MSCs can be mobilized during knee arthroscopy, thereby showing proof of concept for the future evaluation and clinical use of native joint resident MSCs in single-stage joint repair strategies. Study Design: Descriptive laboratory study. Methods: Patients (n = 15) undergoing knee arthroscopy who were free from synovitis or active inflammation were selected. Three samples of irrigation fluid were collected from each patient at inception of the procedure, after an initial inspection of the joint, and after agitation of the synovium. MSC numbers were evaluated by colony forming unit–fibroblastic assay. The phenotype of synovial fluid resident and synovial-mobilized MSCs was determined by flow cytometry, and their functionality was determined by trilineage differentiation. Adhesion of culture-expanded mobilized MSCs to fibrin scaffolds was also evaluated to ascertain whether mobilized MSCs might concentrate at sites of bleeding. Results: Normal irrigation during arthroscopy depleted resident synovial fluid MSCs (4-fold decrease, n = 15). Numbers of MSCs mobilized through use of a purpose-made device were significantly higher (105-fold) than those mobilized through use of a cytology brush (median of 5763 and 54 colonies, respectively; P = .001; n = 15). The mobilized cellular fraction contained viable MSCs with proliferative potential and trilineage differentiation capacity for bone, cartilage, and fat lineages, and cultured daughter cells exhibited the standard MSC phenotype. Following culture, mobilized synovial MSCs also adhered to various fibrin scaffolds in vitro. The technique was simple and convenient to use and was not associated with any complications. Conclusion: Numbers of functional MSCs can be greatly increased during arthroscopy through use of this technique to mobilize cells from the synovium. Clinical Relevance: This study highlights a novel, single-stage technique to increase joint-specific, synovial-derived MSCs and thereby increase the repair potential of the joint. This technique can be undertaken during many arthroscopic procedures, and it supports the principle of integrating mobilized MSCs into microfracture sites and sites of bleeding or targeted repair through use of fibrin-based and other scaffolds.

Dual-crosslinked homogeneous alginate microspheres for mesenchymal stem cell encapsulation

A smart hydrogel material was used in combination with custom microfluidic devices (MFDs) to create microspheres for human mesenchymal stem cell (MSC) encapsulation. Methods for fabricating homogeneous stimuli-responsive microspheres for MSC encapsulation and cell delivery have gained interest to increase viability and manipulate microencapsulation within microspheres 10-1000 µm in diameter. Herein, MFDs were combined with non-toxic smart hydrogel materials to tune both the size and mechanics of the microspheres. Traditional hydrogels have a single input/stimulus for crosslinking, utilize potentially toxic ultraviolet radiation, and fail to mimic surrounding musculoskeletal tissue mechanics. Thus, it is highly beneficial to encapsulate MSCs inside a mechanically-stable microsphere made from naturally-derived materials. The objectives of this research were to optimize microsphere fabrication techniques using custom microfluidic devices (MFDs), and to encapsulate viable MSCs within visible-light crosslinked smart-alginate microspheres, with tunable mechanical properties. Microsphere production was characterized optically, and MSC viability, post-encapsulation, was verified using a standard florescence assay. Cell viability was maintained in chemically-modified alginate homogenous microspheres post encapsulation, and after subsequent crosslinking via green light exposure.

Colloidal gelatin microgels with tunable elasticity support the viability and differentiation of mesenchymal stem cells under pro‐inflammatory conditions

Despite a promising potential for mesenchymal stem cells (MSCs) in tissue regeneration, a major challenge in MSC-based therapy has been associated with poor cell survival and low levels of cell integration into host tissue following transplantation. The objective of this study was to develop a gelatin-based colloidal microgel platform that enables the encapsulation of viable MSCs as well as confer fine-tuning of mechanical stiffness and low cytotoxicity. In this study, we report a facile method of fabricating gelatin-based microgel spheres for the encapsulation of MSCs using a water-in-oil mini-emulsification method, which is covalently crosslinked by genipin. At a given seeding cell number, there was a positive correlation between the size of the microsphere and the number of encapsulated MSCs. Controlling the crosslinking degree of gelatin matrix enabled a fine-tuning of mechanical stiffness of gel microsphere. MSCs within softer microgel exhibit more spread morphology than the cells in the stiffer matrix, while cells within stiffer matrix become more elongated morphology. Importantly, we show that the colloidal gelatin microgel could support the viability and differentiation of encapsulated MSCs in a pro-inflammatory environment. This study demonstrates the feasibility of using genipin-crosslinked gelatin gel microspheres as an injectable carrier of MSCs for tissue engineering applications, which can be further explored for MSC-based cell therapy for tissue repair. © 2018 Wiley Periodicals, Inc. J Biomed Mater Res Part A: 106A: 2753-2761, 2018.

Improved delivery of PLGA microparticles and microparticle-cell scaffolds in clinical needle gauges using modified viscosity formulations

Polymer microparticles are widely used as acellular drug delivery platforms in regenerative medicine, and have emerging potential as cellular scaffolds for therapeutic cell delivery. In the clinic, PLGA microparticles are typically administered intramuscularly or subcutaneously, with the clinician and clinical application site determining the precise needle gauge used for delivery. Here, we explored the role of needle diameter in microparticle delivery yield, and develop a modified viscosity formulation to improve microparticle delivery across a range of clinically relevant needle diameters. We have identified an optimal biocompatible formulation containing 0.25% pluronic F127 and 0.25% carboxymethyl cellulose, which can increase delivery payload to 520% across needle gauges 21–30G, and note that needle diameter impacts delivery efficacy. We use this formulation to increase the delivery yield of PLGA microparticles, and separately, PLGA-cell scaffolds supporting viable mesenchymal stem cells (MSCs), demonstrating the first in vitro delivery of this cell scaffold system. Together, these results highlight an optimal formulation for the delivery of microparticle and microparticle-cell scaffolds, and illustrate how careful choice of delivery formulation and needle size can dramatically impact delivery payload.

Supercooling Storage for the Transplantable Sources From the Rat and the Rabbit: A Preliminary Report

BackgroundIt is necessary to store the transplantable sources for a certain period during the variety of manipulation processing steps. The method used to preserve (depending on conditions of solvent, temperature, periods, density, and physical impulse, etc.) can affect the safety and efficacy of the samples. Supercooling refers to a phenomenon of lowering the temperature below its freezing point without freezing. We investigated the possibility of supercooling for the preservation of cells and organs according to the limited conditions. MethodThe viability of mesenchymal stem cells (MSCs) derived from the intra-abdominal fat of the New Zealand white rabbit were observed, and the neonatal rat kidneys were maintained in histidine-tryptophan-ketoglutarate solution and stored at various temperatures for 48 hours. The supercooling refrigerator was used for −2 °C and −5 °C in controlled preservation conditions. We observed and compared histopathological changes of samples at each temperature condition. ResultsAs time passed, the number of rabbit MSCs decreased in each group with storage temperature. At room temperature, the number of viable MSCs decreased rapidly, but the number of MSCs tended to decrease slowly in the cooling and supercooling groups. The rat kidneys preserved on supercooling temperature at −2 °C tended to have the least damage on the cortex and medulla parenchyma. ConclusionsThe difference in damage of transplantable sources by storage temperature conditions is the evidence that effectiveness may depend on the storage method. It is necessary to determine further optimal supercooling temperature of the preservation methods with various cells, tissues, and organs in the future.

Effects of Different Cell-Detaching Methods on the Viability and Cell Surface Antigen Expression of Synovial Mesenchymal Stem Cells

Flow cytometric analysis of cell surface antigens is a powerful tool for the isolation and characterization of stem cells residing in adult tissues. In contrast to the collection of hematopoietic stem cells, the process of enzymatic digestion is usually necessary to prepare mesenchymal stem cells (MSCs) suspensions, which can influence the expression of cell surface markers. In this study, we examined the effects of various cell-detaching reagents and digestion times on the expression of stem cell-related surface antigens and MSC functions. Human MSCs were detached from dishes using four different reagents: trypsin, TrypLE, collagenase, and a non enzymatic cell dissociation reagent (C5789; Sigma-Aldrich). Following dissociation reagent incubations ranging from 5 to 120 min, cell surface markers were analyzed by flow cytometry. Trypsin and TrypLE quickly dissociated the cells within 5 min, while collagenase and C5789 required 60 min to obtain maximum cell yields. C5789 significantly decreased cell viability at 120 min. Trypsin treatment significantly reduced CD44+, CD55+, CD73+, CD105+, CD140a+, CD140b+, and CD201+ cell numbers within 30 min. Collagenase treatment reduced CD140a expression by 30 min. In contrast, TrypLE treatment did not affect the expression of any cell surface antigens tested by 30 min. Despite the significant loss of surface antigen expression after 60 min of treatment with trypsin, adverse effects of enzymatic digestion on multipotency of MSCs were limited. Overall, our data indicated that TrypLE is advantageous over other cell dissociation reagents tested for the rapid preparation of viable MSC suspensions.

Comparative study of the methods of extracting mesenchymal stem cells from cryopreserved Wharton's Jelly

The Wharton's Jelly (WJ) is an established source of mesenchymal stem cells (MSC). We compared 3 methods of extracting WJ-MSC from cryopreserved tissue and determined that enzymatic digestion of the WJ yielded the most viable MSC, compared to the explant and mechanical digestion methods. The enzymatically-released WJ-MSC conformed to the International Society for Cellular Therapy (ISCT) criteria: displayed plastic-adherence, co-expressed CD73, CD90, CD105 and were negative for hematopoietic lineage cell markers.

Aging and Cell Therapy for the Treatment of Osteonecrosis of the Femoral Head

The addition of mesenchymal stem cells (MSCs) to core decompression for the treatment of early-stage osteonecrosis of the femoral head (ONFH) represents a joint preserving operation to potentially avoid hip arthroplasty. The idea to regenerate the proximal femoral bone stock by replenishing the necrotic segment with viable MSCs has shown great promise compared with core decompression alone. However, the fate of the MSCs and the potential effects of aging have posed some important challenges. Aging affects the number of MSCs available for harvesting and injection, as well as their potential for differentiation into the osteogenic lineage, which are two critical parameters for the success of “cell-based therapy” for ONFH. This review endeavors to provide information relevant to the use of MSCs in aging patients for the treatment of ONFH.