The influence of donor age and in vitro expansion on the proliferation and differentiation properties of donor-matched bone marrow and adipose-derived mesenchymal stem cells : implications for musculoskeletal tissue engineering

Burrow, Kimberley Louise

January 2014

Introduction: Mesenchymal stem cells (MSC) offer a novel cell therapy within tissue engineering and regenerative medicine (TERM)-based strategies, and the prospect of MSC therapies are widening since the discovery of MSCs within multiple locations of the body including bone marrow (BM-MSCs) and adipose tissue, (AD-MSCs). It is highly recognised that an organisms reparative and regenerative potential declines with advancing age, therefore aged patients are one of the primary target populations for TERM applications. Although information is available regarding the effects of patient age on the quality of human BM-MSCs, little and conflicting information currently exists for AD-MSCs. In addition, few studies have compared the quality of freshly isolated and expanded donor-matched BM and AD-MSCs to elucidate the more appropriate cell source. This study investigated the effect of donor age and in vitro ageing on functional behaviour (i.e. senescence state, population kinetics and differentiation potential) of donor-matched BM and AD-MSCs. Methods: The influence of donor age and in vitro ageing on mature (28-55 years) and elderly (75-86 years) donor-matched BM and AD-MSCs was assessed upon isolation (early life-span) and during extended (mid and late lifespan) timepoints through culture. During culture MSCs were characterised for cumulative population doublings (CPDs) and the expression of senescence associated marker genes, p16INK4A, p21 and p53, and transcription factor NANOG. At each lifespan telomere length was assessed along with differentiation efficiency along the osteogenic, adipogenic and chondrogenic lineages through lineage specific marker genes and histological staining. Results: Elderly BM and AD-MSCs displayed similar characteristics in terms of initial CPD number, p21, p53 and NANOG expression, telomere length and differentiation along osteogenic and adipogenic lineages. With increasing donor age there was a significant decline in p16INK4A expression within BM-MSCs, whilst expression of all chondrogenic markers significantly decreased within AD-MSCs. BM and AD-MSCs were comparable for the majority of outcome measures with the exception of chondrogenic differentiation which was superior with BM-MSCs in terms of COL2A1 expression and histological staining for proteoglycans. Donor age had a negative effect on BM-MSCs with long-term culture leading to a significantly longer PD time and decreased telomere lengths. Similar population kinetics was displayed between BM and AD-MSCs during long-term culture. Increasing culture time had effects on differentiation potential for both MSC sources with complete loss of osteogenic capacity and decreased adipogenic capacity; however chondrogenic capacity was only decreased within AD-MSCs. Differentiation potential after long-term culture between BM and AD-MSCs showed similar osteogenic and adipogenic ability yet superior chondrogenic ability was apparent within mature BM-MSCs compared to AD-MSCs, in terms of ECM deposition. Conclusions: In conclusion the source of MSCs for TERM will need to be considered depending upon the type of tissue regeneration required. The clinical outcome would be greater using MSCs during early stages of culture, as culture expansion has detrimental effects on functional properties of both BM and AD-MSCs.

610.28

Bone marrow-derived mesenchymal stem cells promote colorectal cancer progression via CCR5 / 骨髄由来間葉系幹細胞はケモカイン受容体CCR5を介して大腸癌の進展を促進する

Nishikawa, Gen

24 September 2019

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第22039号 / 医博第4524号 / 新制||医||1038(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 濵﨑 洋子, 教授 武藤 学, 教授 妹尾 浩 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Mesenchymal stem cell

colorectal cancer

CCR5

tumor microenvironment

490

Mutant IDH1 Dysregulates the Differentiation of Mesenchymal Stem Cells in Association with Gene-Specific Histone Modifications to Cartilage- and Bone-Related Genes / 変異型IDH1は遺伝子特異的なヒストン修飾を介して、間葉系幹細胞から軟骨及び骨への分化を脱制御する

Hassan, Mohamed Hassan Ali Elalaf

23 May 2016

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第19891号 / 医博第4140号 / 新制||医||1016(附属図書館) / 32968 / 京都大学大学院医学研究科医学専攻 / (主査)教授 妻木 範行, 教授 山田 泰広, 教授 開 祐司 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Cartilaginous tumor

IDH1 mutation

Mesenchymal stem cell

Histone modification

490

Inflammatory and Immune Effects of Intra-Articular Mesenchymal Stem Cells in Horses

Pigott, John H.

05 July 2013

No description available.

Veterinary Services

Mesenchymal stem cell

equine

joint

inflammation

Modelling Strategy for the Characterization and Prediction of IIFK-Based Hydrogel Stiffness for Cell Culture Applications

Othman, Eter

01 1900

Due to the similar nature 3D synthetics share with in vivo cell conditions, peptide-based hydrogels pose an attractive strategy for the culturing of stem cells. One aspect of this unique cell culturing technique is the tunability of the hydrogel’s stiffness, a quality linked to stem cell differentiation. Due to this linkage, a methodology in which specific cell lineages are achieved within IIFK hydrogel cultures is proposed. This work provides an analysis for the peptide scaffold IIFK; it characterizes the effect between different peptide and PBS concentrations over the resulting hydrogel stiffness and develops a mathematical model to further elucidate this interaction. Nine different hydrogel formulations were made (with a minimum of eleven replicates each) and each of its replicate’s stiffness (storage modulus, Pa) was measured through rheological experiments. Then, two different methods of replicate selection were conducted and various models were derived, each using either of the two replicate selection methods and incorporating a specific number of replicates in their creation. Regardless of sample selection and replicate number, the generated models show extremely high significances between IIFK hydrogel stiffness and PBS concentrations over the resulting hydrogel stiffness. Data analysis shows that for IIFK, the hydrogel stiffness bears a strong behavior that can be modeled by a full quadratic equation. However, the data also shows that the dependency of the model is strongly correlated with the datasets chosen to produce it, with number of replicates and replicate values both resulting in differences in each model’s predictive reliability (e.g., 82% vs 91%). Therefore, while this thesis demonstrates the ability to model IIFK hydrogel behaviour with high predictability ratings, it also establishes the necessity of both producing more replicates as well as selecting the best values for IIFK-based hydrogel modelling.

hydrogel

IIFK

stiffness

modeling

mesenchymal stem cell

differentiation

Role of Actin Cytoskeleton Filaments in Mechanotransduction of Cyclic Hydrostatic Pressure

Fulzele, Keertik S

07 August 2004

This research examines the role of actin cytoskeleton filaments in chondroinduction by cyclic hydrostatic pressurization. A chondroinductive hydrostatic pressurization system was developed and characterized. A pressure of 5 MPa at 1 Hz frequency, applied for 7200 cycles (4 hours intermittent) per day, induced chondrogenic differentiation in C3H10T1/2 cells while 1800 cycles (1 hour intermittent) did not induce chondrogenesis. Quantitative analysis of chondrogenesis was determined as sulfated glycosaminoglycan synthesis and rate of collagen synthesis while qualitative analysis was obtained as Alcian Blue staining and collagen type II immunostaining. Actin disruption using 2 uM Cytochalasin D inhibited the enhanced sGAG synthesis in the chondroinductive hydrostatic pressurization environment and significantly inhibited rate of collagen synthesis to the mean level lower than that of the non-pressurized group. These results suggest an involvement of actin cytoskeleton filaments in mechanotransduction of cyclic hydrostatic pressure.

Chondrogenesis

Mesenchymal stem cell

Hydrostatic pressurization

Actin cytoskeleton filaments

Tissue Engineering Strategies to Improve Tendon Healing and Insertion Site Integration

Kinneberg, Kirsten R.C.

20 September 2011

No description available.

Biomedical Research

Tissue Engineering

Patellar Tendon

Autograft

Mesenchymal Stem Cell

A NEW DYNAMIC CULTURE SYSTEM DESIGNED TO PROVIDE CONTROLLED STRAIN TO CELL SEEDED COLLAGEN CONSTRUCTS FOR TENDON REPAIR

SCHANTZ, ERIC J.

11 October 2001

No description available.

Engineering, Biomedical

strain

biomechanics

mesenchymal stem cell

collagen

in vitro

Tendon Regeneration: Roles of Growth Factors and Phenotypic Diversity in Tendon Stem Cells

Rajpar, Ibtesam Mohamed Husein

04 March 2019

Tendon injuries significantly impact quality of life and are often career ending. Mesenchymal stem cell (MSC) therapy is known to augment intrinsic tendon healing, however, little is known of the stem cells endogenous to tendon, the microenvironmental cues that induce tendon differentiation, and whether individual cells in an inflammatory milieu respond differently to these cues. To address these questions, a three-dimensional tenogenesis assay was developed as an efficient and reproducible metric of cellular capacity to differentiate toward tendon. In contrast to more complex assays of tenogenesis, this design incorporates a simple apparatus using commercially available plasticware for the application of uniaxial static strain in in a type I collagen cell-seeded hydrogel construct. Tendon-related gene expression, glycosaminoglycan levels, elongated cell morphologies and parallel cell alignments are enhanced with BMP-12 induction over ten days of culture. This dissertation provides novel insight to the roles of growth factors in MSC tenogenesis. Tendon healing in vivo is dependent on endogenous tendon stem cells (TSC) that mediate the inflammatory response to injury and promote synthesis of collagen and matrix remodeling, among other extracellular processes. Recent evidence suggests that these cells exist on a spectrum of differentiation potencies, and may be differently committed to the tendon fate. Individual stem cells were isolated from the tendon, and their capacities for proliferation, tri-lineage differentiation and tenogenesis were evaluated. Three distinct TSC phenotypes were revealed, and significant, positive correlations were found in quadra-differentiation potency (toward four lineages) and the expression of a strong, composite tendon phenotype. These studies have important implications in the current standard-of-care in regenerative therapies for tendon. Our benchtop tenogenesis assay can be used to determine the therapeutic potential of allogeneic MSC lines and MSCs from novel sources for 'off-the-shelf' treatments. Our study of TSCs lends valuable insight to the diversity of cell phenotypes found in tendon, and the potential contributions of each phenotype to tendon healing and homeostasis. These results further strengthen the status of tendon as a superior source of stem cells for tendon repair. / Ph. D. / Tendons are fibrous, elastic bands of collagen that connect muscles to bones and are essential to movement and proper functioning of the skeletal system. Weight-bearing tendons like the Achilles in humans and superficial digital flexor tendons in horses are particularly prone to damage and degeneration with overuse and/or aging. Bone marrow-derived stem cell treatments have shown promise in the reduction of pain and inflammation, and restoration of native tendon structure and function in cases of severe tendon injuries. However, the roles of stem cells in tendon healing, particularly their ability to transition to cell types native to tendon and integrate with an environment distinct from their own is unknown. Culturing of stem cells in three dimensional (3D) environments has enabled us to identify and understand the biochemical and mechanical signals that trigger stem cell transitions to tendon cells in tendons, but currently available 3D culture systems are complex and inefficient. In this dissertation we have developed a cost-effective and high throughput 3D culture system to assay the potential of stem cells to form tendon cells and composite tendon-like tissues. Toward this, we have also optimized the effects of known tendon proteins on the tendon fate in 3D culture of stem cells. Like most adult tissues, the tendon encompasses an in-house repository of stem cells. Tendon stem cells (TSCs) are primarily responsible for the inflammatory and reparative responses to tendon injury. Recent evidence suggests that TSCs are diverse in character, and differ from each other in their ability to form cells and tissues of fat, bone and cartilage. In this work, we provide evidence that TSCs are also differently committed to forming tendon tissue, and moreover that significant inter-relationships among gene expression patterns in these cells directly contribute to cultural diversity. In sum, our results provide novel insight to the roles of stem cells in tendon healing, particularly their response to subtle changes in their biochemical environment, and the contributions of individual cells in a milieu to a holistic reparative response.

tendon

mesenchymal stem cell

growth factor

collagen gel

FBS free culture of porcine umbilical cord matrix cells

Parker, Steven W.

January 1900

Master of Science / Department of Animal Sciences and Industry / Duane L. Davis / The common choice of medium for culturing pig umbilical cord matrix stem cells (PUCs) is high glucose Dulbecco’s Minimum Essential Medium (HG-DMEM) supplemented with fetal bovine serum (FBS). FBS is a chemically undefined supplement that encourages attachment of explants and cells and is useful for long-term proliferation in an undifferentiated state. Removing FBS from the culture medium would decrease the possibility of microbial contamination and might produce more consistent results. A defined medium would facilitate experiments to determine requirements for specific growth factors and nutrients. Starting PUCs in a FBS-free environment proved to be a challenge. The results of 15 experiments testing various media, supplements, and culture conditions indicate that PUCs initially plated in an FBS-free environment do not attach as readily as those in HG-DMEM supplemented with FBS. PUCs were collected using enzyme digestion of the whole cord or by plating explants from the cord in culture medium. In the final experiment PUCs were seeded in 24-well plates (5.0 * 10[superscript]4 viable cells per well) with a collagen coating and cultured in Knock-out DMEM (KO-DMEM) with basic fibroblast growth factor (5ng/mL) and platelet derived growth factor (5ng/mL) in a low oxygen atmosphere (5% O[subscript]2/ 5% CO[subscript]2/ 90% N[subscript]2). The total non-adherent cell count at passage 1 was 1.78 * 10[superscript]5 +or- 3.68 * 10[superscript]4 and the total adherent cells were 2.58 * 10[superscript]5 +or- 9.29 * 10[superscript]4. The well confluence during initial cell proliferation appeared similar to cells cultured in the control media with 20% FBS (total adherent cells = 6.40 * 10[superscript]5 +or- S.E. 1.61 * 10[superscript]5 and total non-adherent cells = 2.88 * 10[superscript]5 + 7.60 * 10[superscript]4). However the number of adherent cells recovered for passage 2 was considerably less for cultures in FBS-free media than for the control group. Serum may affect attachment by providing attachment factors or it could change expression of integrins or other attachment molecules on the PUCs that enhance attachment to plastic or other substrates. In future studies the requirements for attachment of PUCs should be further evaluated.

Umbilical Cord

Mesenchymal Stem Cell

Serum Free

Biology, Animal Physiology (0433)

Biology, Cell (0379)