StemXVivo Human/Mouse Chondrogenic Supplement, 0.5 mL
StemXVivo Human/Mouse Chondrogenic Supplement, 0.5 mL Summary
Base media for the differentiation of MSCs into chondrocytes. For use with Human/Mouse and Rat StemXVivo® Chondrogenic Supplements.
Key Benefits
- Supports induction of chondrogenesis in MSCs
- Defined supplement reduces experimental variation
- Developed and optimized using MSCs
Why Induce Chondrogenesis in MSCs with a Defined Media Supplement?
Despite the well-characterized factors and protocols used to differentiate mesenchymal stem/stromal cells (MSCs) into chondrocytes, differentiation efficiencies can vary depending on the quality of the MSC starting population and the reagents used to expand and differentiate MSCs.
Human/Mouse StemXVivo® Chondrogenic Supplement:
- Contains high quality differentiation factors to drive reproducible and efficient MSC chondrogenesis.
- Is defined to reduce unwanted experimental variability.
- Has been developed and optimized using human and mouse MSCs.
The term ‘mesenchymal stromal cells’ is commonly used to describe a heterogeneous population of cultured cells that are adherent to plastic, have a distinct morphology, and express a specific set of marker proteins. Within this heterogeneous population are cells referred to as ‘mesenchymal stem cells.’
Mesenchymal stem cells are multipotent, self-renewing cells that have the ability to differentiate into adipocytes, chondrocytes, and osteoblasts when cultured in vitro. Read More about MSC Nomenclature
Human/Mouse Chondrogenic Supplement Components
This media supplement contains defined, high quality factors to drive MSC differentiation into chondrocytes.
- This supplement requires media (not included), such as Human/Mouse/Rat StemXVivo® Chondrogenic Base Media (Catalog # CCM005) or equivalent.
- The quantity of chondrogenic media supplement supplied is sufficient to make 50 mL of media for differentiation.
2006 Proposed Change to MSC Nomenclature
Although mesenchymal stromal cells were once referred to as ‘mesenchymal stem cells’, a change to ‘mesenchymal stromal cells’ was proposed by the International Society for Cellular Therapy in 2006.1
The change in nomenclature originates from two important factors:
- Methods used to isolate mesenchymal stem cells yield a heterogeneous population of cells with only a fraction of these cells demonstrating multipotency.
- The absence of direct evidence that mesenchymal stem cells can self-renew and differentiate in vivo.
Use of Mesenchymal Stem and Stromal Cell Terminology
Data supporting MSC self-renewal and multipotency have been obtained using in vitro conditions, which does not adequately reflect the in vivo environment. The lack of in vivo data has led some researchers to question the validity of the term ‘mesenchymal stem cell’ providing further support for the use of ‘mesenchymal stromal cells’ to describe MSCs.2 While ‘mesenchymal stromal cells’ may be the more scientifically accurate term for MSCs, the two terms are often used interchangeably in the literature. R&D Systems recognizes the use of both mesenchymal stem cells and mesenchymal stromal cells and uses ‘MSC’ to indicate mesenchymal stem/stromal cells to account for both designations.
Definitions of Mesenchymal Stromal Cells and Mesenchymal Stem Cells
- Mesenchymal Stromal Cells – A heterogeneous population of cultured cells with similar characteristics such as the ability to adhere to plastic and the expression of specific marker proteins.
- Mesenchymal Stem Cells – A subpopulation of mesenchymal stromal cells that have the capacity to self-renew and differentiate into mesodermal lineages when cultured in vitro. The capacity to self-renew and differentiate in vivo has yet to be clearly demonstrated for mesenchymal stem cells.
References
- Dominici, M. et al. (2006) Cytotherapy 8:315.
- Keating, A. (2012) Cell Stem Cell 10:709.
Specifications
Product Datasheets
Scientific Data
Detection of Aggrecan in a Human MSC-differentiated Chondrogenic Pellet Section. Human MSCs cultured with Human/Mouse/Rat StemXVivo®Chondrogenic Base Media (Catalog # CCM005) and Human/Mouse StemXVivo®Chondrogenic Supplement (Catalog # CCM006) and the resulting chondrogenic pellet was cryosectioned. Chondrocyte differentiation was verified using a Goat Anti-Human Aggrecan Antigen Affinity-purified Polyclonal Antibody (Catalog # AF1220). The cells were stained using a NorthernLights™557-conjugated Donkey Anti-Goat Secondary Antibody (Catalog # NL001) and the nuclei were counterstained with DAPI.
MSCs Differentiated into Chondrocytes form Characteristic Cell Pellets. Human MSCs cultured with Human/Mouse/Rat StemXVivo®Chondrogenic Base Media (Catalog # CCM005) and Human/Mouse StemXVivo®Chondrogenic Supplement (Catalog # CCM006) formed a chondrogenic pellet (ball) imaged here at day 21 of culture.
Detection of Collagen II in a Mouse MSC-differentiated Chondrogenic Pellet Section. Mouse MSCs were cultured for 21 days using the Human/Mouse StemXVivo®Chondrogenic Base Media (Catalog # CCM005) and Human/Mouse StemXVivo®Chondrogenic Supplement (Catalog # CCM006) and the resulting chondrogenic pellet was cryosectioned. Chondrocyte differentiation was verified using a Sheep Anti-Mouse Collagen II Antigen Affinity-purified Polyclonal Antibody (Catalog # AF3615). The cells were stained using a NorthernLights™557-conjugated Donkey Anti-Sheep Secondary Antibody (Catalog # NL010).
Assay Procedure
Refer to the product datasheet for complete product details.
Briefly, human or mouse MSCs are differentiated into chondrocytes using the following in vitro differentiation procedure:
- Culture multipotent cells of interest
- Induce chondrogenic differentiation using a media supplement
- Evaluate differentiation using a mature phenotype marker antibody and fluorescent ICC
For use with Human/Mouse/Rat StemXVivo® Chondrogenic Base Media (Catalog # CCM005).
Reagents supplied in the Human/Mouse StemXVivo® Chondrogenic Supplement (Catalog # CCM006):
- 0.5 mL of StemXVivo® Chondrogenic Supplement
Reagents
- Human/Mouse/Rat StemXVivo® Chondrogenic Base Media (Catalog # CCM005)
- Penicillin-Streptomycin-Glutamate (100X)
Materials
- MSCs
- 15 mL centrifuge tubes
- Pipettes and pipette tips
- Serological pipettes
Equipment
- 37 °C and 5% CO2 incubator
- Centrifuge
- Hemocytometer
- Inverted microscope
- 2 °C to 8 °C refrigerator
- 37 °C water bath
This protocol has been tested using bone marrow- and/or adipose tissue-derived MSCs. If using a different tissue source or cell line, the protocol below may need to be optimized.
Transfer 2.5 x 105 MSCs to a 15 mL conical tube.
Centrifuge and resuspend the cells in Chondrogenic Differentiation Medium.
Centrifuge the cells but do not remove the medium.
Every 2-3 days, replace with fresh Chondrogenic Differentiation Medium.
After 14-21 days, the chondrogenic pellet can be harvested and analyzed.
Citations for StemXVivo Human/Mouse Chondrogenic Supplement, 0.5 mL
R&D Systems personnel manually curate a database that contains references using R&D Systems products. The data collected includes not only links to publications in PubMed, but also provides information about sample types, species, and experimental conditions.
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Citations: Showing 1 - 10
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Characterization of MSCs expressing islet neogenesis associated protein (INGAP): INGAP secretion and cell survival in vitro and in vivo
Authors: Petropavlovskaia, M;Assouline-Thomas, B;Cuerquis, J;Zhao, J;Violette-Deslauriers, S;Nano, E;Eliopoulos, N;Rosenberg, L;
Heliyon 2024-08-15
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3D culture of mesenchymal stem cells from the yolk sac to generate intestinal organoid
Authors: Motta, LCB;Pereira, VM;Pinto, PAF;Mançanares, CAF;Pieri, NCG;de Oliveira, VC;Fantinato-Neto, P;Ambrósio, CE;
Theriogenology 2023-06-16
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Periosteal skeletal stem cells can migrate into the bone marrow and support hematopoiesis after injury
Authors: Marchand, T;Akinnola, KE;Takeishi, S;Maryanovich, M;Pinho, S;Saint-Vanne, J;Birbrair, A;Lamy, T;Tarte, K;Frenette, PS;Gritsman, K;
bioRxiv : the preprint server for biology 2023-01-13
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A FoxA2+ long-term stem cell population is necessary for growth plate cartilage regeneration after injury
Authors: S Muruganand, R Pierce, DA Teguh, RF Perez, N Bell, B Nguyen, K Hohl, BD Snyder, MW Grinstaff, H Alberico, D Woods, Y Kong, C Sima, S Bhagat, K Ho, V Rosen, L Gamer, AM Ionescu
Nature Communications, 2022-05-06;13(1):2515. 2022-05-06
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Single-cell RNA landscape of the osteoimmunology microenvironment in periodontitis
Authors: Y Chen, H Wang, Q Yang, W Zhao, Y Chen, Q Ni, W Li, J Shi, W Zhang, L Li, Y Xu, H Zhang, D Miao, L Xing, W Sun
Theranostics, 2022-01-01;12(3):1074-1096. 2022-01-01
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Regional specialization and fate specification of bone stromal cells in skeletal development
Authors: KK Sivaraj, HW Jeong, B Dharmaling, D Zeuschner, S Adams, M Potente, RH Adams
Cell Reports, 2021-07-13;36(2):109352. 2021-07-13
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Broccoli extract increases drug-mediated cytotoxicity towards cancer stem cells of head and neck squamous cell carcinoma
Authors: OA Elkashty, SD Tran
Br. J. Cancer, 2020-08-10;0(0):. 2020-08-10
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Therapeutic Potential of Dental Pulp Stem Cells and Leukocyte- and Platelet-Rich Fibrin for Osteoarthritis
Authors: M Lo Monaco, P Gervois, J Beaumont, P Clegg, A Bronckaers, JM Vandeweerd, I Lambrichts
Cells, 2020-04-15;9(4):. 2020-04-15
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Transplantation of a 3D-printed tracheal graft combined with iPS cell-derived MSCs and chondrocytes
Authors: IG Kim, SA Park, SH Lee, JS Choi, H Cho, SJ Lee, YW Kwon, SK Kwon
Sci Rep, 2020-03-09;10(1):4326. 2020-03-09
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Comparison of Immunosuppressive and Angiogenic Properties of Human Amnion-Derived Mesenchymal Stem Cells between 2D and 3D Culture Systems
Authors: V Miceli, M Pampalone, S Vella, AP Carreca, G Amico, PG Conaldi
Stem Cells Int, 2019-02-18;2019(0):7486279. 2019-02-18
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Long-term regeneration and remodeling of the pig esophagus after circumferential resection using a retrievable synthetic scaffold carrying autologous cells
Authors: S La Frances, JM Aho, MR Barron, EW Blanco, S Soliman, L Kalenjian, AD Hanson, E Todorova, M Marsh, K Burnette, H DerSimonia, RD Odze, DA Wigle
Sci Rep, 2018-03-07;8(1):4123. 2018-03-07
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Acute myeloid leukemia transforms the bone marrow niche into a leukemia-permissive microenvironment through exosome secretion.
Authors: Kumar B, Garcia M, Weng L, Jung X, Murakami J, Hu X, McDonald T, Lin A, Kumar A, DiGiusto D, Stein A, Pullarkat V, Hui S, Carlesso N, Kuo Y, Bhatia R, Marcucci G, Chen C
Leukemia, 2017-08-17;32(3):575-587. 2017-08-17
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Mesenchymal Cell Reprogramming in Experimental MPLW515L Mouse Model of Myelofibrosis
Authors: Y Han, L Yue, M Wei, X Ren, Z Shao, L Zhang, RL Levine, PK Epling-Bur
PLoS ONE, 2017-01-30;12(1):e0166014. 2017-01-30
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Peripheral blood-derived mesenchymal stem cells: candidate cells responsible for healing critical-sized calvarial bone defects.
Authors: Li S, Huang K, Wu J, Hu M, Sanyal M, Hu M, Longaker M, Lorenz H
Stem Cells Transl Med, 2015-03-05;4(4):359-68. 2015-03-05
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Bone marrow-derived multipotent stromal cells attenuate inflammation in obliterative airway disease in mouse tracheal allografts.
Authors: Casey A, Dirks F, Liang O, Harrach H, Schuette-Nuetgen K, Leeman K, Kim C, Gerard C, Subramaniam M
Stem Cells Int, 2014-09-10;2014(0):468927. 2014-09-10
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Improved quality of cartilage repair by bone marrow mesenchymal stem cells for treatment of an osteochondral defect in a cynomolgus macaque model.
Authors: Araki S, Imai S, Ishigaki H, Mimura T, Nishizawa K, Ueba H, Kumagai K, Kubo M, Mori K, Ogasawara K, Matsusue Y
Acta Orthop, 2014-09-01;0(0):1-8. 2014-09-01
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Cat amniotic membrane multipotent cells are nontumorigenic and are safe for use in cell transplantation.
Authors: Vidane A, Souza A, Sampaio R, Bressan F, Pieri N, Martins D, Meirelles F, Miglino M, Ambrosio C
Stem Cells Cloning, 2014-08-27;7(0):71-8. 2014-08-27
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Label retention identifies a multipotent mesenchymal stem cell-like population in the postnatal thymus.
Authors: Osada M, Singh V, Wu K, Sant'Angelo D, Pezzano M
PLoS ONE, 2013-12-10;8(12):e83024. 2013-12-10
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Molecular characterization of prospectively isolated multipotent mesenchymal progenitors provides new insight into the cellular identity of mesenchymal stem cells in mouse bone marrow.
Authors: Qian H, Badaloni A, Chiara F, Stjernberg J, Polisetti N, Nihlberg K, Consalez G, Sigvardsson M
Mol Cell Biol, 2012-11-26;33(4):661-77. 2012-11-26
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Perivascular mesenchymal progenitors in human fetal and adult liver.
Authors: Gerlach J, Over P, Turner M, Thompson R, Foka H, Chen W, Peault B, Gridelli B, Schmelzer E
Stem Cells Dev, 2012-10-16;21(18):3258-69. 2012-10-16
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Mesenchymal stromal cells improve salivary function and reduce lymphocytic infiltrates in mice with Sjogren's-like disease.
Authors: Khalili S, Liu Y, Kornete M, Roescher N, Kodama S, Peterson A, Piccirillo CA, Tran SD
PLoS ONE, 2012-06-07;7(6):e38615. 2012-06-07
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Primary Mesenchymal Stem and Progenitor Cells from Bone Marrow Lack Expression of CD44 Protein.
Authors: Qian H, Le Blanc K, Sigvardsson M
J. Biol. Chem., 2012-05-31;287(31):25795-807. 2012-05-31
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Mesenchymal stem cells stably transduced with a dominant-negative inhibitor of CCL2 greatly attenuate bleomycin-induced lung damage.
Authors: Saito S, Nakayama T, Hashimoto N, Miyata Y, Egashira K, Nakao N, Nishiwaki S, Hasegawa M, Hasegawa Y, Naoe T
Am. J. Pathol., 2011-07-08;179(3):1088-94. 2011-07-08
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Long-lasting inhibitory effects of fetal liver mesenchymal stem cells on T-lymphocyte proliferation.
Authors: Giuliani M, Fleury M, Vernochet A, Ketroussi F, Clay D, Azzarone B, Lataillade JJ, Durrbach A
2011-05-19;6(5):e19988. 2011-05-19
FAQs
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In the Human Mesenchymal Stem Cell Functional Identification Kit (Catalog # SC006), are Part #'s 90415, 390416, and 390417 the same as the StemXVivo® Human Adipogenic Supplement (Catalog # CCM011), StemXVivo® Human Osteogenic Supplement (Catalog # CCM008), and StemXVivo® Human Chondrogenic Supplement (Catalog # CCM006), respectively?
Yes, the StemXVivo® Human Adipogenic Supplement (Catalog # CCM011), StemXVivo® Human Osteogenic Supplement (Catalog # CCM008), and StemXVivo® Human Chondrogenic Supplement (Catalog # CCM006) are the same as Part #'s 390415, 390416, and 390417, respectively, in the Human Mesenchymal Stem Cell Functional Identification Kit (Catalog # SC006).
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Are there any experimental tips/hints for successful chondrogenic differentiation of mesenchymal stem cells?
The following tips/hints are useful for chondrogenic differentiation:
a) The mesenchymal stem cells (MSCs) should not be from a late passage (passage 8 or less), b) if using the Human Mesenchymal Stem Cell Functional Identification Kit (Catalog # SC006) or the StemXVivo® Chondrogenic Supplement (Catalog # CCM006), use the starting MSC cell number that is indicated in the protocol, c) Early during chondrogenic differentiation a pellet should form. As differentiation progresses, the pellet will grow and take up a ball-like appearance. d) The pellet should not attach to the tube, therefore care should be taken to not dislodge it while changing media.
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