Stem Cell Clinic

Amniotic sac in a dish: Stem cells form structures that may aid of infertility research – Phys.Org

August 8, 2017 The PASE, or post-implantation amniotic sac embryoid, is a structure grown from human pluripotent stem cells that mimics many of the properties of the amniotic sac that forms soon after an embryo implants in the uterus wall. The structures could be used to study infertility. Credit: University of Michigan

The first few weeks after sperm meets egg still hold many mysteries. Among them: what causes the process to fail, leading to many cases of infertility.

Despite the importance of this critical stage, scientists haven't had a good way to explore what can go wrong, or even what must go right, after the newly formed ball of cells implants in the wall of the human uterus.

But a new achievement using human stem cells may help change that. Tiny lab-grown structures could give researchers a chance to see what they couldn't before, while avoiding ethical issues associated with studying actual embryos.

A team from the University of Michigan reports in Nature Communications that they have coaxed pluripotent human stem cells to grow on a specially engineered surface into structures that resemble an early aspect of human development called the amniotic sac.

The cells spontaneously developed some of the same structural and molecular features seen in a natural amniotic sac, which is an asymmetric, hollow ball-like structure containing cells that will give rise to a part of the placenta as well as the embryo itself. But the structures grown at U-M lack other key components of the early embryo, so they can't develop into a fetus.

It's the first time a team has grown such a structure starting with stem cells, rather than coaxing a donated embryo to grow, as a few other teams have done.

"As many as half of all pregnancies end in the first two weeks after fertilization, often before the woman is even aware she is pregnant. For some couples, there is a chronic inability to get past these critical early developmental steps, but we have not previously had a model that would allow us to explore the reasons why," says co-senior author Deborah Gumucio, Ph.D. "We hope this work will make it possible for many scientists to dig deeper into the pathways involved in normal and abnormal development, so we can understand some of the most fascinating biology on earth." Gumucio is the Engel Collegiate Professor of Cell & Developmental Biology at Michigan Medicine, U-M's academic medical center.

A steady PASE

The researchers have dubbed the new structure a post-implantation amniotic sac embryoid, or PASE. They describe how a PASE develops as a hollow spherical structure with two distinct halves that remain stable even as cells divide.

One half is made of cells that will become amniotic ectoderm, the other half consists of pluripotent epiblast cells that in nature make up the embryonic disc. The hollow center resembles the amniotic cavity - which in normal development eventually gives rise to the fluid-filled sac that protects and cushions the fetus during development.

Gumucio likens a PASE to a mismatched plastic Easter egg or a blue-and-red Pokmon ball - with two clearly divided halves of two kinds of cells that maintain a stable form around a hollow center.

The team also reports details about the genes that became activated during the development of a PASE, and the signals that the cells in a PASE send to one another and to neighboring tissues. They show that a stable two-halved PASE structure relies on a signaling pathway called BMP-SMAD that's known to be critical to embryo development.

Gumucio notes that the PASE structures even exhibit the earliest signs of initiating a "primitive streak", although it did not fully develop. In a human embryo, the streak would start a process called gastrulation. That's the division of new cells into three cell layersendoderm, mesoderm and ectodermthat are essential to give rise to all organs and tissues in the body.

Collaboration provides the spark

The new study follows directly from previous collaborative work between Gumucio's lab and that of the other senior author, U-M mechanical engineering associate professor Jianping Fu, Ph.D.

In the previous work, reported in Nature Materials, the team succeeded in getting balls of stem cells to implant in a special surface engineered in Fu's lab to resemble a simplified uterine wall. They showed that once the cells attached themselves to this substrate, they began to differentiate into hollow cysts composed entirely of amnion - a tough extraembryonic tissue that holds the amniotic fluid.

But further analysis of these cysts by co-first authors of the new paper Yue Shao, Ph.D., a graduate student in Fu's lab, and Ken Taniguchi, a postdoctoral fellow in Gumucio's lab, revealed that a small subset of these cysts were stably asymmetric and looked exactly like early human or monkey amniotic sacs.

The team found that such structures could also grow from induced pluripotent stem cells (iPSCs)cells derived from human skin and grown in the lab under conditions that give them the ability to become any type of cell, similar to how embryonic stem cells behave. This opens the door for future work using skin cells donated by couples experiencing chronic infertility, which could be grown into iPSCs and tested for their ability to form proper amniotic sacs using the methods devised by the team.

Important notes and next steps

Besides working with genetic and infertility specialists to delve deeper into PASE biology as it relates to human infertility, the team is hoping to explore additional characteristics of amnion tissue.

For example, early rupture of the amnion tissue can endanger a fetus or be the cause of a miscarriage. The team also intends to study which aspects of human amnion formation also occur in development of mouse amnion. The mouse embryo model is very attractive as an in vivo model for investigating human genetic diseases.

The team's work is overseen by a panel that monitors all work done with pluripotent stem cells at U-M, and the studies are performed in accordance with laws regarding human stem cell research. The team ends experiments before the balls of cells effectively reach 14 developmental days, the cutoff used as an international limit on embryo researcheven though the work involves tissue that cannot form an embryo. Some of the stem cell lines were derived at U-M's privately funded MStem Cell Laboratory for human embryonic stem cells, and the U-M Pluripotent Stem Cell Core.

Explore further: Team uses stem cells to study earliest stages of amniotic sac formation

More information: Yue Shao et al, A pluripotent stem cell-based model for post-implantation human amniotic sac development, Nature Communications (2017). DOI: 10.1038/s41467-017-00236-w

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Amniotic sac in a dish: Stem cells form structures that may aid of infertility research - Phys.Org

BioTech Marketing and market opportunity for Stem Cells – Checkbiotech.org (press release)

The global market for stem cells has been estimated at USD 12 billion in 2016and is projected to reach USD 26.6 billion by 2021, at a CAGR of 13.7% during the forecast period 2016to 2021. A stem cell is an undifferentiated cell that has the potential to develop into any type of cell in the body.

Regenerative medicine is the major application of stem cells and other areas are neurology, orthopedics, oncology, cardiology, hematology and others (diabetes, injuries, and wounds). Another prominent application of stem cells is drug discovery and development. The end-users of this market are usually hospitals, cell banks, clinical research laboratories and academic institutes.

Global Stem Cell Marketing Market Dynamics

The global stem cells market is one of the most promising markets in the field of life sciences at present and is forecasted to grow even more in the coming years as stem cells enable cost-effective treatment of many conditions that currently have poor or no treatment.

Drivers

Some of the factors driving the global stem cells market are:

Restraints

While the global stem cells market has ample scope for growth, there are some factors restraining it as well. These include:

The market for stem cells is segmented on the basis of cell types and technology. The cells type segment includes adult stem cells, human embryonic stem cells, induced pluripotent stem cells, rat neural stem cells and very small embryonic-like stem cells. Adult stem cells are again divided into hematopoietic stem cells, mesenchymal stem cells, neuronal stem cells, dental stem cells and umbilical cord cells. The adult stem cells hold the highest share in the global stem cells market, while the market share of induced pluripotent stem cells is expected to grow in the coming years. The technology segment is divided into stem cell acquisition, stem cell production, stem cell cryopreservation, and stem cell expansion sub-segments.

Based on geography, the global market for stem cells is segmented into North America, Europe, Asia-Pacific and Rest of the World. The global stem cells market is dominated byNorth America, followed byEurope, the estimated market share of which is more than 25% as per a recent study. With 30% of the market, the USA holds the majority of share. However, due to increasing awareness among the public and advances in technologies, the market in the Asia-Pacific is expected to grow at a high rate.

Many players in this market are trying to expand their product portfolio in order to top the global market. While some companies are entering into the market by acquisitions, top companies are expanding their growth in this market by acquiring other companies. Few companies have adopted product innovation and new product launches as their key business strategy to ensure their dominance in this market.

Some of the key players in the market are:

Key Deliverables in the Study

If you are in need of BioTechnology marketing or Stem Cell Marketing call 972-800-6670

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BioTech Marketing and market opportunity for Stem Cells - Checkbiotech.org (press release)

Stem Cell Training and Top Protocols using Human Umbilical Cell Tissue – Checkbiotech.org (press release)

What is HUCT?

Human Umbilical Cell Tissue is stem cells extracted from the umbilical cord, placenta and cord blood from healthy mothers who have been prequalified and deliver through a c-section. HUCT are captured at the earliest point the umbilical cord, placenta and cord blood are ready for utilization in its earliest stages making them some of the best stem cells available for therapy purposes.

Using HUCT stem cells aids in healing otherwise deficient human cells, tissues and organs. In regenerative medicine, the use of cell replacement approaches which usually requires stem cells is a primary therapy. Current research and scientific studies have shown that stem cells can replace bone, fat, cartilage, heart tissue and muscle. Use of stem cells from HUCT has much potential for helping to heal or reduce the severity of many disease states. The umbilical cord serves as a conduit of nutrients for a fetus. Oxygenated nutrient rich blood is carried from the placenta to the fetus until the baby is born. This cord blood within the tissue is rich in primitive stem cells, growth factors and immune cells that are nave as they have to be compatible for the baby and mother. Moreover, the use of allogeneic cord blood has been used for decades in greater than 500 patients with diseases such as Hurlers syndrome, Duchenne muscular dystrophy and Krabbes disease. Most importantly it is safe. These otherwise discarded tissues are an excellent source of high-quality stem cells and growth factors which may be used in regenerative medicine. Utilizing HUCT from the newborn after birth increases the potency and effectiveness of the cells because it is a known fact as we age the number of stem cells greatly diminishes making the HUCT protocol a very popular solution.

Stem cells that are a derivative from umbilical cord tissue are clinically the least invasive and safest method of removal available. Alternative options include extraction from embryonic tissue that is derived from embryos, bone marrow which can be extracted by aspiration and is usually painful, and adipose tissue which can be surgically extracted through liposuction under general anesthesia.

The human umbilical cord is a reliable source of mesenchymal stem cells (HUCMSC). Unlike bone marrow stem cells, HUCMSCs have a comparatively painless collection procedure and faster self-regenerative properties. Different derivation protocols may provide different amounts and populations of stem cells. Stem cell populations have also been identified in other compartments of the umbilical cord, such as the cord lining, perivascular tissue, and Whartons jelly. The use of HUCMSCs are noncontroversial sources compared to embryonic stem cells. They can differentiate into the three germ layers that promote tissue repair, moderate immune response, and anti-cancer properties. Additionally, they are considered more beneficial autologous or allogeneic agents for the treatment of malignant and nonmalignant solid and soft type cancers. Other alternative benefits from HUCT include correction of corneal epithelial defects, burn and diabetic wound ulcer treatment modalities, better osteogenesis capabilities, rescue of liver fibrosis, and hyperglycemia in the diabetic population. In comparison, embryonic stem cells (ESCs) can differentiate into almost all tissues in the human body and are thus labeled as pluripotent. However, the use of ESCs generated from embryos has raised ethical concerns. Furthermore, the clinical applications of therapies derived from embryonic stem cells have been criticized because of the possibility of forming tumors by integrated oncogenes and suppression of cells that disrupt tumor formation. This alternative portrays HUCT as a better, safer choice for clinical applications, efficiency, and safety precautions. Regarding the therapeutic principles of HUCT, effective storage banking systems and protocols should be established immediately.

Isolation by enzymatic digestion Type I collagenase, or collagenase type A, is extensively used for the isolation of mesenchymal-like cells from the cord tissue to facilitate the degradation of matrix ground substance and shortens the time required for the isolation process. The time required for tissue digestion ranges from 30 minutes to 16 hours depending on the quantity/concentration of enzyme and duration of treatment with digesting reagents. Filtration of the digested material through 70100m pore sized cell strainers facilitates the removal of any unwanted tissue debris. Isolation by explants culture The principle of the method is generally described as fine chopping of the Whartons jelly sections of the cord tissue, after excision of the blood vessels, with a scalpel, plating of the fine fragments in sterile culture plates or Petri dishes, and culturing of these with low-glucose DMEM, supplemented with foetal bovine serum (10-20% v/v), L-glutamine and antibiotics/antimycotics. Cryopreservation methods for UCT and hMSCs isolated from UCT: Slow cooling and Vitrification Cryopreservation of cord tissue and/or cells extracted from the tissue represents an important stage to overcome in the view of the therapeutic use of stem cells. HUCT cryopreservation should be able to maintain the cellular metabolism in a dormancy state for an indefinite period of time. Use of defined culture media supplemented with high amounts of foetal bovine serum and 7% 10% (v/v) dimethyl sulfoxide (DMSO) or glycerol and freeze the cells gradually (eg. 10C/min) and keep them between -135C and -196C. After rapid thawing at 37C, viability rates of over 50% can be achieved.

The samples should be frozen for a period of time ranging from 5 to 78 days. The slow cooling protocol was more efficient than the vitrification, for cryopreservation of umbilical cord tissue, because it has caused fewer changes in the structure of tissue (edema and degeneration of the epithelium) and despite the significant decrease cell viability compared to fresh samples, the ability of cell proliferation in vitro is greatly preserved. Cryopreservation of small fragments of tissue from the umbilical cord and to obtain viable cells capable of proliferation in vitro after thawing, contribute to the creation of a frozen tissue bank. In vitro differentiation To successfully differentiated lineages using a variety of cell culture techniques and reagents for in vitro differentiation of Adipocytes, Chondrocytes, Osteocytes, Cardiomyocytes, Skeletal myocytes, Neuronal/glial precursors, Dopaminergic neurons, and Endothelial cells. Independently of their origin, the adipogenic potential of HUCT MSCs is inversely related to the length of in vitro culture, and sharply declines when HUCT MSCs become senescent. Contrary, prolonged culturing increases their osteogenic differentiation. In vitro expansion of HUCT MSCs should, therefore, be performed with limited passaging, to avoid changes in their differentiation ability. Gradual shortening of the telomeres during a cells life continues until the presence of critically short telomeres triggers a senescence pathway, which results in proliferation arrest. Because of that, a normal human cell can only divide 50 to 100 times in vitro conditions; HUCT MSCs are no exception. UC blood HUCT MSCs, however, have slightly longer telomeres than other MSCs, and thus can be cultured for longer periods before they senesce. Proliferation arrest in HUCT MSCs results in their senescence, which is described by the appearance of large senescent cells with a flat shape, circumscribed nuclei, and increased lysosome compartment. These morphological changes are not restricted to the senescent stage only, but represent continuous alterations in the course of HUCT MSCs long-term culture. Immunophenotyping of HUCT MSCs Characterisation of HUCT MSCs is generally accomplished by flow cytometry analysis of surface markers. Stro-1 has been identified as a marker for cells that can differentiate into multiple mesenchymal lineages. CD9/CD90/CD166 triple positive subpopulation of HUCT MSCs showed multipotency for chondrogenic, osteogenic and adipogenic differentiation providing a basis for identification of HUCT MSCs. It has been indicated that positive expression of CD166 is indicative of multipotency in HUCT MSCs. Expression levels of CD90 and CD105 are maintained over sequential passages and they can be important for validating cultures of HUCT MSCs intended for therapy. A good indication of HUCT MSC identity can be reached by expression of CD90, CD105 and CD166 and lack of expression of CD34 and CD45 as a minimum set of surface markers. Variability in MSCs extraction from HUCT There are ways of minimizing variations between lots produced, by controlling process parameters, and by screening the raw materials that will be in contact with the cells and cell source. There are other noncontrollable parameters such as the source of the cells, which represents a real challenge for regenerative medicine applications. Each cell extraction method is produced with cells from a different patient/donor, with intrinsic characteristics that result in variations of cell growth patterns and differentiation. It is, therefore, necessary to develop extraction methods that are suitable to real world applications. It is necessary to map the operating environment and assess risk factors before empirically determining the effect on the process. This will be particularly critical for processes using primary tissue or cell sources where the biological variation at input is likely to be high. Regulated therapeutic products will require characterized and risk assessed manufacturing processes. This fits the philosophy of process control industry tools such as quality by design (QbD) and Six Sigma, represent approaches to understanding process operating space and risks of associated variables. Extraction of hMSCs from umbilical cord tissue via enzymatic digestion. 200-400 mg cord slices from multiple cords, both fresh and frozen, with the purpose to screen different methods for an assessment of method success with a view to downstream standardization of the isolation and expansion of mesenchymal stem cells from the HUCT aided in the development of this protocol.

2 hours enzyme digestion of cord tissue with 3 different enzymatic solutions: 9 (200 400 mg) slices of cord tissue were digested in 3 ml of enzymatic solution/each; solutions obtained after digestion were filtered through 40 m cell strainers and centrifuged at 1500 rcf for 10 min/each; all cord tissue is kept frozen through this initial process.

4 hours enzyme digestion of cord tissue with 3 different enzymatic solutions: 9 (200 400 mg) slices of cord tissue were digested in 3 ml of enzymatic solution/each; solutions obtained after digestion were filtered through 70 m cell strainers and centrifuged at 1500 rcf for 10 min/each; all cord tissue still remains frozen.

18 hours enzyme digestion of cord tissue with 3 different enzymatic solutions: 9 (200 400 mg) slices of cord tissue were digested in 3 ml of enzymatic solution/each; solutions obtained after digestion were filtered through 70 m cell strainers and centrifuged at 1500 rcf for 10 min/each; all cord tissue still remains frozen.

2, 4 and 18 hours enzyme digestion of cord tissue with 3 different enzymatic solutions: 18 (200 400 mg) slices of cord tissue were digested in 3 ml of enzymatic solution/each; solutions obtained after digestion were filtered through 70 m cell strainers and centrifuged at 1500 rcf for 10 min/each; all cord tissue is fresh (2 days old).

2, 4 and 18 hours enzyme digestion of cord tissue with 3 different enzymatic solutions: 18 (200 400 mg) slices of cord tissue were digested in 5 ml of enzymatic solution/each; solutions obtained after digestion were filtered through 100 m cell strainers and centrifuged at 500 rcf for 10 min/each; cord tissue is frozen.

2, 4 and 18 hours enzyme digestion of cord tissue with 3 different enzymatic solutions: 9 (200 400 mg) slices of cord tissue were digested in 5 ml of enzymatic solution/each; solutions obtained after digestion were filtered through 100 m cell strainers; no centrifugation for slices digested with 2 of the enzymatic solutions and 1000 rcf centrifugation speed for slices digested with the 3rd type of enzymatic solution; cord tissue is frozen.

2, 4 and 18 hours enzyme digestion of cord tissue with 3 different enzymatic solutions: 9 (200 400 mg) slices of cord tissue were digested in 5 ml of enzymatic solution/each; solutions obtained after digestion were filtered through 100 m cell strainers; no centrifugation for slices digested with 2 of the enzymatic solutions and 1000 rcf centrifugation speed for slices digested with the 3rd type of enzymatic solution; cord tissue is fresh (not frozen).

18 hours enzyme digestion of cord tissue with cord banks method and reagents: (200 400 mg) slices of cord tissue were digested in 5 ml of enzymatic solution/each; solutions obtained after digestion were filtered through 100 m cell strainers and diluted with 3ml of culture media, before being plated in T25 flasks; no centrifugation; cord tissue is frozen.

a) Vials containing cryopreserved 200-400 mg cord tissue slices are defrosted by placing them in a 37C water bath for 3-5 minutes, or until only a trace of ice remains b) After, cryovials are transferred to a Class II biological safety cabinet (BSC) and the cord sections are removed from cryovials with a sterile aspirator stripette and placed in a Petri dish containing DPBS + 1% antibiotic/antimycotic v/v (PSA) in it. c) Individual slices are transferred to a fresh, sterile Petri dish, and chopped up into fine fragments (1-2mm3 ), with the aid of a scalpel and forceps. The fragments are then placed into a 15 ml centrifuge tube, with the aid of a scalpel and forceps. d) Cord slice fragments are enzymatically digested for 2h, 4h or 18h at 37C, with the following enzymatic solutions: A. Collagenase type I, (in serum free growth Medium A, 3-5ml/slice), 300 CDU/ml; B. Collagenase type I, 300 CDU/ml + hyaluronidase, 1mg/ml (in serum free growth Medium A, 3-5ml/slice); C. Collagenase type I, 300 CDU/ml for 1, 3 or 17 1/2 h, depending on the digestion period, followed by trypsin-EDTA 0.25% for a further 30 min (both enzyme solutions are prepared in serum free growth Medium A, 3-5ml/slice) e) Upon completion of digestion, tubes containing slices digested with enzymatic solutions A and B, are treated as follows: 5.1 Diluted 50% with serum free growth Medium A. 5.2 Filtered through a 40m, a 70m, or a 100m cell strainer; squeezing remaining tissue fragments with the forceps to aid cell release after filtration. 5.3 Centrifuged cell suspension at 1500 rcf for 10 min, 500 rcf for 10 min, or no centrifugation. 5.3.1 In the case of no centrifugation, an appropriate amount of FBS (final concentration 10%) os added to the suspension before filtration and 2ml of fresh growth media to wash the cell strainer with. 5.3.2 For methods that involved centrifugation the supernatant is discarded and the pellet re-suspended in 5ml of fresh growth Medium A; 5.4 Count cells by using a disposable haemocytometer (20l of cell suspension and 20l of trypan blue); and seeded at 104 cell/cm2 , in an appropriately sized culture vessel. f) Upon completion of digestion, tubes containing slices digested with method C, are treated according to the protocol below: 6.1 Diluted 50% with serum free growth Medium A.Centrifuged at 1500 rcf for 10 min, 500 rcf, or 1000 rcf. 6.2 Discarded supernatant and re-suspended pellet in 3-5ml of 0.25% trypsin-EDTA; 6.3 Replaced in the incubator for another 30 minutes. 6.4 After 30 min took tubes out and added 0.3-0.5ml of FBS/each tube to stop the enzyme action. 6.6 Diluted 50% with serum free growth Medium A. 6.5 Filtered through a 40m, a 70m, or a 100m cell strainer; squeezing remaining tissue fragments with the forceps to aid cell release after filtration. 6.7 Centrifuged at 1500 rcf for 10 min, 500 rcf, or 1000 rcf. 6.8 Discarded supernatant and re-suspended pellet in 5ml of fresh Medium A. 6.8.1 Counted cells by using a disposable haemocytometer (20l of cell suspension and 20l of trypan blue); and seeded at 104 cell/cm , in an appropriately sized culture vessel. g) All culture vessels are incubated at 37C and 5% CO2 in a humidified incubator. h) First media change is performed after 48h and every 3 days thereafter until cells have reached 80-85% confluence.

Protocol for enzymatic digestion of fresh cord tissue Procedure: a. For processing, cord sections are removed from tubes, inside a BSC, with sterile forceps and positioned on sterile prep trays; the outside of the cord is wiped with alcohol wipes (also held with sterile forceps to avoid touching cord surface). The remaining cord blood is squeezed from the cord by pressing the blunt edge of a sterile scalpel along the length of the cord. b. The cord tissue sections are then placed in a Petri dish with DPBS and 1% PSA in it. Swirled contents to wash. If the saline water is really cloudy with blood, the wash step is repeated. c. Cord sections are cut into 200-400 mg slices (approximately 2-4mm thick, depending on the thickness of the cord), and placed into separate Petri dishes with fresh DPBS and 1% PSA, to wash. The slices are then placed in separate Petri dishes with warm, serum free Media A. Each slice is weighed in a pre-weighed sterile, closed container; only slices that weigh approximately 300 mg are used, in order to maintain consistency. d. Each slice, is placed on a separate, sterile Petri dish, and chopped up in fine fragments (1-2mm). The fragments from each slice are placed in individual 15 ml centrifuge tubes. e. Cord fragments are enzymatically digested for 2h, 4h or 18h at 37C, with the following enzymatic solutions: A. Collagenase type I, (in serum free growth Medium A, 3-5ml/slice), 300 CDU/ml; B. Collagenase type I, 300 CDU/ml + hyaluronidase, 1mg/ml (in serum free growth Medium A, 3-5ml/slice); Mesenchymal Stem Cell E, C. Collagenase type I, 300 CDU/ml for 1, 3 or 17 1/2 h, depending on the digestion period, followed by trypsin-EDTA 0.25% for a further 30 min (both enzyme solutions being prepared in serum free growth Medium A, 3-5ml/slice); f. For tubes containing slices digested with methods A and B, after digestion time had finished, refer to previous protocol, step e-g. For tubes containing slices digested with method C, after digestion time has finished refer to previous protocol, step f. g. All culture vessels are incubated at 37C and 5% CO2, in a humidified incubator. h. First media change is performed after 48h and every 3 days thereafter until cells reached 80-85% confluence.

Protocol for enzymatic digestion of fresh and frozen cord tissue with the cord banks method a. Take each UCT slice, placed on separate, sterile Petri dish, and chop it up into fine tissue fragments (1-2mm3 ), which are then placed in individual 15 ml centrifuge tubes; b. Fragments from each slice are digested for 18h with: 2.1 collagenase type I (AMS Biotechnology Ltd, UK) 5ml/slice/tube; enzyme solution is prepared in serum free growth Medium B, at a concentration of 0.075% (750 CDU/ml) enzymatic solution A (used by cord blood bank); 2.2 collagenase type I (Sigma Aldrich, UK) 5ml/slice/tube; enzyme solution is prepared in serum free growth Medium B, at a concentration of 0.075% (750 CDU/ml) enzymatic solution B. c. Upon completion of digestion: Filter all digested slices through 100m cell strainer in 50 ml tubes; squeezing remaining tissue fragments with the forceps to aid cell release after filtration. 0.5ml FBS (provided by cord blood bank) + 3ml growth Media B are added to the suspension resulted from a slice digested with enzymatic solution A, through the cells strainer; this action served two purposes, releasing the remaining cells on the strainer and dilution of suspension. d. 0.5ml FBS (provided by cord blood bank) + 3ml growth Media B is added to the suspension, resulted from a slice digested with enzymatic solution B, through the cells strainer. 0.5ml FBS + 3ml growth Media B is added to the suspension resulted from a slice digested with enzymatic solution A, through the cells strainer. 3.3 The cell suspension obtained after filtration and dilution is seeded in T25 culture flasks. e. All culture vessels incubate at 37C and 5% CO2, in a humidified incubator. f. After 48h, culture flasks are removed from the incubator, spent media containing dead cells and extracellular matrix, left over from the digestion process, is aspirated and a wash with warm DPBS is performed. After washing the surface of the cell culture, fresh, warm (37C), growth Media B is added. Media change was performed after that every 3 days until cells reached 80-85% confluence.

Stem Cell References: Conconi MT, Burra P, Di Liddo R et al., 2006. CD105(+) cells from Whartons jelly show in vitro and in vivo myogenic differentiative potential. Int J Mol Med, 18, pp. 1089 1096 Ding, D., Chang, Y., Shyu, W., & Lin, S. (2015). Human Umbilical Cord Mesenchymal Stem Cells: A New Era for Stem Cell Therapy. Cell Transplantation, 24(3), 339-347. Fan CG, Zhang Q, Zhou J 2011. Therapeutic Potentials of Mesenchymal Stem Cells Derived from Human Umbilical Cord. Stem Cell Rev., 7(1), pp. 195-207. Fazzina, R., Mariotti, A., Procoli, A., Fioravanti, D., Iudicone, P., Scambia, G., & Bonanno, G. (2015). A new standardized clinical-grade protocol for banking human umbilical cord tissue cells. Transfusion, 55(12), 2864-2873. doi:10.1111/trf.13277 Izadpanah R, Kaushal D, Kriedt C, et al., 2008. Long-term in vitro expansion alters the biology of adult mesenchymal stem cells. Cancer Res., 68, pp. 4229-4238. Lu LL, Liu YJ, Yang SG et al., 2006. Isolation and characterization of human umbilical cord mesenchymal stem cells with hematopoiesis-supportive function and other potentials. Haematologica, 91, pp. 10171026. Petsa A, et al., 2009. Effectiveness of protocol for the isolation of Whartons jelly stem cells in large-scale applications. In Vitro Cell. Dev. Biol. Animal, The Society for In Vitro Biology. Thomas RJ, Hourd P, Williams DJ, 2008. Application of process quality engineering techniques to improve the understanding of the in vitro processing of stem cells for therapeutic use. Journal of Biotechnology, 136, pp. 148155.

This is an informational page designed to help collect information and share information. It is not intended to provide medical advice nor is it qualified by any government source. Stem Cells are not FDA approved but the labs and tissue banks should be in the US. Author is not a doctor and we do not provide medical advice on this page, if you need medical assistance call a professional or in the US dial 911 for an emergency.

Read more:
Stem Cell Training and Top Protocols using Human Umbilical Cell Tissue - Checkbiotech.org (press release)