Introduction to Stem Cell Therapy
By daniellenierenberg
J Cardiovasc Nurs. Author manuscript; available in PMC 2014 Jul 21.
Published in final edited form as:
PMCID: PMC4104807
NIHMSID: NIHMS100185
1Department of Bioengineering, University of Illinois at Chicago
2Department of Physiology and Biophysics and Department of Bioengineering, University of Illinois at Chicago
1Department of Bioengineering, University of Illinois at Chicago
2Department of Physiology and Biophysics and Department of Bioengineering, University of Illinois at Chicago
Stem cells have the ability to differentiate into specific cell types. The two defining characteristics of a stem cell are perpetual self-renewal and the ability to differentiate into a specialized adult cell type. There are two major classes of stem cells: pluripotent that can become any cell in the adult body, and multipotent that are restricted to becoming a more limited population of cells. Cell sources, characteristics, differentiation and therapeutic applications are discussed. Stem cells have great potential in tissue regeneration and repair but much still needs to be learned about their biology, manipulation and safety before their full therapeutic potential can be achieved.
Stem cells have the ability to build every tissue in the human body, hence have great potential for future therapeutic uses in tissue regeneration and repair. In order for cells to fall under the definition of stem cells, they must display two essential characteristics. First, stem cells must have the ability of unlimited self-renewal to produce progeny exactly the same as the originating cell. This trait is also true of cancer cells that divide in an uncontrolled manner whereas stem cell division is highly regulated. Therefore, it is important to note the additional requirement for stem cells; they must be able to give rise to a specialized cell type that becomes part of the healthy animal.1
The general designation, stem cell encompasses many distinct cell types. Commonly, the modifiers, embryonic, and adult are used to distinguish stem cells by the developmental stage of the animal from which they come, but these terms are becoming insufficient as new research has discovered how to turn fully differentiated adult cells back into embryonic stem cells and, conversely, adult stem cells, more correctly termed somatic stem cells meaning from the body, are found in the fetus, placenta, umbilical cord blood and infants.2 Therefore, this review will sort stem cells into two categories based on their biologic properties - pluripotent stem cells and multipotent stem cells. Their sources, characteristics, differentiation and therapeutic applications are discussed.
Pluripotent stem cells are so named because they have the ability to differentiate into all cell types in the body. In natural development, pluripotent stem cells are only present for a very short period of time in the embryo before differentiating into the more specialized multipotent stem cells that eventually give rise to the specialized tissues of the body (). These more limited multipotent stem cells come in several subtypes: some can become only cells of a particular germ line (endoderm, mesoderm, ectoderm) and others, only cells of a particular tissue. In other words, pluripotent cells can eventually become any cell of the body by differentiating into multipotent stem cells that themselves go through a series of divisions into even more restricted specialized cells.
During natural embryo development, cells undergo proliferation and specialization from the fertilized egg, to the blastocyst, to the gastrula during natural embryo development (left side of panel). Pluripotent, embryonic stem cells are derived from the inner cell mass of the blastoctyst (lightly shaded). Multipotent stem cells (diamond pattern, diagonal lines, and darker shade) are found in the developing gastrula or derived from pluripotent stem cells and are restricted to give rise to only cells of their respective germ layer.
Based on the two defining characteristics of stem cells (unlimited self-renewal and ability to differentiate), they can be described as having four outcomes or fates3 (). A common fate for multipotent stem cells is to remain quiescent without dividing or differentiating, thus maintaining its place in the stem cell pool. An example of this is stem cells in the bone marrow that await activating signals from the body. A second fate of stem cells is symmetric self-renewal in which two daughter stem cells, exactly like the parent cell, arise from cell division. This does not result in differentiated progeny but does increase the pool of stem cells from which specialized cells can develop in subsequent divisions. The third fate, asymmetric self-renewal, occurs when a stem cell divides into two daughter cells, one a copy of the parent, the other a more specialized cell, named a somatic or progenitor cell. Asymmetric self-renewal results in the generation of differentiated progeny needed for natural tissue development/regeneration while also maintaining the stem cell pool for the future. The fourth fate is that in which a stem cell divides to produce two daughters both different from the parent cell. This results in greater proliferation of differentiated progeny with a net loss in the stem cell pool.
Four potential outcomes of stem cells. A) Quiescence in which a stem cell does not divide but maintains the stem cell pool. B) Symmetric self-renewal where a stem cell divides into two daughter stem cells increasing the stem cell pool. C) Asymmetric self-renewal in which a stem cell divides into one differentiated daughter cell and one stem cell, maintaining the stem cell pool. D) Symmetric division without self-renewal where there is a loss in the stem cell pool but results in two differentiated daughter cells. (SC- Stem cell, DP-Differentiated progeny)
The factors that determine the fate of stem cells is the focus of intense research. Knowledge of the details could be clinically useful. For example, clinicians and scientists might direct a stem cell population to expand several fold through symmetrical self-renewal before differentiation into multipotent or more specialized progenitor cells. This would ensure a large, homogeneous population of cells at a useful differentiation stage that could be delivered to patients for successful tissue regeneration.
Pluripotent stem cells being used in research today mainly come from embryos, hence the name, embryonic stem cells. Pre-implantation embryos a few days old contain only 10-15% pluripotent cells in the inner cell mass (). Those pluripotent cells can be isolated, then cultured on a layer of feeder cells which provide unknown cues for many rounds of proliferation while sustaining their pluripotency.
Recently, two different groups of scientists induced adult cells back into the pluripotent state by molecular manipulation to yield induced pluripotent stem cells (iPS) that share some of the same characteristics as embryonic stem cells such as proliferation, morphology and gene expression (in the form of distinct surface markers and proteins being expressed).4-8 Both groups used retroviruses to carry genes for transcription factors into the adult cells. These genes are transcribed and translated into proteins that regulate the expression of other genes designed to reprogram the adult nucleus back into its embryonic state. Both introduced the embryonic transcription factors known as Sox2 and Oct4. One group also added Klf4 and c-Myc4, and the other group added Lin28 and Nanog.6 Other combinations of factors would probably also work, but, unfortunately, neither the retroviral carrier method nor the use of the oncogenic transcription factor c-Myc are likely to be approved for human therapy. Consequently, a purely chemical approach to deliver genes into the cells, and safer transcription factors are being tried. Results of these experiments look promising.9
Multipotent stem cells may be a viable option for clinical use. These cells have the plasticity to become all the progenitor cells for a particular germ layer or can be restricted to become only one or two specialized cell types of a particular tissue. The multipotent stem cells with the highest differentiating potential are found in the developing embryo during gastrulation (day 14-15 in humans, day 6.5-7 in mice). These cells give rise to all cells of their particular germ layer, thus, they still have flexibility in their differentiation capacity. They are not pluripotent stem cells because they have lost the ability to become cells of all three germ layers (). On the low end of the plasticity spectrum are the unipotent cells that can become only one specialized cell type such as skin stem cells or muscle stem cells. These stem cells are typically found within their organ and although their differentiation capacity is restricted, these limited progenitor cells play a vital role in maintaining tissue integrity by replenishing aging or injured cells. There are many other sub-types of multipotent stem cells occupying a range of differentiation capacities. For example, multipotent cells derived from the mesoderm of the gastrula undergo a differentiation step limiting them to muscle and connective tissue; however, further differentiation results in increased specialization towards only connective tissue and so on until the cells can give rise to only cartilage or only bone.
Multipotent stem cells found in bone marrow are best known, because these have been used therapeutically since the 1960s10 (their potential will be discussed in greater detail in a later section). Recent research has found new sources for multipotent stem cells of greater plasticity such as the placenta and umbilical cord blood.11 Further, the heart, until recently considered void of stem cells, is now known to contain stem cells with the potential to become cardiac myocytes.12 Similarly, neuro-progenitor cells have been found within the brain.13
The cardiac stem cells are present in such small numbers, that they are difficult to study and their function has not been fully determined. The second review in this series will discuss their potential in greater detail.
Since Federal funding for human embryonic stem cells is restricted in the United States, many scientists use the mouse model instead. Besides their ability to self-renew indefinitely and differentiate into cell types of all three germ layers, murine and human pluripotent stem cells have much in common. It should not be surprising that so many pluripotency traits are conserved between species given the shared genomic sequences and intra-cellular structure in mammals. Both mouse and human cells proliferate indefinitely in culture, have a high nucleus to cytoplasm ratio, need the support of growth factors derived from other live cells, and display similar surface antigens, transcription factors and enzymatic activity (i.e. high alkaline phosphatase activity).14 However, differences between mouse and human pluripotent cells, while subtle, are very important. Although the transcription factors mentioned above to induce pluripotency from adult cells (Oct3/4 and Sox2) are shared, the extracellular signals needed to regulate them differ. Mouse embryonic stem cells need the leukemia inhibitory factor and bone morphogenic proteins while human require the signaling proteins Noggin and Wnt for sustained pluripotency.15 Surface markers used to identify pluripotent cells also differ slightly between the two species as seen in the variants of the adhesion molecule SSEA (SSEA-1 in mouse, SSEA-3 & 4 in humans).16 Thus, while pluripotency research in mouse cells is valuable, a direct correlation to the human therapy is not likely.
Last, but certainly not least, a big difference between mouse and human stem cells are the moral and ethical dilemmas that accompany the research. Some people consider working with human embryonic stem cells to be ethically problematic while very few people have reservations on working with the mouse models. However, given the biological differences between human and mouse cells, most scientists believe that data relevant for human therapy will be missed by working only on rodents.
Cell surface markers are typically also used to identify multipotent stem cells. For example, mesenchymal stem cells can be purified from the whole bone marrow aspirate by eliminating cells that express markers of committed cell types, a step referred to as lineage negative enrichment, and then further separating the cells that express the sca-1 and c-Kit surface markers signifying mesenchymal stem cells. Both the lineage negative enrichment step and the sca-1/c-Kit isolation can be achieved by using flow cytometry and is discussed in further detail in the following review. The c-Kit surface marker also is used to distinguish the recently discovered cardiac stem cells from the rest of the myocardium. A great deal of recent work in cardiovascular research has centered on trying to find which markers indicate early multipotent cells that will give rise to pre-cardiac myocytes. Cells with the specific mesodermal marker, Kdr, give rise to the progenitor cells of the cardiovascular system including contracting cardiac myocytes, endothelial cells and vascular smooth muscle cells and are therefore considered to be the earliest cells with specification towards the cardiovascular lineage.17 Cells at this early stage still proliferate readily and yet are destined to become cells of the cardiovascular system and so may be of great value therapeutically.
Scientists are still struggling to reliably direct differentiation of stem cells into specific cell types. They have used a virtual alphabet soup of incubation factors toward that end (including trying a variety of growth factors, chemicals and complex substrates on which the cells are grown), with, so far, only moderate success. As an example of this complexity, one such approach to achieve differentiation towards cardiac myocytes is to use the chemical activin A and the growth factor BMP-4. When these two factors are administered to pluripotent stem cells in a strictly controlled manner, both in concentration and temporally, increased efficiency is seen in differentiation towards cardiac myocytes, but still, only 30% of cells can be expected to become cardiac.18
Multipotent cells have also been used as the starting point for cell therapy, again with cocktails of growth factors and/or chemicals to induce differentiation toward a specific, desired lineage. Some recipes are simple, such as the use of retinoic acid to induce mesenchymal stem cells into neuronal cells,19 or transforming growth factor- to make bone marrow-derived stem cells express cardiac myocyte markers.20 Others are complicated or ill-defined such as addition of the unknown factors secreted by cells in culture. Physical as well as chemical cues cause differentiation of stem cells. Simply altering the stiffness of the substrate on which cells are cultured can direct stem cells to neuronal, myogenic or osteogenic lineages.21 Cells evolve in physical and chemical environments so a combination of both will probably be necessary for optimal differentiation of stem cells. The importance of physical cues in the cells environment will be discussed in greater detail in the final review of this series. Ideally, for stem cells to be used therapeutically, efficient, uniform protocols must be established so that cells are a well-controlled and well-defined entity.
Pluripotent stem cells have not yet been used therapeutically in humans because many of the early animal studies resulted in the undesirable formation of unusual solid tumors, called teratomas. Teratomas are made of a mix of cell types from all the early germ layers. Later successful animal studies used pluripotent cells modified to a more mature phenotype which limits this proliferative capacity. Cells derived from pluripotent cells have been used to successfully treat animals. For example, animals with diabetes have been treated by the creation of insulin-producing cells responsive to glucose levels. Also, animals with acute spinal cord injury or visual impairment have been treated by creation of new myelinated neurons or retinal epithelial cells, respectively. Commercial companies are currently in negotiations with the FDA regarding the possibility of advancing to human trials. Other animal studies have been conducted to treat several maladies such as Parkinsons disease, muscular dystrophy and heart failure.18,22,23
Scientists hope that stem cell therapy can improve cardiac function by integration of newly formed beating cardiac myocytes into the myocardium to produce greater force. Patches of cardiac myocytes derived from human embryonic stem cells can form viable human myocardium after transplantation into animals,24 with some showing evidence of electrical integration.25,26 Damaged rodent hearts showed slightly improved cardiac function after injection of cardiac myocytes derived from human embryonic stem cells.21 The mechanisms for the gain in function are not fully understood but it may be only partially due to direct integration of new beating heart cells. It is more likely due to paracrine effects that benefit other existing heart cells (see next review).
Multipotent stem cells harvested from bone marrow have been used since the 1960s to treat leukemia, myeloma and lymphoma. Since cells there give rise to lymphocytes, megakaryocytes and erythrocytes, the value of these cells is easily understood in treating blood cancers. Recently, some progress has been reported in the use of cells derived from bone marrow to treat other diseases. For example, the ability to form whole joints in mouse models27 has been achieved starting with mesenchymal stem cells that give rise to bone and cartilage. In the near future multipotent stem cells are likely to benefit many other diseases and clinical conditions. Bone marrow-derived stem cells are in clinical trials to remedy heart ailments. This is discussed in detail in the next review of this series.
Pluripotent and multipotent stem cells have their respective advantages and disadvantages. The capacity of pluripotent cells to become any cell type is an obvious therapeutic advantage over their multipotent kin. Theoretically, they could be used to treat diseased or aging tissues in which multipotent stem cells are insufficient. Also, pluripotent stem cells proliferate more rapidly so can yield higher numbers of useful cells. However, use of donor pluripotent stem cells would require immune suppressive drugs for the duration of the graft28 while use of autologous multipotent stem cells (stem cells from ones self) would not. This ability to use ones own cells is a great advantage of multipotent stem cells. The immune system recognizes specific surface proteins on cells/objects that tell them whether the cell is from the host and is healthy. Autologous, multipotent stem cells have the patients specific surface proteins that allow it to be accepted by the hosts immune system and avoid an immunological reaction. Pluripotent stem cells, on the other hand, are not from the host and therefore, lack the proper signals required to stave off rejection from the immune system. Research is ongoing trying to limit the immune response caused by pluripotent cells and is one possible advantage that iPS cells may have.
The promises of cures for human ailments by stem cells have been much touted but many obstacles must still be overcome. First, more human pluripotent and multipotent cell research is needed since stem cell biology differs in mice and men. Second, the common feature of unlimited cell division shared by cancer cells and pluripotent stem cells must be better understood in order to avoid cancer formation. Third, the ability to acquire large numbers of the right cells at the right stage of differentiation must be mastered. Fourth, specific protocols must be developed to enhance production, survival and integration of transplanted cells. Finally, clinical trials must be completed to assure safety and efficacy of the stem cell therapy. When it comes to stem cells, knowing they exist is a long way from using them therapeutically.
Supported by NIH (HL 62426 and T32 HL 007692)
Visit link:
Introduction to Stem Cell Therapy
- Secretome Therapeutics Closes $20.4 Million Financing Round to Advance Cardiomyopathy and Heart Failure Therapies - Business Wire - November 29th, 2024
- Developing the Cell-Based Therapies of the Future - University of Miami - November 15th, 2024
- Advancing heart stem cell therapy - UHN Foundation - November 15th, 2024
- Heart defects affect 40,000 US babies every year but cutting edge AI and stem cell tech will save lives and even cure them in the womb - New York... - November 15th, 2024
- Science Is Finding Ways to Regenerate Your Heart - The Wall Street Journal - November 6th, 2024
- AIIMS Bathinda Makes Breakthrough in Stem Cell Therapy Research for Heart Ailments - Elets - October 21st, 2024
- USC launches collaboration with StemCardia to advance heart regeneration therapies - University of Southern California - October 13th, 2024
- The heart is a resident tissue for hematopoietic stem and progenitor cells in zebrafish - Nature.com - September 3rd, 2024
- Opthea Announces Results of the A$55.9m (US$36.9m¹) Retail Entitlement Offer - July 16th, 2024
- Benitec Biopharma Reports Continued Durable Improvements in the Radiographic Assessments of Swallowing Efficiency and the Subject-Reported Outcome... - July 16th, 2024
- AstraZeneca Closes Acquisition of Amolyt Pharma - July 16th, 2024
- Addex Presents Positive Results from GABAB PAM Cough Program at the Thirteenth London International Cough Symposium (13th LICS) - July 16th, 2024
- Lexeo Therapeutics Announces Positive Interim Phase 1/2 Clinical Data of LX2006 for the Treatment of Friedreich Ataxia Cardiomyopathy - July 16th, 2024
- ANI Pharmaceuticals Announces the FDA Approval and Launch of L-Glutamine Oral Powder - July 16th, 2024
- MediWound Announces $25 Million Strategic Private Placement Financing - July 16th, 2024
- Atsena Therapeutics Appoints Joseph S. Zakrzewski as Board Chair - July 16th, 2024
- ASLAN Pharmaceuticals Announces Receipt of Nasdaq Delisting Determination; Has Determined Not to Appeal - July 16th, 2024
- Kraig Biocraft Laboratories Completes Phase One of its Spider Silk Production Facility Expansion - July 16th, 2024
- Pliant Therapeutics Announces Positive Long-Term Data from the INTEGRIS-PSC Phase 2a Trial Demonstrating Bexotegrast was Well Tolerated at 320 mg with... - July 16th, 2024
- Oncternal Announces Enrollment Completed and Dosing Initiated for Sixth Dose Cohort of Phase 1/2 Study of ONCT-534 for the Treatment of R/R Metastatic... - July 16th, 2024
- Rectify Pharmaceuticals Appoints Bharat Reddy as Chief Business Officer - July 16th, 2024
- Spectral AI Continues Support of Naked Short Selling Inquiry - July 16th, 2024
- Milestone Pharmaceuticals Refreshes Board of Directors - July 16th, 2024
- New Published Data Highlights Potential Cost-Savings of INPEFA® (sotagliflozin) for Heart Failure - July 16th, 2024
- Regenerative medicine can be a boon for those with Drug-Resistant Tuberculosis - Hindustan Times - April 21st, 2023
- Cardiac stem cells: Current knowledge and future prospects - April 13th, 2023
- Stem cell therapies in cardiac diseases: Current status and future ... - April 13th, 2023
- Stem Cell and Regenerative Biology | Johns Hopkins Heart and Vascular ... - April 13th, 2023
- Center for Regenerative Biotherapeutics - Cardiac Regeneration - April 13th, 2023
- MAGENTA THERAPEUTICS, INC. MANAGEMENT'S DISCUSSION AND ANALYSIS OF FINANCIAL CONDITION AND RESULTS OF OPERATIONS (form 10-K) - Marketscreener.com - March 25th, 2023
- CAREDX, INC. MANAGEMENT'S DISCUSSION AND ANALYSIS OF FINANCIAL CONDITION AND RESULTS OF OPERATIONS (form 10-K) - Marketscreener.com - March 1st, 2023
- A Possible Connection between Mild Allergic Airway Responses and Cardiovascular Risk Featured in Toxicological Sciences - Newswise - February 4th, 2023
- Baby's life saved by surgeon who carried out world's first surgery ... - December 25th, 2022
- An organoid model of colorectal circulating tumor cells with stem cell ... - December 25th, 2022
- Skeletal Muscle Cell Induction from Pluripotent Stem Cells - December 1st, 2022
- Stem-cell niche - Wikipedia - December 1st, 2022
- Scientists Discover Protein Partners that Could Heal Heart Muscle | Newsroom - UNC Health and UNC School of Medicine - October 13th, 2022
- Global Induced Pluripotent Stem Cell ((iPSC) Market to Reach $0 Thousand by 2027 - Yahoo Finance - October 13th, 2022
- Scientists Spliced Human Brain Tissue Into The Brains of Baby Rats - ScienceAlert - October 13th, 2022
- Decoding the transcriptome of calcified atherosclerotic plaque at single-cell resolution | Communications Biology - Nature.com - October 13th, 2022
- Global Synthetic Stem Cells Market Is Expected To Reach Around USD 42 Million By 2025 - openPR - October 13th, 2022
- Merck and Moderna Announce Exercise of Option by Merck for Joint Development and Commercialization of Investigational Personalized Cancer Vaccine -... - October 13th, 2022
- Regenerative Medicine For Heart Diseases: How It Is Better Than Conventional Treatments | TheHealthSite.co - TheHealthSite - October 5th, 2022
- 'Love hormone' oxytocin could help reverse damage from heart attacks via cell regeneration - Study Finds - October 5th, 2022
- Recapitulating Inflammation: How to Use the Colon Intestine-Chip to Study Complex Mechanisms of IBD - Pharmaceutical Executive - September 27th, 2022
- Adult Stem Cells // Center for Stem Cells and Regenerative Medicine ... - September 19th, 2022
- CCL7 as a novel inflammatory mediator in cardiovascular disease, diabetes mellitus, and kidney disease - Cardiovascular Diabetology - Cardiovascular... - September 19th, 2022
- Kite's CAR T-cell Therapy Yescarta First in Europe to Receive Positive CHMP Opinion for Use in Second-line Diffuse Large B-cell Lymphoma and... - September 19th, 2022
- Neural crest - Wikipedia - September 3rd, 2022
- Rise In Number Of CROS In Various Regions Such As Europe Is Expected To Fuel The Growth Of Induced Pluripotent Stem Cell Market At An Impressive CAGR... - September 3rd, 2022
- Discover the Mental and Physical Health Benefits of Fasting - Intelligent Living - September 3rd, 2022
- Heart Association fellowship to support research - Binghamton - August 26th, 2022
- Repeated intravenous administration of hiPSC-MSCs enhance the efficacy of cell-based therapy in tissue regeneration | Communications Biology -... - August 26th, 2022
- High intensity interval training protects the heart against acute myocardial infarction through SDF-1a, CXCR4 receptors and c-kit levels - Newswise - August 26th, 2022
- Yale University: Uncovering New Approaches to a Common Inherited Heart Disorder | India Education - India Education Diary - August 10th, 2022
- Heart failure in obesity: insights from proteomics in patients treated with or without weight-loss surgery | International Journal of Obesity -... - August 10th, 2022
- Pigs died after heart attacks. Scientists brought their cells back to life. - Popular Science - August 10th, 2022
- Protocol for a Nested, Retrospective Study of the Australian Placental Transfusion Study Cohort - Cureus - August 10th, 2022
- Autologous Cell Therapy Market Size to Grow by USD 4.11 billion, Bayer AG and Brainstorm Cell Therapeutics Inc. Among Key Vendors - Technavio - PR... - August 2nd, 2022
- UTSW researcher part of team awarded $36 million heart research grant - The Dallas Morning News - August 2nd, 2022
- Buffalo center fuels research that can save your life from heart disease and stroke - Buffalo News - August 2nd, 2022
- Hyperglycaemia-Induced Impairment of the Autorhythmicity and Gap Junction Activity of Mouse Embryonic Stem Cell-Derived Cardiomyocyte-Like Cells -... - July 25th, 2022
- NASA's Solution to Stem Cell Production is Out of this World - BioSpace - July 25th, 2022
- Inhibition of pancreatic EZH2 restores progenitor insulin in T1D donor | Signal Transduction and Targeted Therapy - Nature.com - July 25th, 2022
- 'My Teen Sweetheart And I Drifted Apart. 30 Years Later I Made a Shocking Discovery' - Newsweek - July 25th, 2022
- EU: New Blood? Proposed Revisions to the EUs Blood, Tissues and Cells Rules - GlobalComplianceNews - July 25th, 2022
- Stem Cells Market to Expand at a CAGR of 10.4% from 2021 to 2028 Travel Adventure Cinema - Travel Adventure Cinema - July 25th, 2022
- Cell Separation Technologies Market Expands with Rise in Prevalence of Chronic Diseases, States TMR Study - GlobeNewswire - July 25th, 2022
- Dental Membrane and Bone Graft Substitutes Market to Exceed Value of US$ 1,337 Mn by 2031 - PR Newswire UK - July 25th, 2022
- Stem Cells Used to Repair Heart Defects in Children - NBC 5 Dallas-Fort Worth - July 16th, 2022
- Pneumonia and Heart Disease: What You Should Know - Healthline - July 16th, 2022
- Promising solution to fatal genetic-disorder complications discovered by University professor and Ph.D. candidate - Nevada Today - July 16th, 2022
- Current and advanced therapies for chronic wound infection - The Pharmaceutical Journal - July 16th, 2022
- Why do some women struggle to breastfeed? A UCSC researcher on what we know, and don't - Lookout Santa Cruz - July 16th, 2022
- Mesenchymal stem cells: from roots to boost - PMC - July 8th, 2022
- New study allows researchers to more efficiently form human heart cells from stem cells - University of Wisconsin-Madison - July 8th, 2022
- Dr Victor Chang saved hundreds of lives. 31 years ago today, he was murdered. - Mamamia - July 8th, 2022
- Exosome Therapeutics Market Research Report Size, Share, New Trends and Opportunity, Competitive Analysis and Future Forecast Designer Women -... - July 8th, 2022
- Cell Line Development Market: Increase in Prevalence of Cancer and Other Chronic Diseases to Drive the Market - BioSpace - July 8th, 2022
- Homology Medicines Announces Peer-Reviewed Publication on Novel Discovery of AAVHSC with Robust Distribution to the Central Nervous System and... - July 8th, 2022