regenerative medicine

print Print
Please select which sections you would like to print:
verifiedCite
While every effort has been made to follow citation style rules, there may be some discrepancies. Please refer to the appropriate style manual or other sources if you have any questions.
Select Citation Style
Feedback
Corrections? Updates? Omissions? Let us know if you have suggestions to improve this article (requires login).
Thank you for your feedback

Our editors will review what you’ve submitted and determine whether to revise the article.

News

Human vision restored by stem cell replacement in regenerative medicine breakthrough Nov. 13, 2024, 12:15 AM ET (Medical Xpress)
Next-generation regenerative treatment may help prevent tendon re-tears Oct. 25, 2024, 10:03 AM ET (Medical Xpress)

regenerative medicine, the application of treatments developed to replace tissues damaged by injury or disease. These treatments may involve the use of biochemical techniques to induce tissue regeneration directly at the site of damage or the use of transplantation techniques employing differentiated cells or stem cells, either alone or as part of a bioartificial tissue. Bioartificial tissues are made by seeding cells onto natural or biomimetic scaffolds (see tissue engineering). Natural scaffolds are the total extracellular matrixes (ECMs) of decellularized tissues or organs. In contrast, biomimetic scaffolds may be composed of natural materials, such as collagen or proteoglycans (proteins with long chains of carbohydrate), or built from artificial materials, such as metals, ceramics, or polyester polymers. Cells used for transplants and bioartificial tissues are almost always autogeneic (self) to avoid rejection by the patient’s immune system. The use of allogeneic (nonself) cells carries a high risk of immune rejection and therefore requires tissue matching between donor and recipient and involves the administration of immunosuppressive drugs.

Cell and bioartificial tissue transplantation

A variety of autogeneic and allogeneic cell and bioartificial tissue transplantations have been performed. Examples of autogeneic transplants using differentiated cells include blood transfusion with frozen stores of the patient’s own blood and repair of the articular cartilage of the knee with the patient’s own articular chondrocytes (cartilage cells) that have been expanded in vitro (amplified in number using cell culture techniques in a laboratory). An example of a tissue that has been generated for autogeneic transplant is the human mandible (lower jaw). Functional bioartificial mandibles are made by seeding autogeneic bone marrow cells onto a titanium mesh scaffold loaded with bovine bone matrix, a type of extracellular matrix that has proved valuable in regenerative medicine for its ability to promote cell adhesion and proliferation in transplantable bone tissues. Functional bioartificial bladders also have been successfully implanted into patients. Bioartificial bladders are made by seeding a biodegradable polyester scaffold with autogeneic urinary epithelial cells and smooth muscle cells.

Another example of a tissue used successfully in an autogeneic transplant is a bioartificial bronchus, which was generated to replace damaged tissue in a patient affected by tuberculosis. The bioartificial bronchus was constructed from an ECM scaffold of a section of bronchial tissue taken from a donor cadaver. Differentiated epithelial cells isolated from the patient and chondrocytes derived from mesenchymal stem cells collected from the patient’s bone marrow were seeded onto the scaffold.

There are few clinical examples of allogeneic cell and bioartificial tissue transplants. The two most common allogeneic transplants are blood-group-matched blood transfusion and bone marrow transplant. Allogeneic bone marrow transplants are often performed following high-dose chemotherapy, which is used to destroy all the cells in the hematopoietic system in order to ensure that all cancer-causing cells are killed. (The hematopoietic system is contained within the bone marrow and is responsible for generating all the cells of the blood and immune system.) This type of bone marrow transplant is associated with a high risk of graft-versus-host disease, in which the donor marrow cells attack the recipient’s tissues. Another type of allogeneic transplant involves the islets of Langerhans, which contain the insulin-producing cells of the body. This type of tissue can be transplanted from cadavers to patients with diabetes mellitus, but recipients require immunosuppression therapy to survive.

Cell transplant experiments with paralyzed mice, pigs, and nonhuman primates demonstrated that Schwann cells (the myelin-producing cells that insulate nerve axons) injected into acutely injured spinal cord tissue could restore about 70 percent of the tissue’s functional capacity, thereby partially reversing paralysis.

Regeneration using stem cells

Studies on experimental animals are aimed at understanding ways in which autogeneic or allogeneic adult stem cells can be used to regenerate damaged cardiovascular, neural, and musculoskeletal tissues in humans. Among adult stem cells that have shown promise in this area are satellite cells, which occur in skeletal muscle fibres in animals and humans. When injected into mice affected by dystrophy, a condition characterized by the progressive degeneration of muscle tissue, satellite cells stimulate the regeneration of normal muscle fibres. Ulcerative colitis in mice was treated successfully with intestinal organoids (organlike tissues) derived from adult stem cells of the large intestine. When introduced into the colon, the organoids attached to damaged tissue and generated a normal-appearing intestinal lining.

In many cases, however, adult stem cells such as satellite cells have not been easily harvested from their native tissues, and they have been difficult to culture in the laboratory. In contrast, embryonic stem cells (ESCs) can be harvested once and cultured indefinitely. Moreover, ESCs are pluripotent, meaning that they can be directed to differentiate into any cell type, which makes them an ideal cell source for regenerative medicine.

Are you a student?
Get a special academic rate on Britannica Premium.

Studies of animal ESC derivatives have demonstrated that these cells are capable of regenerating tissues of the central nervous system, heart, skeletal muscle, and pancreas. Derivatives of human ESCs used in animal models have produced similar results. For example, cardiac stem cells from heart-failure patients were engineered to express a protein (Pim-1) that promotes cell survival and proliferation. When these cells were injected into mice that had experienced myocardial infarction (heart attack), the cells were found to enhance the repair of injured heart muscle tissue. Likewise, heart muscle cells (cardiomyocytes) derived from human ESCs improved the function of injured heart muscle tissue in guinea pigs.

Derivatives of human ESCs are likely to produce similar results in humans, although these cells have not been used clinically and could be subject to immune rejection by recipients. The question of immune rejection was bypassed by the discovery in 2007 that adult somatic cells (e.g., skin and liver cells) can be converted to ESCs. This is accomplished by transfecting (infecting) the adult cells with viral vectors carrying genes that encode transcription factor proteins capable of reprogramming the adult cells into pluripotent stem cells. Examples of these factors include Oct-4 (octamer 4), Sox-2 (sex-determining region Y box 2), Klf-4 (Kruppel-like factor 4), and Nanog. Reprogrammed adult cells, known as induced pluripotent stem (iPS) cells, are potential autogeneic sources for cell transplantation and bioartificial tissue construction. Such cells have since been created from the skin cells of patients suffering from amyotrophic lateral sclerosis (ALS) and Alzheimer disease and have been used as human models for the exploration of disease mechanisms and the screening of potential new drugs. In one such model, neurons derived from human iPS cells were shown to promote recovery of stroke-damaged brain tissue in mice and rats, and, in another, cardiomyocytes derived from human iPS cells successfully integrated into damaged heart tissue following their injection into rat hearts. These successes indicated that iPS cells could serve as a cell source for tissue regeneration or bioartificial tissue construction.