Widespread interest and funding for research on regenerative medicine has prompted institutions in the United States and around the world to establish departments and research institutes that specialize in regenerative medicine including: The Department of Rehabilitation and Regenerative Medicine at
Columbia University, the Institute for Stem Cell Biology and Regenerative Medicine at
Stanford University, the Center for Regenerative and Nanomedicine at
Northwestern University, the Wake Forest Institute for Regenerative Medicine, and the British Heart Foundation Centers of Regenerative Medicine at the
University of Oxford. In China, institutes dedicated to regenerative medicine are run by the
Chinese Academy of Sciences,
Tsinghua University, and the
Chinese University of Hong Kong, among others.
In dentistry Regenerative medicine has been studied by dentists to find ways that damaged teeth can be repaired and restored to obtain natural structure and function. Dental tissues are often damaged due to tooth decay, and are often deemed to be irreplaceable except by synthetic or metal dental fillings or crowns, which requires further damage to be done to the teeth by drilling into them to prevent the loss of an entire tooth. Researchers from King's College London have created a drug called
Tideglusib that claims to have the ability to regrow dentin, the second layer of the tooth beneath the enamel which encases and protects the pulp (often referred to as the nerve). Animal studies conducted on mice in Japan in 2007 show great possibilities in regenerating an entire tooth. Some mice had a tooth extracted and the cells from bioengineered tooth germs were implanted into them and allowed to grow. The result were perfectly functioning and healthy teeth, complete with all three layers, as well as roots. These teeth also had the necessary ligaments to stay rooted in its socket and allow for natural shifting. They contrast with traditional dental implants, which are restricted to one spot as they are drilled into the jawbone. A person's baby teeth are known to contain stem cells that can be used for regeneration of the dental pulp after a root canal treatment or injury. These cells can also be used to repair damage from periodontitis, an advanced form of gum disease that causes bone loss and severe gum recession. Research is still being done to see if these stem cells are viable enough to grow into completely new teeth. Some parents even opt to keep their children's baby teeth in special storage with the thought that, when older, the children could use the stem cells within them to treat a condition.
Extracellular matrix Extracellular matrix materials are commercially available and are used in
reconstructive surgery, treatment of
chronic wounds, and some
orthopedic surgeries; as of January 2017 clinical studies were under way to use them in
heart surgery to try to repair damaged heart tissue. The use of fish skin with its natural constituent of
omega 3, has been developed by an
Icelandic company
Kereceis. Omega 3 is a natural
anti-inflammatory, and the fish skin material acts as a scaffold for cell regeneration. In 2016 their product
Omega3 Wound was approved by the
FDA for the treatment of chronic wounds and burns.
Cord blood Though uses of
cord blood beyond blood and immunological disorders is speculative, some research has been done in other areas. Any such potential beyond blood and immunological uses is limited by the fact that cord cells are
hematopoietic stem cells (which can differentiate only into blood cells), and not
pluripotent stem cells (such as
embryonic stem cells, which can differentiate into any type of tissue). Cord blood has been studied as a treatment for diabetes. However, apart from blood disorders, the use of cord blood for other diseases is not a routine clinical modality and remains a major challenge for the stem cell community. and as of 2015 had been studied in vitro, in animal models, and in early stage clinical trials for cardiovascular diseases, as well as neurological deficits, liver diseases, immune system diseases, diabetes, lung injury, kidney injury, and leukemia.
Bioelectricity The potential use of
developmental bioelectricity in regenerative medicine is under active investigation, with particular interest in future organ and limb regeneration guided by bioelectric stimulation. Developmental bioelectricity refers to endogenous ion flows and voltage gradients across cell membranes (Vmem) in excitable (able to create an
action potential) and non-excitable tissues that provide instructive cues for growth. These bioelectric states, set by ion channels and pumps, are propagated through
gap-junction coupling and together with chemical gradients and physical forces they form long-range patterning circuits. Through voltage-sensitive signalling pathways, changes in Vmem modulate gene expression and cell behaviours (proliferation, migration, differentiation), thereby shaping tissue growth and polarity. Experiments in vertebrate and invertebrate models indicate that bioelectric cues can steer regeneration. In
Xenopus tadpoles, activating a proton pump (
V-ATPase) that moves hydrogen ions out of cells is necessary for tail regrowth and can restore regeneration during a normally refractory stage; in adult
Zebrafish, inhibiting the same pump impairs fin regrowth. In
Planarians, brief electrical perturbations can cause tail pieces to form heads (including two-headed animals) or to regenerate heads resembling other species. In adult frogs, a 24-hour treatment with a drug-delivering ‘BioDome’ device initiated long-term hindlimb regrowth with multi-tissue repair and functional recovery. Proposed techniques combine pharmacological control of ion channels and gap junctions,
optogenetic actuators to write Vmem patterns with light, and devices that condition the injury microenvironment or apply controlled direct-current fields. Proposed tools include voltage-sensitive dyes, microelectrodes, and wearable or implantable stimulators. ==See also==