Given our extensive experiences in neuronal differentiation of hESCs [6], [7], [8] and the potential application of hESC - derived neurons in
cell replacement therapies for neurodegenerative diseases, we designed a set of experiments aimed at developing a hESC - based automated assay for screening small molecules that have differential toxicity to hESC - derived NSCs and their differentiated neural progenies.
Beyond Type 1 Provides Grant to ViaCyte to Support Research and Development of
Cell Replacement Therapies for Type 1 Diabetes
«We are grateful to CIRM and the citizens of California for their continued support of our potentially transformative stem cell - derived,
cell replacement therapies for diabetes,» said Paul Laikind, Ph.D., President and CEO of ViaCyte.
«These events offer several venues and platforms to share the exciting progress ViaCyte is making in developing novel
cell replacement therapies for diabetes,» said Paul Laikind, PhD, President and CEO of ViaCyte.
There are now multiple immunotherapies targeting clearance of alpha - synuclein from the brain in early - stage clinical trials, and multiple trials underway or in the works on the next generation of
cell replacement therapies for dopaminergic neurons, including the TRANSEURO trial; the Summit4StemCell initiative, put together by Jeanne Loring — a researcher at The Scripps Research Institute who is exceptionally engaged with turning her research into therapies; a Japanese trial to be run by Jun Takahashi of Kyoto University in Japan (cf. here and here); and a trial centered at Memorial Sloan Kettering Cancer Center headed by cell biologist Lorenz Studer.
Our research goal is to understand the molecular and cellular events required for pancreatic β - cell regeneration, and apply this knowledge towards the development of
cell replacement therapies for diabetes.
This brings together the two leaders in
cell replacement therapies for diabetes.
However, the study led by Pyle found that the current methods are inefficient; they produce immature cells that are not appropriate for modeling Duchenne in the laboratory or creating
a cell replacement therapy for the disease.
«Skeletal muscle created from stem cells: Discovery is major step towards a stem
cell replacement therapy for Duchenne Muscular Dystrophy.»
The findings are a major step towards developing a stem
cell replacement therapy for muscle diseases including Duchenne Muscular Dystrophy, which affects approximately 1 in 5,000 boys in the U.S. and is the most common fatal childhood genetic disease.
ViaCyte's PEC - EncapTM (also known as VC - 01TM) product candidate is the first pluripotent stem cell - derived islet
cell replacement therapy for the treatment of type 1 diabetes in clinical - stage development.
The cells generated in the Zeng lab may not only provide a potential unlimited source for
cell replacement therapy for Parkinson's disease, but also offer an unprecedented opportunity to develop screening models for assessing small molecule drugs and to clarify the mechanisms of disease.
The company is the first to advance an encapsulated islet
cell replacement therapy for type 1 diabetes into clinical trials.
JDRF and ViaCyte Announce Support for Development of PEC - Direct
Cell Replacement Therapy for Type 1 Diabetes
STEP ONE is the first trial in the world investigating a stem cell - derived beta
cell replacement therapy for diabetes.
ViaCyte's VC - 01 ™ product candidate, a first - in - class
cell replacement therapy for the treatment of type 1 diabetes, is currently being evaluated in a Phase 1/2 trial called STEP ONE, or Safety, Tolerability, and Efficacy of VC - 01 Combination Product in Type One Diabetes.
Understanding how heart muscle cells, or cardiomyocytes, change in space improves efforts for studying disease, screening drugs and conducting
cell replacement therapy for future space missions.
As the first company to advance
a cell replacement therapy for type 1 diabetes into the clinic, ViaCyte is committed to developing a functional cure for all type 1 diabetes patients.
The company is the first to advance an encapsulated islet
cell replacement therapy for type -LSB-...]
ViaCyte's stem
cell replacement therapy for the treatment of type 1 diabetes was highlighted in a June 2012 Popular Science article on artificial organs.
Not exact matches
«This research has broad impact, because by deepening our understanding of
cell reprogramming we have the potential to improve disease modeling and the generation of better sources of patient - specific specialized
cells suitable
for replacement therapy,» said Plath.
Diabetes researchers are considering various
replacements for insulin injections: Transplanting new pancreatic islet
cells that make insulin, coaxing the patient's own islets to regenerate, or treating diabetics early in the disease with immune - suppressing
therapies to prevent their body from destroying the rest of their pancreatic islets.
HSCT is effectively used today as a form of «
replacement»
therapy for patients with hard - to - treat blood cancers, providing healthy
cells from either the patient (autologous transplantation) or from a donor (allogeneic transplantation) to better equip patients to fight the disease on their own.
But
for cell replacement therapy to realize its potential, I anticipate that scientists must solve the developmental code, the set of rules that govern the formation of tissues, organs, and beings from the original single
cell — the zygote.
One potential treatment
for CF is gene
therapy, and a major challenge in gene
therapy is packaging
replacement genes so they can be delivered to the target
cells.
«
For the broad application of stem
cell - derived pituitary
cells in the future,
cell replacement therapy may need to be customized to the specific needs of a given patient population,» Zimmer says.
With these findings, Helmholtz Zentrum München scientists have discovered key molecular functions of stem
cell differentiation which could be used
for beta
cell replacement therapy in diabetes.
Our long - term goal, therefore, is to explore the potential to genetically disrupt both ccr5 and cxcr4
for cell replacement therapies in HIV infected individuals, and in the case of cxcr4 do so in a way that specifically targets CXCR4 on T
cells and not the many other
cell types on which it is expressed.
«The loss of insulin - producing beta
cells leads to type 1 diabetes, making it an ideal target
for cell replacement therapy,» said James Shapiro, MD, PhD, FRCSC, Director of the Clinical Islet Transplant Program, University of Alberta.
Regardless of the targeted organ
for cell replacement or regeneration, the shared challenges in
cell therapies for diabetes such as transplant procedure and immune rejection will be well - served by the collective expertise within CCTD.
Cell therapy, as envisaged by the teams of I - Stem, is primarily based on the identification of experimental protocols that can specifically guide differentiation of pluripotent cells to a cell fate, which presents a interest for the replacement of the defective cell population from the patient (the striatal neurons for Huntington's disease, the cells of the retinal pigment epithelium for retinitis pigmentosa, keratinocytes for genodermatoses, et
Cell therapy, as envisaged by the teams of I - Stem, is primarily based on the identification of experimental protocols that can specifically guide differentiation of pluripotent
cells to a
cell fate, which presents a interest for the replacement of the defective cell population from the patient (the striatal neurons for Huntington's disease, the cells of the retinal pigment epithelium for retinitis pigmentosa, keratinocytes for genodermatoses, et
cell fate, which presents a interest
for the
replacement of the defective
cell population from the patient (the striatal neurons for Huntington's disease, the cells of the retinal pigment epithelium for retinitis pigmentosa, keratinocytes for genodermatoses, et
cell population from the patient (the striatal neurons
for Huntington's disease, the
cells of the retinal pigment epithelium
for retinitis pigmentosa, keratinocytes
for genodermatoses, etc.).
«ViaCyte was the first to differentiate human stem
cells into glucose - responsive, insulin - producing
cells, and now we are running the first and only clinical trials of stem
cell - derived islet
replacement therapies for type 1 diabetes,» said Paul Laikind, PhD, President and CEO of ViaCyte.
In addition, ViaCyte launched the first clinical trials
for stem
cell - derived islet
replacement therapies for type 1 diabetes.
SAN DIEGO and BETHESDA, MD, March 3, 2015 — ViaCyte, Inc., a privately - held regenerative medicine company with the first stem
cell - derived islet
replacement therapy for the treatment of diabetes in clinical trials, today announced a presentation by Dr. Eugene Brandon, Director of Strategic Relations and Project Management, at the JDRF TypeOneNation Summit.
SAN DIEGO, April 20, 2016 — ViaCyte, Inc., a privately - held regenerative medicine company with the first pluripotent stem
cell - derived islet
replacement therapy for the treatment of diabetes in clinical - stage development, today announced four presentations at upcoming healthcare events.
This information could then be used to prompt embryonic stem
cells to differentiate in the culture dish into neurons
for potential use in
cell -
replacement therapy.
Comparisons of genetically matched human pluripotent stem
cells reveals that somatic
cell nuclear transfer is the ideal means of generating
cells for replacement therapy
For the first time, researchers demonstrate long term success of a
cell replacement therapy using autologous induced pluripotent stem
cell derivatives
Basically what was happening when you use a hematopoietic stem
cell to correct an inherited metabolic disease is that through engraftment of that
cell you are allowing that
cell to become the
replacement source
for the missing enzyme or other factor - almost like a cellular form of gene
therapy or, as I call it, «poor man's gene
therapy».
The title of the paper is «The Ideal Gene Delivery Vector: Chromallocytes,
Cell Repair Nanorobots
for Chromosome
Replacement Therapy» and it is currently in press at the peer - reviewed Journal of Evolution and Technology (and is soon to be available online).
SAN DIEGO, September 9, 2016 — ViaCyte, Inc., a privately - held regenerative medicine company with the first pluripotent stem
cell - derived islet
replacement therapy for the treatment of diabetes in clinical - stage development, today announced participation on a panel at the 2016 BioPharm ™ America — 9th Annual International Partnering Conference.
In addition, we use our expertise to facilitate the development of functionally mature beta
cells from embryonic stem
cells for cell replacement therapies of type 1 diabetes.
SAN DIEGO, March 17, 2015 — ViaCyte, Inc., a privately - held regenerative medicine company with the first stem
cell - derived islet
replacement therapy for the treatment of diabetes in clinical trials, today announced a presentation by Dr. Paul Laikind, President and CEO, at the third annual Regen Med Investor Day co-hosted by the Alliance
for Regenerative Medicine (ARM) and top financial firm Piper Jaffray.
In addition, the funding will be used to support other operations including the continued development of the PEC - Encap ™ product candidate, ViaCyte's stem
cell - derived islet
replacement therapy that is being developed as a treatment
for all diabetes patients who require insulin to control their disease.
San Diego, January 8, 2015 — ViaCyte, Inc., a privately - held regenerative medicine company with the first stem
cell - derived islet
replacement therapy for the treatment of diabetes in clinical trials, has received a No Objection Letter from Health Canada providing clearance to proceed with sites in Canada
for the Company's Phase 1/2 clinical trial of its VC - 01TM product candidate.
San Diego, California, October 6, 2014 — ViaCyte, Inc., a privately - held regenerative medicine company developing a stem
cell - derived islet replacement therapy for the treatment of diabetes, called VC - 01 ™, will give two presentations at the annual Stem Cell Meeting on the Mesa Conference, being held at the Estancia La Jolla Hotel & Spa and The Salk Institute for Biological Studies, as foll
cell - derived islet
replacement therapy for the treatment of diabetes, called VC - 01 ™, will give two presentations at the annual Stem
Cell Meeting on the Mesa Conference, being held at the Estancia La Jolla Hotel & Spa and The Salk Institute for Biological Studies, as foll
Cell Meeting on the Mesa Conference, being held at the Estancia La Jolla Hotel & Spa and The Salk Institute
for Biological Studies, as follows:
Ultimately, we use all this information to establish innovative culture techniques
for generating unlimited neural stem
cell sources
for the derivation of specific types of clinically relevant neuronal or glial
cells,
for their use in disease modelling and drug discovery platforms, and towards refining their efficacy
for future
cell replacement - based
therapy.
The new iPS
cells generated using novel methods may represent biomedically - and clinically - ideal
cells, providing potential platforms
for studying human disease mechanisms and achieving the long - term goal of personalized
cell -
replacement therapy.
SAN DIEGO, March 1, 2016 — ViaCyte, Inc., a privately - held regenerative medicine company with the first pluripotent stem
cell - derived islet
replacement therapy for the treatment of diabetes in clinical - stage development, today announced presentations at the JDRF TypeOneNation Summit meetings being held in Washington DC and Los Angeles.
Partial clinical hold on high dose SGT - 001 resolved, additional information requested on full clinical hold NIH grant will further development of
replacement beta
cells for type 1 and type 2 diabetes New trial will assess MSCs to improve heart function in heart failure patients ReNeuron wins grant
for retinal
cell therapy development