Featured series 
Tag: Induced pluripotent stem cells
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Nation & World
Progress in treating hearing loss
Harvard Stem Cell Institute researchers have developed a drug cocktail that unlocks the potential to regrow inner-ear hair cells, which could help combat hearing loss.
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Nation & World
Patients’ cells provide possible treatment for blood disorder
Harvard researchers were able, for the first time, to use patients’ own cells to create cells similar to those in bone marrow, and identify potential treatments for a rare blood disorder.
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Nation & World
Creating pain-sensing neurons
Harvard Stem Cell Institute researchers at Boston Children’s Hospital and Harvard’s Department of Stem Cell and Regenerative Biology have successfully converted mouse and human skin cells into pain-sensing neurons that respond to a number of stimuli that cause acute and inflammatory distress.
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Nation & World
New hope in regenerative medicine
Harvard Stem Cell Institute researchers at Boston Children’s Hospital have reprogrammed mature blood cells from mice into blood-forming hematopoietic stem cells (HSCs), using a cocktail of eight genetic switches called transcription factors. The reprogrammed cells have the functional hallmarks of HSCs and are able to self-renew like those cells.
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Nation & World
Big advance against cystic fibrosis
Harvard stem cell researchers at Massachusetts General Hospital have taken a critical step toward discovering in the relatively near future a drug to control cystic fibrosis, a fatal lung disease that claims about 500 lives each year, with 1,000 new cases diagnosed annually.
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Nation & World
Stem cell lessons
Five years after first gaining institutional permission to attempt to produce stem cell lines via somatic cell nuclear transfer (SCNT), two Harvard researchers and a former Harvard postdoctoral fellow have closed the loop with a flurry of new studies and a commentary in several leading journals.
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Nation & World
From skin cells to motor neurons
Harvard stem cell researchers have succeeded in reprogramming adult mouse skin cells directly into the type of motor neurons damaged in amyotrophic lateral sclerosis, best known as Lou Gehrig’s disease, and spinal muscular atrophy.
