The use of animal models to study cell transplantation in neuropathic hearing loss

Abbas, Leïla; Rivolta, Marcelo N.

doi:10.1016/j.heares.2019.03.014

Cited by 11 publications

(9 citation statements)

References 192 publications

(192 reference statements)

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“…In vivo environmental factors have been shown to substantially improve cell specification 122 and tissue maturation upon in situ transdifferentiation 178 or transplantation, 59 suggesting that the local niche signals may enhance reprogramming compared to in vitro. Adapting preclinical animal models developed for cell replacement strategies through transplantation 180 to probe in situ reprogramming may enable to test whether the generation of glutamatergic neurons with proper peripheral and central connection may suffice to relay acoustic or electrical signals.…”

Section: Stem Cell‐based Application For Hearing Researchmentioning

confidence: 99%

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Directed differentiation and direct reprogramming: Applying stem cell technologies to hearing research

Roccio

2020

Stem Cells

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Hearing loss is the most widely spread sensory disorder in our society. In the majority of cases, it is caused by the loss or malfunctioning of cells in the cochlea: the mechanosensory hair cells, which act as primary sound receptors, and the connecting auditory neurons of the spiral ganglion, which relay the signal to upper brain centers.In contrast to other vertebrates, where damage to the hearing organ can be repaired through the activity of resident cells, acting as tissue progenitors, in mammals, sensory cell damage or loss is irreversible. The understanding of gene and cellular functions, through analysis of different animal models, has helped to identify causes of disease and possible targets for hearing restoration. Translation of these findings to novel therapeutics is, however, hindered by the lack of cellular assays, based on human sensory cells, to evaluate the conservation of molecular pathways across species and the efficacy of novel therapeutic strategies. In the last decade, stem cell technologies enabled to generate human sensory cell types in vitro, providing novel tools to study human inner ear biology, model disease, and validate therapeutics. This review focuses specifically on two technologies: directed differentiation of pluripotent stem cells and direct reprogramming of somatic cell types to sensory hair cells and neurons. Recent development in the field are discussed as well as how these tools could be implemented to become routinely adopted experimental models for hearing research.

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Section: Stem Cell‐based Application For Hearing Researchmentioning

confidence: 99%

“…Adapting preclinical animal models developed for cell replacement strategies through transplantation 180 to probe in situ reprogramming may enable to test whether the generation of glutamatergic neurons…”

Section: In Situ Directed Reprogramming To Trigger Cell Replacementmentioning

confidence: 99%

Directed differentiation and direct reprogramming: Applying stem cell technologies to hearing research

Roccio

2020

Stem Cells

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“…However, the incomplete differentiation of the organ of Corti at early stages can result in a response that differs between young postnatal animals and adults, because of the higher regenerative potential and differences in sensitivity of neonates to ototoxic agents (Henley and Rybak, 1995). Alternatively, toxicity and regeneration can be studied directly in vivo, using animal models in which hearing thresholds or sensory cell survival can be tested (Abbas and Rivolta, 2015;Abbas and Rivolta, 2019;Breglio et al, 2017;Furman et al, 2013;Kujawa and Liberman, 2019). The level of complexity of animal testing using rodents is substantial, and as only a small number of compounds or concentrations can be handled simultaneously, these experiments are difficult to scale up to medium-or high-throughput screens.…”

Section: Drug Screensmentioning

confidence: 99%

“…Transplantation of PSC-derived (otic) neuronal progenitor cells into the modiolus/nerve trunk has been advancing in preclinical models and is a viable option to repopulate the spiral ganglion after cell loss resulting from neuropathies (Chen et al, 2012;Corrales et al, 2006;Shi et al, 2007). This approach could increase the effectiveness of neuroprosthetic stimulation in cochlear implant recipients (Abbas and Rivolta, 2019). Whether spiral ganglion neuron progenitors derived using the latest 3D induction protocol would lead to improved functional outcomes remains to be tested.…”

Section: Cell Replacementmentioning

confidence: 99%

Inner ear organoids: new tools to understand neurosensory cell development, degeneration and regeneration

Roccio

Edge

2019

Development

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The development of therapeutic interventions for hearing loss requires fundamental knowledge about the signaling pathways controlling tissue development as well as the establishment of human cell-based assays to validate therapeutic strategies ex vivo. Recent advances in the field of stem cell biology and organoid culture systems allow the expansion and differentiation of tissue-specific progenitors and pluripotent stem cells in vitro into functional hair cells and otic-like neurons. We discuss how inner ear organoids have been developed and how they offer for the first time the opportunity to validate drugbased therapies, gene-targeting approaches and cell replacement strategies.

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“…Moza Al-Kowari* and Meritxell Espino-Guarch Translational Medicine, Sidra Medicine Hospital, Doha, Qatar *Address all correspondence to: malkowari@sidra.org the in-depth study of stem cell and its therapeutic potential, stem cell technology opened new approaches for hair cell and auditory nerve regeneration [137,138]. By using two strategies of endogenous stem cell activation and exogenous stem cell transplantation, exciting results on restoring hearing function are showed.…”

Section: Author Detailsmentioning

confidence: 99%

Genetics and Acquired Hearing Loss

Alkowari¹,

Guarch²

2019

Geriatric Medicine and Gerontology

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Hearing loss (HL) is a worldwide disease with substantial economic costs for the public health. Around 466 million people have disabling hearing loss and the WHO estimated that by 2050 over 900 million people will suffer hearing loss. Several factors including infections, noise-exposure, ototoxic medications or genetic disorders could cause hearing impairment. Hearing devices such as cochlear implants and aids are the current therapies. Although the prevalence of hearing loss is very high, alternative treatments as pharmaceutical agents are currently insufficient. Within the past years, increased knowledge on hearing loss etiology and physiopathology opened new opportunities for future research towards hearing loss treatment. Here we aim to review current bibliography on genetics factors involved in hearing loss.

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The use of animal models to study cell transplantation in neuropathic hearing loss

Cited by 11 publications

References 192 publications

Directed differentiation and direct reprogramming: Applying stem cell technologies to hearing research

Directed differentiation and direct reprogramming: Applying stem cell technologies to hearing research

Inner ear organoids: new tools to understand neurosensory cell development, degeneration and regeneration

Genetics and Acquired Hearing Loss

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