Stammzellbasierte Ansätze zur Therapie von Innenohrerkrankungen

Three-Dimensional Otic Neuronal Progenitor Spheroids Derived from Human Embryonic Stem Cells

Stem cell-replacement therapies have been proposed as a potential tool to treat sensorineural hearing loss by aiding the regeneration of spiral ganglion neurons (SGNs) in the inner ear. However, transplantation procedures have yet to be explored thoroughly to ensure proper cell differentiation and optimal transplant procedures. We hypothesized that the aggregation of human embryonic stem cell (hESC)-derived otic neuronal progenitor (ONP) cells into a multicellular form would improve their function and their survival in vivo post-transplantation. We generated hESC-derived ONP spheroids-an aggregate form conducive to differentiation, transplantation, and prolonged cell survival-to optimize conditions for their transplantation. Our findings indicate that these cell spheroids maintain the molecular and functional characteristics similar to those of ONP cells, which are upstream in the SGN lineage. Moreover, our phenotypical, electrophysiological, and mechanical data suggest an optimal spheroid transplantation point after 7 days of in vitro three-dimensional (3D) culture. We have also developed a feasible transplantation protocol for these spheroids using a micropipette aided by a digital microinjection system. In summary, the present work demonstrates that the transplantation of ONP cells in spheroid form into the inner ear through micropipette 7 days after seeding for 3D spheroid culture is an expedient and viable method for stem cell replacement therapies in the inner ear.

Transplantation of mouse-induced pluripotent stem cells into the cochlea for the treatment of sensorineural hearing loss

CONCLUSION

Mouse-induced pluripotent stem cells (iPSCs) could differentiate into hair cell-like cells and spiral ganglion-like cells after transplantation into mouse cochleae, but it cannot improve the auditory brain response (ABR) thresholds in short term.

OBJECTIVE

To evaluate the potential of iPSCs for use as a source of transplants for the treatment of sensorineural hearing loss (SNHL).

METHODS

Establishing SNHL mice model, then injecting the iPSCs or equal volume DMEM basic medium into the cochleae, respectively. Immunofluorescence staining and reverse transcription-polymerase chain reaction (RT-PCR) were used to assess the survival, migration, differentiation of the transplanted iPSCs in cochleae and then recorded the ABR threshold in different time. Hematoxylin-eosin (HE) staining was used to observe the teratoma formation.

RESULTS

Four weeks after transplantation, CM-Di1-labeled iPSCs could be found in the modiolus and Rosenthal's canal (RC), and some of them could expressed auditory hair cell markers or spiral ganglion neuron makers in group A, but not found in group B and C. As to the ABR threshold, no significance differences were found between pre- with postoperative in group A or B. In our study, no teratoma was observed in the cochleae.

Comparing the cultivated cochlear cells derived from neonatal and adult mouse

Background

Previous reports showed the presence of limited numbers of stem cells in neonatal murine cochlear sensory epithelia and these cells are progressively lost during the postnatal development. The goal of this study was to investigate whether stem cells can be derived from mature mouse cochleae under suspension culture conditions, and to analyze the expression of the stem cell and inner ear progenitor cell markers in cells dissociated from neonatal and adult mouse organs of Corti.

Methods

Organs of Corti were dissected from postnatal day 1 (P1) or postnatal day 60 (P60) mouse. The dissociated cells were cultivated under suspension cultures conditions. Reverse transcription-polymerase chain reaction (RT-PCR) and immunocytochemistry were conducted for phenotype characterization.

Results

The number of cochlear stem cells (otospheres) yielded from P1 organ of Corti was significantly higher than that of the P60 organ of Corti. RT-PCR analyses showed that the stem markers, such as nanog, sox2, klf4, and nestin can be found to be distributed similarly in the cells derived from both of organisms, but the inner ear developmental/progenitor cell markers showed lower expression in P60 organ of Corti compared to P1. Immunocytochemistry results also revealed the evidence that P60 otospheres lacking of differentiation potential in vitro, which opposed to the strong differentiation potential of otospheres at P1 stage.

Conclusions

Our findings suggest that the loss of numbers and features of stem cells in the adult organ of Corti is associated with the substantial down-regulation of inner ear progenitor key-markers during maturation of the cells in organ of Corti.

Nanoparticle-based delivery for the treatment of inner ear disorders

PURPOSE OF REVIEW

The delivery of targetable synthetic vectors that can carry a variety of drugs, proteins, and nucleic acids, such as DNA and small interfering RNA (siRNA), to mammalian cells is important as a potential therapeutic system that avoids the problems that are associated with viruses.

RECENT FINDINGS

The so-called multifunctional nanocarriers that are equipped with several functions, such as targetability, shelter from the immune system, and opsonization, and are capable of delivering payload across the nuclear envelope, have been synthesized. To improve transfection efficiency, a group of novel peptides have been attached to the surface of the carrier that will enhance endosomal escape and promote nuclear entry. The targeting of tropomyocin receptor kinase B (TrkB) with ligands enhances uptake in spiral ganglion cell culture. Treatment cargos have included growth factors such as the Math-1 gene, short hairpin RNA, and steroids. The problems with current synthetic nanocarriers are poorer selectivity, internalization, and transfection rate compared with viral vectors.

SUMMARY

Within a few years, when the synthetic vectors have been optimized, the first human drugs/proteins/gene product-based therapies will become available in a phase I study.

Biomaterials in cochlear implants

The cochlear implant (CI) represents, for almost 25 years now, the gold standard in the treatment of children born deaf and for postlingually deafened adults. These devices thus constitute the greatest success story in the field of ‘neurobionic’ prostheses. Their (now routine) fitting in adults, and especially in young children and even babies, places exacting demands on these implants, particularly with regard to the biocompatibility of a CI’s surface components. Furthermore, certain parts of the implant face considerable mechanical challenges, such as the need for the electrode array to be flexible and resistant to breakage, and for the implant casing to be able to withstand external forces.

As these implants are in the immediate vicinity of the middle-ear mucosa and of the junction to the perilymph of the cochlea, the risk exists – at least in principle – that bacteria may spread along the electrode array into the cochlea. The wide-ranging requirements made of the CI in terms of biocompatibility and the electrode mechanism mean that there is still further scope – despite the fact that CIs are already technically highly sophisticated – for ongoing improvements to the properties of these implants and their constituent materials, thus enhancing the effectiveness of these devices.

This paper will therefore discuss fundamental material aspects of CIs as well as the potential for their future development.

[Characterization of stem cells derived from the neonatal auditory sensory epithelium]

BACKGROUND

In contrast to regenerating hair cell-bearing organs of nonmammalian vertebrates the adult mammalian organ of Corti appears to have lost its ability to maintain stem cells. The result is a lack of regenerative ability and irreversible hearing loss following auditory hair cell death. Unexpectedly, the neonatal auditory sensory epithelium has recently been shown to harbor cells with stem cell features. The origin of these cells within the cochlea's sensory epithelium is unknown.

MATERIAL AND METHODS

We applied a modified neurosphere assay to identify stem cells within distinct subregions of the neonatal mouse auditory sensory epithelium. Sphere cells were characterized by multiple markers and morphologic techniques.

RESULTS

Our data reveal that both the greater and the lesser epithelial ridge contribute to the sphere-forming stem cell population derived from the auditory sensory epithelium. These self-renewing sphere cells express a variety of markers for neural and otic progenitor cells and mature inner ear cell types.

CONCLUSION

Stem cells can be isolated from specific regions of the auditory sensory epithelium. The distinct features of these cells imply a potential application in the development of a cell replacement therapy to regenerate the damaged sensory epithelium.

Regenerating cochlear hair cells: quo vadis stem cell

Many elderly people worldwide lose the neurosensory part of their ear and turn deaf. Cochlear implants to restore some hearing after neurosensory hearing loss are, at present, the only therapy for these people. In contrast to this therapy, replacement of hair cells via stem cell therapies holds the promise for a cure. We review here current insights into embryonic, adult, and inducible stem cells that might provide cells for seeding the cochlea with the hope of new hair cell formation. We propose a two-step approach using a first set of transcription factors to enhance the generation of inducible pluripotent stem (iPS) cells and a second set of factors to initiate the differentiation of hair cells. Recent evidence regarding ear development and stem cell research strongly suggest that microRNAs will be an important new regulatory factor in both iPS cell formation and differentiation to reprogram cells into hair cells. In addition, we highlight currently insurmountable obstacles to the successful transformation of stem cells into hair cell precursors and their injection into the cochlear canal to replace lost hair cells.

[The role of the spiral ganglion neurons in cochlear implants. Today and in future regenerative inner ear treatment]

Sensorineural hearing impairment is caused by pathologies within the cochlear portion of the inner ear or the central auditory pathway. Within the last decade, tremendous progress has been made in inner ear biology, thus greatly increasing our understanding of congenital and acquired inner ear pathologies. Moreover, the discovery of hair cell regeneration and the presence of neuronal stem cells in the cochlea has raised hopes of being able to treat the causes of sensorineual hearing impairment in the mid-term future. To do so, the regenerated cells will have to be reinnervated through the peripheral axons of the spiral ganglion neurons (SGNs). So far, most factors with the potential to guide peripheral axons of SGNs have been investigated in the developing cochlea of rodent models but not in humans. Remaining SGNs can already be directly stimulated electrically by cochlear implants, electrode arrays surgically inserted into the cochlea, providing effective treatment for severe cochlear hearing impairment.