Two-photon microscopy of the mouse cochlea<i>in situ</i>for cellular diagnosis

Yang, Xing; Pu, Ye; Hsieh, Chia-Lung; Ong, Cheng Ai; Psaltis, Demetri; Stanković, Konstantina M.

doi:10.1117/1.jbo.18.3.031104

Cited by 20 publications

(18 citation statements)

References 25 publications

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“…Although the cochlea’s small size and bony capsule make intracochlear interrogation challenging, better non- or minimally-invasive tools to diagnose cellular damage in the inner ear are needed. Promising new technologies soon expected to enter clinical applications include confocal fluorescence microscopy, optical coherence tomography, and in particular two-photon micro-endoscopy, which has been shown in animals to enable the detection of cell-specific damage in situ (Chen et al, 2007; MacDonald et al, 2008; Wong et al, 2000; Yang et al, 2013). Our results suggest that exclusive reliance on audiometric thresholds or word recognition scores in clinical trials of novel therapies for deafness, such as gene therapy, may prematurely disqualify a promising therapy when the current methods for detecting a potentially significant effect are not adequately sensitive.…”

Section: Discussionmentioning

confidence: 99%

Human audiometric thresholds do not predict specific cellular damage in the inner ear

2016

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Introduction As otology enters the field of gene therapy and human studies commence, the question arises whether audiograms – the current gold standard for the evaluation of hearing function – can consistently predict cellular damage within the human inner ear and thus should be used to define inclusion criteria for trials. Current assumptions rely on the analysis of small groups of human temporal bones post mortem or from psychophysical identification of cochlear “dead regions” in vivo, but a comprehensive study assessing the correlation between audiometric thresholds and cellular damage within the cochlea is lacking. Methods A total of 131 human temporal bones from 85 adult individuals (ages 19-92 years, median 69 years) with sensorineural hearing loss due to various etiologies were analyzed. Cytocochleograms – which quantify loss of hair cells, neurons, and strial atrophy along the length of the cochlea – were compared with subjects’ latest available audiometric tests prior to death (time range 5 hours to 22 years, median 24 months). The Greenwood function and the equivalent rectangular bandwidth were used to infer, from cytocochleograms, cochlear locations corresponding to frequencies tested in clinical audiograms. Correlation between audiometric thresholds at clinically tested frequencies and cell type-specific damage in those frequency regions was examined by calculating Spearman’s correlation coefficients. Results Similar audiometric profiles reflected widely different cellular damage in the cochlea. In our diverse group of patients, audiometric thresholds tended to be more influenced by hair cell loss than by neuronal loss or strial atrophy. Spearman’s correlation coefficient across frequencies was at most 0.7 and often below 0.5, with 1.0 indicating perfect correlation. Conclusions Audiometric thresholds do not predict specific cellular damage in the human inner ear. Our study highlights the need for better non- or minimally-invasive tools, such as cochlear endoscopy, to establish cellular-level diagnosis and thereby guide therapy and monitor response to treatment.

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Section: Discussionmentioning

confidence: 99%

Human audiometric thresholds do not predict specific cellular damage in the inner ear

2016

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“…Our results motivate future application of qPLM to characterize various murine models of human hearing loss, based on specific changes in the birefringent properties of cochlear structures. In light of our recent study demonstrating that the optical properties of fixed cochlear tissues are similar to those of unfixed specimens, 38 qPLM data from fixed specimens may ultimately be applied in humans in vivo to guide diagnosis and management through the use of new noninvasive imaging modalities.…”

Section: Resultsmentioning

confidence: 99%

Quantitative polarized light microscopy of unstained mammalian cochlear sections

et al. 2013

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Abstract. Hearing loss is the most common sensory deficit in the world, and most frequently it originates in the inner ear. Yet, the inner ear has been difficult to access for diagnosis because of its small size, delicate nature, complex three-dimensional anatomy, and encasement in the densest bone in the body. Evolving optical methods are promising to afford cellular diagnosis of pathologic changes in the inner ear. To appropriately interpret results from these emerging technologies, it is important to characterize optical properties of cochlear tissues. Here, we focus on that characterization using quantitative polarized light microscopy (qPLM) applied to unstained cochlear sections of the mouse, a common animal model of human hearing loss. We find that the most birefringent cochlear materials are collagen fibrils and myelin. Retardance of the otic capsule, the spiral ligament, and the basilar membrane are substantially higher than that of other cochlear structures. Retardance of the spiral ligament and the basilar membrane decrease from the cochlear base to the apex, compared with the more uniform retardance of other structures. The intricate structural details revealed by qPLM of unstained cochlear sections ex vivo strongly motivate future application of polarization-sensitive optical coherence tomography to human cochlea in vivo.

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“…Establishing the polarization dependent optical properties of normal healthy cochlear tissue is the first step in considering qPLM as a diagnostic tool in vivo. Although the histological sections used in this study were fixed, they are likely representative of unfixed tissue, based on our comparison of polarization dependent optical properties of fixed and unfixed cochlear tissues using two photon microscopy [3]. However, we recognize that fixation can change retardance, scattering and depolarization of polarized light [19], which strongly motivates future studies of unfixed cochlear tissues.…”

Section: Discussionmentioning

confidence: 99%

“…Today, the only source of information about the cellular basis of human deafness is cadaveric human temporal bones that house the inner ear. To enable future cellular-level intracochlear imaging in alive humans, we have been exploring optical imaging tools [3,4] because optics provides higher spatial resolution at a lower cost than techniques based on ionizing radiation or magnetic resonance.…”

Section: Introductionmentioning

confidence: 99%

Quantitative polarized light microscopy of human cochlear sections

Low¹,

Ober²,

McKinley³

et al. 2015

Biomed. Opt. Express

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Dysfunction of the inner ear is the most common cause of sensorineural hearing loss, which is the most common sensory deficit worldwide. Conventional imaging modalities are unable to depict the microanatomy of the human inner ear, hence the need to explore novel imaging modalities. We provide the first characterization of the polarization dependent optical properties of human cochlear sections using quantitative polarized light microscopy (qPLM). Eight pediatric cadaveric cochlear sections, aged 0 (term) to 24 months, were selected from the US National Temporal Bone Registry, imaged with qPLM and analyzed using Image J. Retardance of the bony otic capsule and basilar membrane were substantially higher than that of the stria vascularis, spiral ganglion neurons, organ of Corti and spiral ligament across the half turns of the spiraling cochlea. qPLM provides quantitative information about the human inner ear, and awaits future exploration in vivo. fold imaging with polarization sensitive optical coherence tomography and a MEMS scanning catheter," Opt.

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Two-photon microscopy of the mouse cochleain situfor cellular diagnosis

Cited by 20 publications

References 25 publications

Human audiometric thresholds do not predict specific cellular damage in the inner ear

Human audiometric thresholds do not predict specific cellular damage in the inner ear

Quantitative polarized light microscopy of unstained mammalian cochlear sections

Quantitative polarized light microscopy of human cochlear sections

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