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更新于：2025-05-07

Night Blindness, Congenital Stationary

先天静止性夜盲症

更新于：2025-05-07

基本信息

别名

CONE-ROD SYNAPTIC DISORDER, CONGENITAL NONPROGRESSIVE、CRSD、CSNB - Congenital stationary night blindness

+ [56]

简介

Congenital stationary night blindness (CSNB) refers to a non-progressive group of retinal disorders characterized by night or dim light vision disturbance or delayed dark adaptation, poor visual acuity (ranging from 20/30 to 20/200), myopia (ranging from low (-0.25 diopters [D] to -4.75 D) to high (&#8805;-10.00 D)), nystagmus, strabismus, normal color vision and fundus abnormalities.

关联

靶点-

作用机制

基因转移

在研机构-

原研机构

Institut de la Vision

在研适应症-

非在研适应症

先天静止性夜盲症

最高研发阶段无进展

首次获批国家/地区-

首次获批日期1800-01-20

项与先天静止性夜盲症相关的临床试验

NCT02965534

/ CompletedN/AIIT

Evaluation of a Night Spectacle Correction Concerning an Improvement of Mesopic Vision Quality

Reduced quality of vision and glare in twilight or night are frequently mentioned complaints within the optometric examination. A reason for these problems could be a myopic refractive shift in dark light conditions, commonly known as night myopia or twilight myopia.
The aim of this study was to investigate whether quality of vision in twilight or night could be improved by a spectacle correction optimized for mesopic light conditions. Moreover, objective refraction in large pupils measured by aberrometry was compared to subjective mesopic refraction.

开始日期2015-10-01

申办/合作机构-

NCT02909985

/ CompletedN/AIIT

Visual Activity Evoked by Infrared in Humans After Dark Adaptation

This pilot study will evaluate the visual response to infrared (IR) in humans after dark adaptation. The investigators plan to determine which wavelength and intensity the human eye is most sensitive to in healthy and color-blind participants by using a broad spectrum light source and wavelength-specific IR bandpass filters.
The long-term goal of this research is to better understand the role that IR plays in visual function, and whether this can be manipulated to allow for vision in certain retinal pathologies that result from loss of photoreceptor cells. The investigators central objective is to test the electrophysiologic response to IR in the dark-adapted retinal and visual pathways. The investigator's central hypothesis is that IR evokes a visual response in humans after dark adaptation, and the characteristics of this response suggest transient receptor potential (TRP) channel involvement. The investigators rationale is that a better understanding of how IR impacts vision may allow for an alternative mechanism for vision in a number of diseases that cause blindness from the degradation or loss of function of photoreceptor cells. The investigators will test the investigator's hypothesis with the following Aims:
Aim 1:
Arm 1: To determine the optimal IR wavelength for visual perception in dark-adapted human participants. The investigators hypothesize that the healthy human eye will detect IR irradiation, with a maximum sensitivity at a specific wavelength. Using a broad-spectrum light source with wavelength-specific bandpass filters, the spectral range of visual perception to IR will be evaluated.
Arm 2: To determine the optimal IR wavelength for visual perception in dark-adapted human participants who are colorblind. The investigators hypothesize that the colorblind human eye will detect IR irradiation, with a maximum sensitivity at a specific wavelength. Using a broad-spectrum light source with wavelength-specific bandpass filters, the spectral range of visual perception to IR will be evaluated.

开始日期2015-09-01

申办/合作机构

The University of New Mexico

JPRN-UMIN000018565

/ RecruitingN/AIIT

Genetic testing for Japanese retinitis pigmentosa and related diseases - Genetic testing for Japanese retinitis pigmentosa and related diseases

开始日期2015-09-01

申办/合作机构-

100 项与先天静止性夜盲症相关的临床结果

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100 项与先天静止性夜盲症相关的转化医学

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0 项与先天静止性夜盲症相关的专利（医药）

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692

项与先天静止性夜盲症相关的文献（医药）

2025-04-01·Journal of Equine Veterinary Science

Genetic testing as a tool for diagnosis of congenital stationary night blindness (CSNB) in white spotted breeds in Poland

Article

作者: Ropka-Molik, K ; Bellone, R R ; Stefaniuk-Szmukier, M ; Bieniek, A

Congenital stationary night blindness (CSNB) has been connected to the leopard complex spotting phenotype (LP) in various horse breeds. CSNB associated with LP is thought to be caused by a 1378 bp insertion in TRPM1, with homozygotes being nightblind and having few to no spots of pigment in their white patterned area. This study aimed to assess the prevalence of CSNB alleles in tarant-colored horses in Poland through a three-primer system for an allele-specific Polymerase Chain Reaction (PCR). The TRPM1 gene insertion was genotyped in 221 horses belonging to Małopolska, Felin and Shetland Ponies. The chi-square (χ²) test indicates, that χ2 <5.991 suggesting that the population is in Hardy-Weinberg equilibrium. Of the horses carrying the LP allele, 7 % of Małopolska horses, 4,8 % of Felin ponies and 6.25 % of the Shetland ponies were homozygous for the TRMP1 insertion, indicating low-light vision issues, crucial for horses working in dim conditions. This study highlights the utility of genetic testing for accurate phenotype evaluation, and clinical and breeding management.

2025-03-01·Life Science Alliance

Defective glycosylation and ELFN1 binding of mGluR6 congenital stationary night blindness mutants

Article

作者: Miller, Michael L ; Rideout, Andrew P ; Noppers, Juliet S ; Pindwarawala, Mustansir ; Agosto, Melina A ; Abid, Faiyaz AK ; Lee, Jaeeun

Synaptic transmission from photoreceptors to ON-bipolar cells (BCs) requires the postsynaptic metabotropic glutamate receptor mGluR6, located at BC dendritic tips. Binding of the neurotransmitter glutamate initiates G protein signaling that regulates the TRPM1 transduction channel. mGluR6 also interacts with presynaptic ELFN adhesion proteins, and these interactions are important for mGluR6 synaptic localization. The mechanisms of mGluR6 trafficking and synaptic targeting remain poorly understood. In this study, we investigated mGluR6 missense mutations from patients with congenital stationary night blindness (CSNB), which is associated with loss of synaptic transmission to ON-BCs. We found that multiple CSNB mutations in the extracellular ligand-binding domain of mGluR6 impart a trafficking defect leading to lack of complex N-glycosylation but efficient plasma membrane insertion, suggesting a Golgi bypass mechanism. These mutants fail to bind ELFN1, consistent with lack of a necessary modification normally acquired in the Golgi. The same mutants were mislocalized in bipolar cells, explaining the loss of function in CSNB. The results reveal a key role of Golgi trafficking in mGluR6 function, and suggest a role of the extracellular domain in Golgi sorting.

2025-02-01·British Journal of Ophthalmology

Characterising the refractive error in paediatric patients with congenital stationary night blindness: a multicentre study

Article

作者: Banin, Eyal ; Vincent, Ajoy ; Sisk, Robert ; Kuehlewein, Laura ; Sharon, Dror ; Stephenson, Andrew ; Preising, Markus ; Sundaramurthy, Srilekha ; Webster, Andrew ; Luski, Shahar ; Vincent, Andrea ; Yang, Paul ; Van Den Broeck, Filip ; Balikova, Irina ; Meunier, Isabelle ; Lorenz, Birgit ; Munier, Francis L ; Dollfus, Hélène ; Yassin, Shaden ; Heon, Elise ; Casteels, Ingele ; Schwartz, Hillary ; Raghuram, Aparna ; Everett, Lesley ; Khateb, Samer ; Iannaccone, Alessandro ; Wilson, Lorri B ; Krauss, Emily ; White, Elizabeth ; De Baere, Elfride ; Tayyib, Alaa ; Stingl, Katarina ; Bedoukian, Emma C ; Choi, Dongseok ; Walraedt, Sophie ; Zeitz, Christina ; Kohl, Susanne ; Fredrick, Douglas ; Zanlonghi, Xavier ; Gottlob, Irene ; O'Neil, Erin C ; Nagasamy, Soumittra ; Borooah, Shyamanga ; Aleman, Tomas S ; Mahroo, Omar A ; Jordan, Charlotte ; Katta, Mohamed ; Leroy, Bart Peter ; Reith, Milda ; Pennesi, Mark Edward ; Koenekoop, Robert ; Michaelides, Michel ; Igelman, Austin D ; Fulton, Anne ; Sen, Parveen ; McLean, Rebecca J ; Nagiel, Aaron

Background/Aaims Congenital stationary night blindness (CSNB) is an inherited retinal disease that is often associated with high myopia and can be caused by pathological variants in multiple genes, most commonly CACNA1F , NYX and TRPM1 . High myopia is associated with retinal degeneration and increased risk for retinal detachment. Slowing the progression of myopia in patients with CSNB would likely be beneficial in reducing risk, but before interventions can be considered, it is important to understand the natural history of myopic progression. Methods This multicentre, retrospective study explored CSNB caused by variants in CACNA1F , NYX or TRPM1 in patients who had at least 6 measurements of their spherical equivalent of refraction (SER) before the age of 18. A mixed-effect model was used to predict progression of SER overtime and differences between genotypes were evaluated. Results 78 individuals were included in this study. All genotypes showed a significant myopic predicted SER at birth (−3.076D, −5.511D and −5.386D) for CACNA1F , NYX and TRPM1 respectively. Additionally, significant progression of myopia per year (−0.254D, −0.257D and −0.326D) was observed for all three genotypes CACNA1F , NYX and TRPM1 , respectively. ConclusionsPatients with CSNB tend to be myopic from an early age and progress to become more myopic with age. Patients may benefit from long-term myopia slowing treatment in the future and further studies are indicated. Additionally, CSNB should be considered in the differential diagnosis for early-onset myopia.

项与先天静止性夜盲症相关的新闻（医药）

2023-03-29

·Science Daily

How whale shark rhodopsin evolved to see, in the deep blue sea

A group of researchers discovered that the rhodopsin -- a protein in the eye that detects light -- of whale sharks has changed to efficiently detect blue light, which penetrates deep-sea water easily. The amino acid substitutions -- one of which is counterintuitively associated with congenital stationary night blindness in humans -- aid in detecting the low levels of light in the deep-sea. Although these changes make the whale shark rhodopsin less thermally stable the deep-sea temperature, allows their rhodopsin to keep working. This suggests that the unique adaptation evolved to function in the low-light low-temperature environment where whale sharks live. A research group including Professors Mitsumasa Koyanagi and Akihisa Terakita of the Osaka Metropolitan University Graduate School of Science has investigated both the genetic information and structure of the photoreceptor rhodopsin, responsible for detecting dim light, of whale sharks to investigate how they can see in the dim light at extreme depths. The research group compared the whale sharks to zebra sharks, which are considered their closest relative, and brown-banded bamboo sharks, which are in the same group: the order orectolobiformes -- commonly known as carpet sharks. "This research used genetic information and molecular biological techniques to achieve stunning results -- without harming whale sharks' or their biology. Our research approach is to use these techniques to provide clues that reveal the mysteries of how these organisms live," explained Professor Koyanagi. "The beautiful part is that it even works for species where information is limited, such as large or wild animals that are difficult to observe or follow in their natural habitat." The research revealed that the whale sharks' rhodopsin can efficiently detect blue light -- the most common wavelength of light in the deep-sea -- because two amino acid substitutions shifted the light spectra that rhodopsin detects, making it sensitive to blue wavelengths. However, one of the amino acid substitutions defies conventional wisdom, as it corresponds to a mutation at a position known to cause congenital stationary night blindness in humans. The researchers found that the amino acid substitutions make the whale shark rhodopsin less thermally stable, it decays rapidly at 37 ºC, compared to human or other of sharks' rhodopsin without the substitution. However, at deep-sea temperatures -- well below 37 ºC -- the functionality of the whale shark rhodopsin can be maintained, suggesting that this unique adaptation evolved for life in the low-temperature low-light deep-sea environment.

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