| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Andrew Stockman, Andrew T Ride. Formulae for generating standard and individual human cone spectral sensitivities. Color research and application. vol 48. issue 6. 2024-03-20. PMID:38504724. |
knowledge of how each type responds to different wavelengths-the three cone spectral sensitivities-can be used to model human color vision and in practical applications to specify color and predict color matches. |
2024-03-20 |
2024-03-23 |
human |
| Andrew Stockman, Andrew T Ride. Formulae for generating standard and individual human cone spectral sensitivities. Color research and application. vol 48. issue 6. 2024-03-20. PMID:38504724. |
the cie has sanctioned the cone spectral sensitivity estimates of stockman and sharpe (stockman and sharpe, 2000, vision res) and their associated measures of luminous efficiency as "physiologically-relevant" standards for color vision (cie, 2006; 2015). |
2024-03-20 |
2024-03-23 |
human |
| Andrew Stockman, Andrew T Ride. Formulae for generating standard and individual human cone spectral sensitivities. Color research and application. vol 48. issue 6. 2024-03-20. PMID:38504724. |
furthermore, these formulae allow the easy computation of non-standard cone spectral sensitivities (and other color matching functions) with individual differences in macular, lens and photopigment optical densities, and with spectrally shifted hybrid or polymorphic l- and m-cone photopigments appropriate for either normal or red-green color vision deficient observers. |
2024-03-20 |
2024-03-23 |
human |
| Pablo A Barrionuevo, María L Sandoval Salinas, José M Fanchin. Are ipRGCs involved in human color vision? Hints from physiology, psychophysics, and natural image statistics. Vision research. vol 217. 2024-03-08. PMID:38458004. |
in comparison with the transient and adaptive nature of cone and rod signals, iprgcs' signaling might provide an ecological advantage to different attributes of color vision. |
2024-03-08 |
2024-03-11 |
human |
| Takuma Sasaki, Kota Katayama, Hiroo Imai, Hideki Kandor. Glu102 Biochemistry. 2024-03-08. PMID:38458614. |
here, we focus on the lumi intermediate formed by thermal relaxation from the initial photointermediate, batho in primate green cone pigment (mg), a light-sensitive gpcr responsible for color vision. |
2024-03-08 |
2024-03-11 |
Not clear |
| Katherine D Chau, Frances E Hauser, Alexander Van Nynatten, Jacob M Daane, Matthew P Harris, Belinda S W Chang, Nathan R Lovejo. Multiple Ecological Axes Drive Molecular Evolution of Cone Opsins in Beloniform Fishes. Journal of molecular evolution. 2024-02-28. PMID:38416218. |
we investigated how diet and habitat affected the molecular evolution of cone opsins, which play a key role in bright light and colour vision and are tightly linked to ecology and life history. |
2024-02-28 |
2024-03-01 |
Not clear |
| Emily R Sechrest, Robert J Barbera, Xiaojie Ma, Frank Dyka, Junyeop Ahn, Brooke A Brothers, Marion E Cahill, Isaac Hall, Wolfgang Baehr, Wen-Tao Den. Expression of red/green-cone opsin mutants K82E, P187S, M273K result in unique pathobiological perturbations to cone structure and function. Frontiers in neuroscience. vol 18. 2024-02-27. PMID:38410159. |
long-and middle-wavelength cone photoreceptors, which are responsible for our visual acuity and color vision, comprise ~95% of our total cone population and are concentrated in the fovea of our retina. |
2024-02-27 |
2024-03-02 |
mouse |
| Gabrielle Lim-Kian-Siang, Arianna R Izawa-Ishiguro, Yong Ra. Neurexin-1-dependent circuit activity is required for the maintenance of photoreceptor subtype identity in Drosophila. Molecular brain. vol 17. issue 1. 2024-01-03. PMID:38167109. |
in the human and drosophila color vision system, each photoreceptor neuron (cone cell in humans and r7/r8 photoreceptor cell in drosophila) makes a stochastic decision to express a single photopigment of the same family with the exclusion of the others. |
2024-01-03 |
2024-01-06 |
human |
| Mikayla L Puska, Michelle M Giarmarco, Jay Neitz, Maureen Neitz, James A Kuchenbecke. Poster Session II: Non-degenerating double cone opsin knockout mouse model of blue cone monochromacy. Journal of vision. vol 23. issue 15. 2023-12-18. PMID:38109588. |
this dko mouse model will be a valuable tool for developing gene therapies targeting cone opsins, and also for understanding color vision circuitry in the retina. |
2023-12-18 |
2023-12-21 |
mouse |
| Vimal Prabhu Pandiyan, Sierra Schleufer, Palash Bharadwaj, Ramkumar Sabesa. Poster Session II: Variation of cone spectral composition in the macula. Journal of vision. vol 23. issue 15. 2023-12-18. PMID:38109590. |
cone spectral composition is central to the study of color vision and retinal development. |
2023-12-18 |
2023-12-21 |
human |
| Yu-Ye Wang, Xu-Fang Liang, Ke L. Knockout of SWS2 in zebrafish (Danio rerio) reveals its roles in feeding and phototactic behaviors. Gene. 2023-12-03. PMID:38043833. |
common ancestor of vertebrates had four cone opsin subfamilies to obtain color vision: ultraviolet-sensitive (sws1), blue-sensitive (sws2), middle wavelength sensitive (rh2) and long wavelength sensitive (lws). |
2023-12-03 |
2023-12-10 |
zebrafish |
| Tom Woelders, Annette E Allen, Robert J Luca. Melanopsin enhances image persistence. Current biology : CB. 2023-11-15. PMID:37967553. |
here, we use a four-primary display to produce stimuli differing in melanopsin versus cone contrast in psychophysical paradigms in eight subjects with normal color vision. |
2023-11-15 |
2023-11-20 |
human |
| Ashley A Farre, Preston Thomas, Johnson Huang, Rachel A Poulsen, Emmanuel Owusu Poku, Deborah L Stenkam. Plasticity of cone photoreceptors in adult zebrafish revealed by thyroid hormone exposure. Scientific reports. vol 13. issue 1. 2023-09-21. PMID:37735192. |
vertebrate color vision is predominantly mediated by the presence of multiple cone photoreceptor subtypes that are each maximally sensitive to different wavelengths of light. |
2023-09-21 |
2023-10-07 |
zebrafish |
| San Joon Lee, Douglas Emery, Eric Vukmanic, Yekai Wang, Xiaoqin Lu, Wei Wang, Enzo Fortuny, Robert James, Henry J Kaplan, Yongqing Liu, Jianhai Du, Douglas C Dea. Metabolic transcriptomics dictate responses of cone photoreceptors to retinitis pigmentosa. Cell reports. vol 42. issue 9. 2023-09-01. PMID:37656622. |
most mutations in retinitis pigmentosa (rp) arise in rod photoreceptors, but cone photoreceptors, responsible for high-resolution daylight and color vision, are subsequently affected, causing the most debilitating features of the disease. |
2023-09-01 |
2023-09-07 |
Not clear |
| Isaac H Rossetto, Kate L Sanders, Bruno F Simões, Nguyen Van Cao, Alastair J Ludingto. Functional Duplication of the Short-Wavelength-Sensitive Opsin in Sea Snakes: Evidence for Reexpanded Color Sensitivity Following Ancestral Regression. Genome biology and evolution. vol 15. issue 7. 2023-07-12. PMID:37434309. |
color vision is mediated by ancient and spectrally distinct cone opsins. |
2023-07-12 |
2023-08-14 |
Not clear |
| Rebeca A S Amaral, Fabiana L Motta, Olivia A Zin, Mariana M da Palma, Gabriela D Rodrigues, Juliana M F Sallu. Molecular and Clinical Characterization of Genes. vol 14. issue 6. 2023-06-28. PMID:37372476. |
molecular and clinical characterization of achromatopsia (achm) is a congenital cone photoreceptor disorder characterized by reduced visual acuity, nystagmus, photophobia, and very poor or absent color vision. |
2023-06-28 |
2023-08-14 |
Not clear |
| Xiangjing Wang, Chunsheng Chen, Li Zhu, Kailu Shi, Baocheng Peng, Yixin Zhu, Huiwu Mao, Haotian Long, Shuo Ke, Chuanyu Fu, Ying Zhu, Changjin Wan, Qing Wa. Vertically integrated spiking cone photoreceptor arrays for color perception. Nature communications. vol 14. issue 1. 2023-06-10. PMID:37301894. |
vertically integrated spiking cone photoreceptor arrays for color perception. |
2023-06-10 |
2023-08-14 |
Not clear |
| Xiangjing Wang, Chunsheng Chen, Li Zhu, Kailu Shi, Baocheng Peng, Yixin Zhu, Huiwu Mao, Haotian Long, Shuo Ke, Chuanyu Fu, Ying Zhu, Changjin Wan, Qing Wa. Vertically integrated spiking cone photoreceptor arrays for color perception. Nature communications. vol 14. issue 1. 2023-06-10. PMID:37301894. |
the cone photoreceptors in our eyes selectively transduce the natural light into spiking representations, which endows the brain with high energy-efficiency color vision. |
2023-06-10 |
2023-08-14 |
Not clear |
| Alireza Beyg. Universality of Form: The Case of Retinal Cone Photoreceptor Mosaics. Entropy (Basel, Switzerland). vol 25. issue 5. 2023-05-27. PMID:37238521. |
cone photoreceptor cells are wavelength-sensitive neurons in the retinas of vertebrate eyes and are responsible for color vision. |
2023-05-27 |
2023-08-14 |
human |
| Dragos Rezeanu, Maureen Neitz, Jay Neit. From cones to color vision: a neurobiological model that explains the unique hues. Journal of the Optical Society of America. A, Optics, image science, and vision. vol 40. issue 3. 2023-05-03. PMID:37132996. |
we propose a neurobiological color vision model that overcomes these challenges by using physiological cone ratios, cone-opponent normalization to equal-energy white, and a simple adaptation mechanism to produce color-opponent mechanisms that accurately predict the spectral locations and variability of the unique hues. |
2023-05-03 |
2023-08-14 |
Not clear |