The reaction pattern rules of mouse retinal ganglion cell under different wavelengths of light stimulation / 中华实验眼科杂志
Chinese Journal of Experimental Ophthalmology
; (12): 931-935, 2018.
Article
in Zh
| WPRIM
| ID: wpr-733623
Responsible library:
WPRO
ABSTRACT
Objective To explore the reaction pattern rules of mouse retinal ganglion cells potential under different wavelengths of light stimulation. Methods Thirty SPF grade 3.week.old C57BL/6 mice were used for ex vivo whole mount retina preparation. The cells firing activities were recorded on patch clamp system with on cell touch mode under stimulation of 400 nm,580 nm and white light,respectively. According to different reactions to different light stimulation, the cells were classified into 400 nm sensitive RGC, 580 nm sensitive RGC and color vision insensitive RGC. Then the cells were further classified according to light ON type,light ON/OFF type or light OFF type. The RGC's baseline firing pattern ( baseline firing frequency,burst firing frequency) and light activation firing pattern (response pattern,light response firing frequency,light response firing amplification) were compared among different RGC classifications. Results Eighty.two RGCs were recorded in total. The frequency of spontaneous firing activity ranged from 0. 00 Hz to 32. 33 Hz among different RGCs. 400 nm sensitive RGCs were 52(63. 41%),580 nm sensitive RGCs were 29(35. 37%) and color vision insensitive RGC was 1(1. 22%). OFF type RGC was the main cell type in 400 nm sensitive group (36. 29%),and ON/OFF type RGC was the main cell type in 580 nm sensitive group (34. 48%). The firing amplification in 580 nm sensitive RGC was (22. 93±10. 23)Hz,which was significantly higher than (14. 44±10. 11)Hz in 400 nm sensitive RGC (t=4. 060,P=0. 044). The firing amplification in 580 nm sensitive ON type RGC was (24. 17±8. 98)Hz,which was significantly higher than (11. 12±10. 35)Hz in 400 nm sensitive ON type RGC (t=5. 373,P=0. 021). Conclusions There is no specific firing pattern rules among different light sensitive RGCs. In the future, artificial color vision may be achieved through personalized electric stimulation and learning feedback strategy.
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WPRIM
Language:
Zh
Journal:
Chinese Journal of Experimental Ophthalmology
Year:
2018
Type:
Article