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component exponential function  (SYSTAT)

 
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    Structured Review

    SYSTAT component exponential function
    Temporal features of high light-evoked PLRs were equivalent between WT and MNU eyes: A) The initial phase of high light-evoked PLRs is displayed in a short time scale. The latency from the light stimulus onset (black dotted line) to the start of the PLR in WT eyes (blue dotted line) and MNU eyes (red dotted line) are shown. B) A summary graph shows the latency in WT and MNU eyes, which showed a significant delay (p<0.05, Student’s unpaired t-test ). The means for WT and MNU are presented in blue and red. C) The onsets of high light-evoked PLRs were fit by single component <t>exponential</t> decay curves for WT eyes (blue) and MNU (red) injected mice (R2>0.90). D) A scatter plot showing each curve fit’s time constant (tau). MNU exhibited low tau, indicating a faster PLR constriction phase than WT PLR (p<0.05, n=12 mice). E) A scatter plot showing peak constriction showed no differences between WT and MNU mice (p= 0.07, n=12 mice).
    Component Exponential Function, supplied by SYSTAT, used in various techniques. Bioz Stars score: 99/100, based on 12350 PubMed citations. ZERO BIAS - scores, article reviews, protocol conditions and more
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    Images

    1) Product Images from "Melanopsin ganglion cells in the mouse retina independently evoke pupillary light reflex"

    Article Title: Melanopsin ganglion cells in the mouse retina independently evoke pupillary light reflex

    Journal: bioRxiv

    doi: 10.1101/2024.05.14.594181

    Temporal features of high light-evoked PLRs were equivalent between WT and MNU eyes: A) The initial phase of high light-evoked PLRs is displayed in a short time scale. The latency from the light stimulus onset (black dotted line) to the start of the PLR in WT eyes (blue dotted line) and MNU eyes (red dotted line) are shown. B) A summary graph shows the latency in WT and MNU eyes, which showed a significant delay (p<0.05, Student’s unpaired t-test ). The means for WT and MNU are presented in blue and red. C) The onsets of high light-evoked PLRs were fit by single component exponential decay curves for WT eyes (blue) and MNU (red) injected mice (R2>0.90). D) A scatter plot showing each curve fit’s time constant (tau). MNU exhibited low tau, indicating a faster PLR constriction phase than WT PLR (p<0.05, n=12 mice). E) A scatter plot showing peak constriction showed no differences between WT and MNU mice (p= 0.07, n=12 mice).
    Figure Legend Snippet: Temporal features of high light-evoked PLRs were equivalent between WT and MNU eyes: A) The initial phase of high light-evoked PLRs is displayed in a short time scale. The latency from the light stimulus onset (black dotted line) to the start of the PLR in WT eyes (blue dotted line) and MNU eyes (red dotted line) are shown. B) A summary graph shows the latency in WT and MNU eyes, which showed a significant delay (p<0.05, Student’s unpaired t-test ). The means for WT and MNU are presented in blue and red. C) The onsets of high light-evoked PLRs were fit by single component exponential decay curves for WT eyes (blue) and MNU (red) injected mice (R2>0.90). D) A scatter plot showing each curve fit’s time constant (tau). MNU exhibited low tau, indicating a faster PLR constriction phase than WT PLR (p<0.05, n=12 mice). E) A scatter plot showing peak constriction showed no differences between WT and MNU mice (p= 0.07, n=12 mice).

    Techniques Used: Injection



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    Temporal features of high light-evoked PLRs were equivalent between WT and MNU eyes: A) The initial phase of high light-evoked PLRs is displayed in a short time scale. The latency from the light stimulus onset (black dotted line) to the start of the PLR in WT eyes (blue dotted line) and MNU eyes (red dotted line) are shown. B) A summary graph shows the latency in WT and MNU eyes, which showed a significant delay (p<0.05, Student’s unpaired t-test ). The means for WT and MNU are presented in blue and red. C) The onsets of high light-evoked PLRs were fit by single component <t>exponential</t> decay curves for WT eyes (blue) and MNU (red) injected mice (R2>0.90). D) A scatter plot showing each curve fit’s time constant (tau). MNU exhibited low tau, indicating a faster PLR constriction phase than WT PLR (p<0.05, n=12 mice). E) A scatter plot showing peak constriction showed no differences between WT and MNU mice (p= 0.07, n=12 mice).
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    Temporal features of high light-evoked PLRs were equivalent between WT and MNU eyes: A) The initial phase of high light-evoked PLRs is displayed in a short time scale. The latency from the light stimulus onset (black dotted line) to the start of the PLR in WT eyes (blue dotted line) and MNU eyes (red dotted line) are shown. B) A summary graph shows the latency in WT and MNU eyes, which showed a significant delay (p<0.05, Student’s unpaired t-test ). The means for WT and MNU are presented in blue and red. C) The onsets of high light-evoked PLRs were fit by single component <t>exponential</t> decay curves for WT eyes (blue) and MNU (red) injected mice (R2>0.90). D) A scatter plot showing each curve fit’s time constant (tau). MNU exhibited low tau, indicating a faster PLR constriction phase than WT PLR (p<0.05, n=12 mice). E) A scatter plot showing peak constriction showed no differences between WT and MNU mice (p= 0.07, n=12 mice).
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    Image Search Results


    Temporal features of high light-evoked PLRs were equivalent between WT and MNU eyes: A) The initial phase of high light-evoked PLRs is displayed in a short time scale. The latency from the light stimulus onset (black dotted line) to the start of the PLR in WT eyes (blue dotted line) and MNU eyes (red dotted line) are shown. B) A summary graph shows the latency in WT and MNU eyes, which showed a significant delay (p<0.05, Student’s unpaired t-test ). The means for WT and MNU are presented in blue and red. C) The onsets of high light-evoked PLRs were fit by single component exponential decay curves for WT eyes (blue) and MNU (red) injected mice (R2>0.90). D) A scatter plot showing each curve fit’s time constant (tau). MNU exhibited low tau, indicating a faster PLR constriction phase than WT PLR (p<0.05, n=12 mice). E) A scatter plot showing peak constriction showed no differences between WT and MNU mice (p= 0.07, n=12 mice).

    Journal: bioRxiv

    Article Title: Melanopsin ganglion cells in the mouse retina independently evoke pupillary light reflex

    doi: 10.1101/2024.05.14.594181

    Figure Lengend Snippet: Temporal features of high light-evoked PLRs were equivalent between WT and MNU eyes: A) The initial phase of high light-evoked PLRs is displayed in a short time scale. The latency from the light stimulus onset (black dotted line) to the start of the PLR in WT eyes (blue dotted line) and MNU eyes (red dotted line) are shown. B) A summary graph shows the latency in WT and MNU eyes, which showed a significant delay (p<0.05, Student’s unpaired t-test ). The means for WT and MNU are presented in blue and red. C) The onsets of high light-evoked PLRs were fit by single component exponential decay curves for WT eyes (blue) and MNU (red) injected mice (R2>0.90). D) A scatter plot showing each curve fit’s time constant (tau). MNU exhibited low tau, indicating a faster PLR constriction phase than WT PLR (p<0.05, n=12 mice). E) A scatter plot showing peak constriction showed no differences between WT and MNU mice (p= 0.07, n=12 mice).

    Article Snippet: For the analysis of the transient constriction during high light conditions, raw traces were fitted with a single component exponential function (R 2 > .90, SigmaPlot14.5, Systat).

    Techniques: Injection