<p>Genes presented on the x-axis in the order of increasing stability (M value on y-axis) for liver and small intestine (A, B). Determination of the optimal number of control genes for normalization in liver and small intestine (C, D).</p
<p>Pairwise variations between the normalization factors (NF<sub>n</sub> and NF<sub>n+1</sub>) were ...
<p>A) Expression stability measurements (M) for the five reference genes analyzed. The x-axis from l...
Determination of the optimal number of reference genes for normalization relied on the pairwise vari...
<p>Genes presented on the x-axis in the order of increasing stability (M value on y-axis) for liver ...
<p>The average expression stability (M) of 16 candidate reference genes and the best combination of ...
<p>By using geNorm, the optimal number of reference genes in each sample was determined by an analys...
<p>The optimal number of reference genes for normalization by geNorm analysis.</p
<p>(A) Ranking of candidate reference genes according to average expression stability (M value). The...
<p>(A) Left, the least stable gene was excluded stepwise by calculating <i>M</i> values across 50 ov...
<p>The value of Vn/Vn+1 indicates the pairwise variation (Y axis) between two sequential normalizati...
A) Rank order of gene expression stability based on average expression stability values (M) for the ...
<p>geNorm analysis of diploid (a, b), tetraploid (c, d), hexaploid (e, f), and octoploid (g, h) embr...
A) Rank order of gene expression stability based on average expression stability values (M) for the ...
<p>Pairwise variation (V) was calculated for (a) total tissues (b) control tissues and (c) food stre...
A) Rank order of gene expression stability based on average expression stability values (M) for the ...
<p>Pairwise variations between the normalization factors (NF<sub>n</sub> and NF<sub>n+1</sub>) were ...
<p>A) Expression stability measurements (M) for the five reference genes analyzed. The x-axis from l...
Determination of the optimal number of reference genes for normalization relied on the pairwise vari...
<p>Genes presented on the x-axis in the order of increasing stability (M value on y-axis) for liver ...
<p>The average expression stability (M) of 16 candidate reference genes and the best combination of ...
<p>By using geNorm, the optimal number of reference genes in each sample was determined by an analys...
<p>The optimal number of reference genes for normalization by geNorm analysis.</p
<p>(A) Ranking of candidate reference genes according to average expression stability (M value). The...
<p>(A) Left, the least stable gene was excluded stepwise by calculating <i>M</i> values across 50 ov...
<p>The value of Vn/Vn+1 indicates the pairwise variation (Y axis) between two sequential normalizati...
A) Rank order of gene expression stability based on average expression stability values (M) for the ...
<p>geNorm analysis of diploid (a, b), tetraploid (c, d), hexaploid (e, f), and octoploid (g, h) embr...
A) Rank order of gene expression stability based on average expression stability values (M) for the ...
<p>Pairwise variation (V) was calculated for (a) total tissues (b) control tissues and (c) food stre...
A) Rank order of gene expression stability based on average expression stability values (M) for the ...
<p>Pairwise variations between the normalization factors (NF<sub>n</sub> and NF<sub>n+1</sub>) were ...
<p>A) Expression stability measurements (M) for the five reference genes analyzed. The x-axis from l...
Determination of the optimal number of reference genes for normalization relied on the pairwise vari...
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