Title :
Quantum Dots-Enabled High-Resolution Analysis of Gene Copy Number Variation
Author :
Zhang, Yi ; Wang, Tza-Huei
fDate :
6/1/2011 12:00:00 AM
Abstract :
We have developed a novel quantum dot (QD)-enabled copy number variation (CNV) quantification assay. Current CNV detection techniques are not able to reliably quantify less than a twofold difference. The assay employed a QD to physically transform the target copy number into different electrophoretic mobility (EM) levels that could be assessed by the electrophoresis. We built a model to predict the electrophoretic migration and explain the band broadening of the QD-DNA nanocomplex. The nanoassay demonstrated a remarkable resolution, capable of distinguishing a Li fold (~9%) difference in the target copy number. We applied the nanoassay to detect the CNV of the Rsf-1 gene that plays an important role in ovarian cancer.
Keywords :
DNA; biological techniques; electrophoresis; genetics; molecular biophysics; molecular configurations; nanobiotechnology; quantum dots; QD-DNA nanocomplex band broadening; Rsf-1 gene CNV; electrophoresis; electrophoretic migration; electrophoretic mobility levels; gene copy number variation; high resolution analysis; ovarian cancer; quantum dot enabled CNV quantification assay; quantum dots; target copy number; Bioinformatics; Cancer; DNA; Fluorescence; Genomics; Medical image processing; Quantum dots; Self-assembly;
Journal_Title :
Nanotechnology Magazine, IEEE
DOI :
10.1109/MNANO.2011.940950
