Radioactive cDNA microarray in Neurospsychiatry.
- Author:
Jae Gol CHOE
1
;
Kyung Ho SHIN
;
Min Soo LEE
;
Meyoung kon KIM
Author Information
1. Department of Nuclear Medicine, Korea University Medical School, Seoul, Korea.
- Publication Type:Original Article
- MeSH:
Animals;
Brain;
Cell Line;
Clone Cells;
DNA, Complementary*;
Drosophila;
Gene Expression;
Humans;
Membranes;
Mice;
Neurodegenerative Diseases;
Neuropsychiatry;
Oligonucleotide Array Sequence Analysis*;
Rats;
RNA
- From:Korean Journal of Nuclear Medicine
2003;37(1):43-52
- CountryRepublic of Korea
- Language:Korean
-
Abstract:
Microarray technology allows the simultaneous analysis of gene expression patterns of thousands of genes, in a systematic fashion, under a similar set of experimental conditions, thus making the data highly comparable. In some cases arrays are used simply as a primary screen leading to downstream molecular characterization of individual gene candidates. In other cases, the goal of expression profiling is to begin to identify complex regulatory networks underlying developmental processes and disease states. Microarrays were originally used with cell lines or other simple model systems. More recently, microarrays have been used in the analysis of more complex biological tissues including neural systems and the brain. The application of cDNA arrays in neuropsychiatry has lagged behind other fields for a number of reasons. These include a requirement for a large amount of input probe RNA in fluorescent-glass based array systems and the cellular complexity introduced by multicellular brain and neural tissues. An additional factor that impacts the general use of microarrays in neuropsychiatry is the lack of availability of sequenced clone sets from model systems. While human cDNA clones have been widely available, high quality rat, mouse, and drosophilae, among others are just becoming widely available. A final factor in the application of cDNA microarrays in neuropsychiatry is cost of commercial arrays. As academic microarray facilitates become more commonplace custom made arrays will become more widely available at a lower cost allowing more widespread applications. In summary, microarray technology is rapidly having an impact on many areas of biomedical research. Radioisotope-nylon based microarrays offer alternatives that may in some cases be more sensitive, flexible, inexpensive, and universal as compared to other array formats, such as fluorescent-glass arrays. In some situations of limited RNA or exotic species, radioactive membrane microarrays may be the most practical experimental approach in studying psychiatric and neurodegenerative disorders, and other complex questions in the brain.
