DNA microarray
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DNA Microarray is a technology that allows scientists to examine thousands of genes simultaneously, to understand their expression levels, and to identify genetic variations. This technology has revolutionized the field of genomics, enabling large-scale studies that were previously not possible. DNA microarrays are also known as gene chips, DNA chips, or biochips.
Overview[edit | edit source]
A DNA microarray consists of a small, solid support, typically a glass slide, onto which DNA molecules are fixed in an orderly arrangement. These DNA molecules act as probes to detect complementary DNA or RNA sequences. When target sequences from a sample bind to these probes, they can be quantified, allowing for the analysis of gene expression or the identification of genetic variations.
Types of DNA Microarrays[edit | edit source]
There are two main types of DNA microarrays:
- cDNA Microarrays: These are made by spotting cDNA onto the support. They are typically used for gene expression studies.
- Oligonucleotide Microarrays: These contain short DNA fragments (oligonucleotides) that are synthesized directly onto the surface of the array. They can be used for both gene expression analysis and genotyping.
Applications[edit | edit source]
DNA microarray technology has a wide range of applications, including:
- Gene Expression Profiling: Understanding the expression levels of genes in different conditions, such as healthy vs. diseased tissues.
- Genotyping and SNP Analysis: Identifying genetic variations, such as single nucleotide polymorphisms (SNPs), which can be linked to disease susceptibility.
- Comparative Genomic Hybridization: Comparing genomic DNA from different samples to identify genomic gains and losses.
- Pathogen Detection: Identifying and typing pathogens by detecting their genetic material.
Procedure[edit | edit source]
The general procedure for using a DNA microarray involves:
- Sample Preparation: Extracting RNA or DNA from the sample.
- Labeling: Marking the extracted nucleic acids with fluorescent dyes.
- Hybridization: Incubating the labeled samples with the microarray, allowing complementary sequences to bind.
- Scanning: Using a laser to excite the fluorescent labels and a scanner to measure the intensity of fluorescence.
- Data Analysis: Analyzing the data to interpret gene expression levels or to identify genetic variations.
Challenges and Limitations[edit | edit source]
While DNA microarray technology offers many advantages, there are also challenges and limitations, including:
- Cost: The technology can be expensive, limiting its accessibility.
- Complexity of Data: The vast amount of data generated requires sophisticated tools and expertise for analysis.
- Sensitivity and Specificity: There can be issues with cross-hybridization and background noise, affecting the accuracy of the results.
Future Directions[edit | edit source]
Advancements in DNA microarray technology continue to expand its applications and improve its accuracy and affordability. Integration with other technologies, such as next-generation sequencing, is opening new avenues for research and clinical diagnostics.
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Contributors: Prab R. Tumpati, MD