Virtual karyotype: Difference between revisions
CSV import Tags: mobile edit mobile web edit |
CSV import |
||
| Line 20: | Line 20: | ||
[[Category:Bioinformatics]] | [[Category:Bioinformatics]] | ||
{{stub}} | {{stub}} | ||
<gallery> | |||
File:NHGRI_human_male_karyotype.png|Human male karyotype | |||
File:virtual_karyotype_karyogram.jpg|Virtual karyotype karyogram | |||
File:CLL_ForWiki.jpg|Chronic Lymphocytic Leukemia karyotype | |||
File:gene-duplication.png|Gene duplication | |||
File:Her2Neu.jpg|HER2/neu gene amplification | |||
File:Copy_neutral_LOH.jpg|Copy neutral loss of heterozygosity | |||
File:CRCforwiki.jpg|Colorectal cancer karyotype | |||
File:Human_karyotype_with_bands_and_sub-bands.png|Human karyotype with bands and sub-bands | |||
</gallery> | |||
Latest revision as of 11:17, 18 February 2025
Virtual Karyotype is a medical diagnostic test used in genetics to evaluate the chromosomeal makeup of an individual by analyzing their DNA. Unlike traditional karyotyping, which visually examines chromosomes under a microscope, virtual karyotyping utilizes advanced bioinformatics and genomic technologies to provide a comprehensive view of chromosomal abnormalities. This method is particularly useful in identifying genetic disorders, cancer mutations, and for prenatal screening.
Overview[edit]
Virtual karyotyping is performed using techniques such as Comparative Genomic Hybridization (CGH) and Single Nucleotide Polymorphism (SNP) arrays. These technologies compare the patient's DNA to a reference genome, identifying gains, losses, or rearrangements of chromosomal material. The process involves extracting DNA from a patient's sample, labeling it with fluorescent dyes, and then hybridizing it on a microarray chip that contains thousands of DNA probes. The intensity of the fluorescence is measured and analyzed to detect any chromosomal anomalies.
Applications[edit]
Virtual karyotyping has a wide range of applications in both clinical and research settings. In oncology, it is used to identify genetic mutations that may influence the behavior of cancers and guide treatment decisions. In prenatal diagnostics, it offers a non-invasive method to detect chromosomal abnormalities such as Down syndrome. Additionally, it is used in the study of genetic disorders to identify novel mutations and understand their impact on disease.
Advantages[edit]
The main advantages of virtual karyotyping over traditional methods include its higher resolution, the ability to detect submicroscopic abnormalities, and its applicability to a wide range of sample types, including non-dividing cells. It also allows for the analysis of the entire genome in a single assay, making it a powerful tool for comprehensive chromosomal analysis.
Limitations[edit]
Despite its benefits, virtual karyotyping has limitations. It cannot detect balanced chromosomal rearrangements, such as translocations and inversions, which do not result in a gain or loss of genetic material. Additionally, the interpretation of results can be complex and requires expertise in genetics and bioinformatics.
Conclusion[edit]
Virtual karyotyping represents a significant advancement in the field of genetics, offering a detailed and comprehensive method for analyzing chromosomal abnormalities. Its applications in diagnosing genetic disorders, guiding cancer treatment, and prenatal screening highlight its importance in modern medicine. As technology advances, it is expected that virtual karyotyping will become even more accessible and widely used in clinical practice.
 | |
|---|---|
 |
 |
-
Human male karyotype
-
Virtual karyotype karyogram
-
Chronic Lymphocytic Leukemia karyotype
-
Gene duplication
-
HER2/neu gene amplification
-
Copy neutral loss of heterozygosity
-
Colorectal cancer karyotype
-
Human karyotype with bands and sub-bands
