Accuracy of DNA analysis

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The accuracy of DNA testing depends on the rigor of the methods and processes used. Modern DNA testing techniques are highly accurate and widely accepted in the legal and scientific community. Below are some important points regarding the accuracy of DNA testing.

Accuracy of DNA identification depends on the rigor of themethods andprocessesused

With modern technology, appraisals are highly accurate and trusted by the legal and scientific community.

DNA samples are usually authenticated by analyzing short-strand repeat (STR) sequences, which are very accurate. By following the correct protocols, an accuracy of 99.99% or better is generally guaranteed in parent-child relationships and personal identification.

To check accuracy, look at
Likelihood Ratio
Paternity Positive Probability
Paternity Negative ProbabilityTo check accuracy, look at
Likelihood Ratio
Paternity Positive Probability
Paternity Negative Probability

1. the DNA analysis process

Accurate sample collection and advanced analytical processes are essential for DNA identification. Samples are usually taken from blood, saliva, or hair, and it is important to avoid contamination or adulteration during collection. The collected sample is first extracted for DNA and then the DNA is amplified using the polymerase chain reaction (PCR).This amplification process allows for accurate identification of even very small amounts of DNA.

The most commonly used technique in appraisal is short-strand repeat (STR) analysis; STR analysis clarifies genetic relationships between individuals by comparing specific genetic markers. Another important method used in recent years is single nucleotide polymorphism (SN P) analysis, which refers to areas in the DNA sequence where one base differs from other individuals at a specific position, thus allowing for more detailed genetic information to be analyzed.

Appraisal Process

  1. Sample collection: The accuracy of an appraisal depends on collecting samples in an appropriate manner and avoiding contamination or adulteration.
  2. DNA extraction and amplification: DNA is extracted from the sample and amplified using PCR. This allows for the identification of even very small amounts of DNA samples.
  3. DNA profile comparison: Depending on the purpose of the identification, the DNA profiles of the child and the prospective parents are compared using STRs and SNPs to see if they match.

Combined STR and SNP analysis is an important factor in further improving the reliability and accuracy of DNA analysis and ensuring the accuracy of parent-child relationships and personal identification.

2. factors that enhance accuracy

  • Number of STR markers: Typically, 13 to 40 genetic markers are used to create a DNA profile. The more markers used, the more accurate the identification.
  • SNP markers: SNPs , on the other hand, are used to identify very minute genetic variations found between individuals; differences in a single base can be examined in millions of locations, allowing for deeper genetic analysis. SNPs are useful for phylogenetic analysis and population Genetics , and are also useful for estimating disease risk.
  • Combination of STR and SNP
  • In recent years, combined STR and SNP analysis has further increased accuracy in confirming parent-child relationships and identifying individuals. While STRs are powerful tools, SNPs provide additional information in certain situations, revealing more fine-grained genetic relationships and characteristics.
  • Quality Control: Reliable DNA testing is performed through a rigorous quality control and verification process. This eliminates errors and mistakes as much as possible.
  • Compliance with forensic protocols: certain legal procedures must be followed in order to obtain legally valid appraisal results.

3. Errors and their prevention

Contamination Risk: Strict handling and controls are in place to prevent contamination or adulteration of samples. The maintenance of the system is required.

False Positives/False Negatives: The error rate for forensics is very low, typically less than one part per billion. However, false positive or false negative results can occur if proper processes are not followed or if the sample is contaminated.

Supervisor of the article


Dr. Hiroshi Oka

Director of CAP Laboratory

Graduated from Keio University, Faculty of Medicine

Doctor of Medicine

Medical Doctor