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Making AI accessible for forensic DNA profile analysis.

Abel K J G de Wit1, Claire D Wagenaar1, Nathalie A C Janssen2

  • 1Division of Digital and Biometric Traces, Netherlands Forensic Institute, the Netherlands; Division of Biological Traces, Netherlands Forensic Institute, the Netherlands.

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PubMed
Summary
This summary is machine-generated.

Deep learning model DNANet automates forensic DNA allele calling with high accuracy. Using casework data and a standard U-Net architecture, it matches human performance, making advanced techniques more accessible.

Keywords:
Artificial intelligenceAutomated allele callingConvolutional neural networkDeep learningForensic DNA analysisU-net

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Area of Science:

  • Forensic Science
  • Bioinformatics
  • Computer Vision

Background:

  • Deep learning offers potential for automating allele calling in forensic DNA analysis.
  • Current methods often use custom model architectures and extensive manual annotations, hindering reproducibility.
  • There is a need for accessible and standardized deep learning approaches in forensic genetics.

Purpose of the Study:

  • To investigate the efficacy of training a deep learning model using casework data and a standard U-Net architecture for forensic DNA allele calling.
  • To evaluate the performance of the developed model, DNANet, against human analysts and established ground truths.
  • To promote accessibility by making code, model weights, and data publicly available.

Main Methods:

  • Developed DNANet, a U-Net based deep learning model, for classifying electropherogram scan points as allele or non-allele.
  • Trained the model using allele annotations derived from casework data.
  • Evaluated DNANet on unseen casework data and independent mixture research data, comparing its performance to analyst annotations and actual donor alleles.

Main Results:

  • DNANet achieved high F1 scores: 0.971 on analyst-annotated case data and 0.982 on research data.
  • Performance on actual donor alleles (F1 score 0.962) was comparable to that of human analysts.
  • The model demonstrated that good performance can be achieved with standard data and architectures.

Conclusions:

  • DNANet's performance is on par with human analysts in forensic DNA allele calling, validating the use of standard deep learning architectures and casework data.
  • The study highlights the potential for automating complex forensic tasks with accessible deep learning tools.
  • A call is made for establishing standardized benchmarks to facilitate quantitative comparisons of allele calling systems.