Privacy-preserving and robust watermarking on sequential genome data using belief propagation and local differential privacy

Oksuz, Abdullah Caglar; Ayday, Erman; Güdükbay, Uğur

doi:10.1093/bioinformatics/btab128

Cited by 2 publications

(2 citation statements)

References 54 publications

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“…Similarly, watermarking could protect the copyright and ensure the security of private genetic information to some extent. Meanwhile, there are several considerations for data hiding in genetic data; among them, imperceptibility and robustness against modifications are two crucial factors to consider [ 33 ]. Fingerprinting is another approach that may be involved for the purpose of tracing the recipients.…”

Section: Software-based Solutionsmentioning

confidence: 99%

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Genomic privacy preservation in genome-wide association studies: taxonomy, limitations, challenges, and vision

Aherrahrou,

Tairi,

Aherrahrou

2024

Briefings in Bioinformatics

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Genome-wide association studies (GWAS) serve as a crucial tool for identifying genetic factors associated with specific traits. However, ethical constraints prevent the direct exchange of genetic information, prompting the need for privacy preservation solutions. To address these issues, earlier works are based on cryptographic mechanisms such as homomorphic encryption, secure multi-party computing, and differential privacy. Very recently, federated learning has emerged as a promising solution for enabling secure and collaborative GWAS computations. This work provides an extensive overview of existing methods for GWAS privacy preserving, with the main focus on collaborative and distributed approaches. This survey provides a comprehensive analysis of the challenges faced by existing methods, their limitations, and insights into designing efficient solutions.

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Section: Software-based Solutionsmentioning

confidence: 99%

“…Öksüz et al . [ 33 ] proposed a watermarking scheme for preserving the privacy of genomic data using belief propagation and local differential privacy.…”

Section: Software-based Solutionsmentioning

confidence: 99%

Genomic privacy preservation in genome-wide association studies: taxonomy, limitations, challenges, and vision

Aherrahrou,

Tairi,

Aherrahrou

2024

Briefings in Bioinformatics

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Robust fingerprinting of genomic databases

Ayday

Yılmaz

et al. 2022

Bioinformatics

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Motivation Database fingerprinting has been widely used to discourage unauthorized redistribution of data by providing means to identify the source of data leakages. However, there is no fingerprinting scheme aiming at achieving liability guarantees when sharing genomic databases. Thus, we are motivated to fill in this gap by devising a vanilla fingerprinting scheme specifically for genomic databases. Moreover, since malicious genomic database recipients may compromise the embedded fingerprint (distort the steganographic marks, i.e. the embedded fingerprint bit-string) by launching effective correlation attacks, which leverage the intrinsic correlations among genomic data (e.g. Mendel’s law and linkage disequilibrium), we also augment the vanilla scheme by developing mitigation techniques to achieve robust fingerprinting of genomic databases against correlation attacks. Results Via experiments using a real-world genomic database, we first show that correlation attacks against fingerprinting schemes for genomic databases are very powerful. In particular, the correlation attacks can distort more than half of the fingerprint bits by causing a small utility loss (e.g. database accuracy and consistency of SNP–phenotype associations measured via P-values). Next, we experimentally show that the correlation attacks can be effectively mitigated by our proposed mitigation techniques. We validate that the attacker can hardly compromise a large portion of the fingerprint bits even if it pays a higher cost in terms of degradation of the database utility. For example, with around 24% loss in accuracy and 20% loss in the consistency of SNP–phenotype associations, the attacker can only distort about 30% fingerprint bits, which is insufficient for it to avoid being accused. We also show that the proposed mitigation techniques also preserve the utility of the shared genomic databases, e.g. the mitigation techniques only lead to around 3% loss in accuracy. Availability and implementation https://github.com/xiutianxi/robust-genomic-fp-github.

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Privacy-preserving and robust watermarking on sequential genome data using belief propagation and local differential privacy

Cited by 2 publications

References 54 publications

Genomic privacy preservation in genome-wide association studies: taxonomy, limitations, challenges, and vision

Genomic privacy preservation in genome-wide association studies: taxonomy, limitations, challenges, and vision

Robust fingerprinting of genomic databases

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