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Optimization of a hybridization-based target enrichment protocol for precision oncology. / Shalik, Igor; Vikhorev, Alexander; Chechushkov, Anton и др.

в: Molecular Biology Reports, Том 53, № 1, 876, 03.06.2026.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Shalik, I, Vikhorev, A, Chechushkov, A, Salnikov, P, Sidorenko, D, Nazarov, V & Gridina, M 2026, 'Optimization of a hybridization-based target enrichment protocol for precision oncology', Molecular Biology Reports, Том. 53, № 1, 876. https://doi.org/10.1007/s11033-026-12049-6

APA

Vancouver

Shalik I, Vikhorev A, Chechushkov A, Salnikov P, Sidorenko D, Nazarov V и др. Optimization of a hybridization-based target enrichment protocol for precision oncology. Molecular Biology Reports. 2026 июнь 3;53(1):876. doi: 10.1007/s11033-026-12049-6

Author

Shalik, Igor ; Vikhorev, Alexander ; Chechushkov, Anton и др. / Optimization of a hybridization-based target enrichment protocol for precision oncology. в: Molecular Biology Reports. 2026 ; Том 53, № 1.

BibTeX

@article{d99943ad030c460c96714e4adf535aad,
title = "Optimization of a hybridization-based target enrichment protocol for precision oncology",
abstract = "Background: Next-generation sequencing has become an essential tool in precision oncology, enabling comprehensive detection of clinically relevant genomic alterations. This study aimed to optimize a hybridization-based enrichment protocol for formalin-fixed paraffin-embedded (FFPE)-derived DNA and to evaluate its performance relative to commercial hybridization- and amplification-based kits. Methods and Results: Hybridization conditions, including temperature, duration, buffer composition, and the number of capture rounds, were systematically varied to maximize enrichment efficiency and coverage uniformity. Libraries were sequenced using Illumina platforms and analyzed for enrichment metrics, duplicate fraction, target depth, and variant detection. Comparative analyses were performed against commercial hybridization-based and amplification-based kits, as well as a whole-exome capture panel. Two rounds of short hybridization provided the highest enrichment efficiency while maintaining complete target coverage. The optimized protocol demonstrated approximately sixfold higher enrichment than the hybridization-based analogue, ensuring adequate coverage despite increased duplicate rates. Scalability testing showed performance comparable to a commercial whole-exome kit, with maintained enrichment efficiency and target depth across large panels. Conclusions: The optimized hybridization-based enrichment protocol provides superior target coverage, high variant recall, and flexibility for scaling from small panels to whole-exome sequencing, supporting its suitability for precision oncology applications in challenging FFPE samples.",
keywords = "FFPE DNA, hybridization capture, hybridization-based enrichment, targeted NGS",
author = "Igor Shalik and Alexander Vikhorev and Anton Chechushkov and Pavel Salnikov and Darya Sidorenko and Vladimir Nazarov and Maria Gridina",
note = "Shalik, I., Vikhorev, A., Chechushkov, A. et al. Optimization of a hybridization-based target enrichment protocol for precision oncology. Mol Biol Rep 53, 876 (2026). https://doi.org/10.1007/s11033-026-12049-6 The work was partially supported by state project FWNR-2025-0017. The study was supported by the grant for the implementation of the strategic academic leadership program “Priority 2030” in Novosibirsk State University.",
year = "2026",
month = jun,
day = "3",
doi = "10.1007/s11033-026-12049-6",
language = "English",
volume = "53",
journal = "Molecular Biology Reports",
issn = "0301-4851",
publisher = "Springer Netherlands",
number = "1",

}

RIS

TY - JOUR

T1 - Optimization of a hybridization-based target enrichment protocol for precision oncology

AU - Shalik, Igor

AU - Vikhorev, Alexander

AU - Chechushkov, Anton

AU - Salnikov, Pavel

AU - Sidorenko, Darya

AU - Nazarov, Vladimir

AU - Gridina, Maria

N1 - Shalik, I., Vikhorev, A., Chechushkov, A. et al. Optimization of a hybridization-based target enrichment protocol for precision oncology. Mol Biol Rep 53, 876 (2026). https://doi.org/10.1007/s11033-026-12049-6 The work was partially supported by state project FWNR-2025-0017. The study was supported by the grant for the implementation of the strategic academic leadership program “Priority 2030” in Novosibirsk State University.

PY - 2026/6/3

Y1 - 2026/6/3

N2 - Background: Next-generation sequencing has become an essential tool in precision oncology, enabling comprehensive detection of clinically relevant genomic alterations. This study aimed to optimize a hybridization-based enrichment protocol for formalin-fixed paraffin-embedded (FFPE)-derived DNA and to evaluate its performance relative to commercial hybridization- and amplification-based kits. Methods and Results: Hybridization conditions, including temperature, duration, buffer composition, and the number of capture rounds, were systematically varied to maximize enrichment efficiency and coverage uniformity. Libraries were sequenced using Illumina platforms and analyzed for enrichment metrics, duplicate fraction, target depth, and variant detection. Comparative analyses were performed against commercial hybridization-based and amplification-based kits, as well as a whole-exome capture panel. Two rounds of short hybridization provided the highest enrichment efficiency while maintaining complete target coverage. The optimized protocol demonstrated approximately sixfold higher enrichment than the hybridization-based analogue, ensuring adequate coverage despite increased duplicate rates. Scalability testing showed performance comparable to a commercial whole-exome kit, with maintained enrichment efficiency and target depth across large panels. Conclusions: The optimized hybridization-based enrichment protocol provides superior target coverage, high variant recall, and flexibility for scaling from small panels to whole-exome sequencing, supporting its suitability for precision oncology applications in challenging FFPE samples.

AB - Background: Next-generation sequencing has become an essential tool in precision oncology, enabling comprehensive detection of clinically relevant genomic alterations. This study aimed to optimize a hybridization-based enrichment protocol for formalin-fixed paraffin-embedded (FFPE)-derived DNA and to evaluate its performance relative to commercial hybridization- and amplification-based kits. Methods and Results: Hybridization conditions, including temperature, duration, buffer composition, and the number of capture rounds, were systematically varied to maximize enrichment efficiency and coverage uniformity. Libraries were sequenced using Illumina platforms and analyzed for enrichment metrics, duplicate fraction, target depth, and variant detection. Comparative analyses were performed against commercial hybridization-based and amplification-based kits, as well as a whole-exome capture panel. Two rounds of short hybridization provided the highest enrichment efficiency while maintaining complete target coverage. The optimized protocol demonstrated approximately sixfold higher enrichment than the hybridization-based analogue, ensuring adequate coverage despite increased duplicate rates. Scalability testing showed performance comparable to a commercial whole-exome kit, with maintained enrichment efficiency and target depth across large panels. Conclusions: The optimized hybridization-based enrichment protocol provides superior target coverage, high variant recall, and flexibility for scaling from small panels to whole-exome sequencing, supporting its suitability for precision oncology applications in challenging FFPE samples.

KW - FFPE DNA

KW - hybridization capture

KW - hybridization-based enrichment

KW - targeted NGS

UR - https://www.scopus.com/pages/publications/105041085814

UR - https://www.mendeley.com/catalogue/95d81407-984b-3dd4-91e4-0f3b6a8bc57f/

U2 - 10.1007/s11033-026-12049-6

DO - 10.1007/s11033-026-12049-6

M3 - Article

VL - 53

JO - Molecular Biology Reports

JF - Molecular Biology Reports

SN - 0301-4851

IS - 1

M1 - 876

ER -

ID: 79920189