1 citations
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February 2016 in “Cell Transplantation” Hair follicles have a more inactive cell cycle than other skin cells, which may help develop targeted therapies for skin diseases and cancer.
November 2022 in “bioRxiv (Cold Spring Harbor Laboratory)” Using deep learning to predict gene expression from images could help assess colorectal cancer metastasis.
February 2026 in “British Journal of Dermatology” Tape-strip RNA sequencing can better detect inflammation in hair follicles for alopecia areata.
April 2026 in “Zenodo (CERN European Organization for Nuclear Research)” The study provides exploratory findings on miRNA changes in female hair loss.
January 2026 in “Frontiers in Molecular Biosciences” A new method helps diagnose alopecia areata using specific gene markers and could guide targeted treatments.
A comprehensive human skin cell atlas was created to better understand skin biology and disease.
822 citations
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January 2021 in “Genome biology” scMC effectively separates biological signals from technical noise in single-cell genomics data.
10 citations
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May 2025 in “Cell Biomaterials” New technologies help us understand how the body reacts to medical implants, which can improve implant performance.
April 2026 in “Zenodo (CERN European Organization for Nuclear Research)” The package offers tools for exploring potential miRNA changes in female hair loss.
7 citations
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October 2018 in “BMC genomics” Key genes can rewire networks, changing skin appendage types.
19 citations
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May 2016 in “Biology Direct” A new method, iSiMPRe, effectively identifies key protein regions in cancer genes, highlighting potential drug targets.
A comprehensive human skin cell atlas was created to better understand skin biology and disease.
10 citations
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September 2016 in “Animal genetics” Researchers identified key genes and proteins linked to wool growth in sheep.
November 2025 in “Figshare” SQSTM1 is linked to increased risk of alopecia areata.
Pangenome analysis reveals key genes for pig adaptation and traits, aiding genetic improvement.
October 2022 in “British Journal of Dermatology” January 2024 in “Updates in clinical dermatology” 
1 citations
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August 2023 in “Genome research” The spiny mouse regenerates ear tissue asymmetrically, with gene expression differences possibly explaining its unique healing abilities.
2 citations
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November 2024 in “PeerJ” Long non-coding RNAs play a role in hair growth stages of Hetian sheep, affecting wool quality.
July 2021 in “Plastic and reconstructive surgery. Global open” Radiation therapy in breast cancer patients changes gene expression related to DNA damage, fibroblast growth, and hair follicle development, which could help improve treatment for radiation-induced fibrosis.
26 citations
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May 2020 in “JCI Insight” Alopecia areata involves specific immune cells, offering potential treatment targets.
January 2012 in “eScholarship (California Digital Library)” Hair and nails contain stable RNA, useful for personalized medicine and screening.
61 citations
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September 2010 in “Genomics” The study found that immune responses disrupt hair growth cycles, causing hair loss in alopecia areata.
6 citations
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July 2018 in “Scientific Reports” Methamphetamine affects gene expression in rat whisker follicles, with key genes linked to addiction.
November 2023 in “Zenodo (CERN European Organization for Nuclear Research)” The dataset includes detailed genetic information from mouse skin cells before and after injury.
November 2023 in “Zenodo (CERN European Organization for Nuclear Research)” The dataset includes detailed genetic information from mouse skin cells before and after injury.
December 2025 in “BMC Medical Genomics” Hair follicles can be used to study gene expression and understand conditions like COPD.
31 citations
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March 2013 in “Gene” Signaling pathways are crucial for hair growth in goats.
13 citations
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June 2014 in “Molecular therapy” The lentiviral array can monitor and predict gene activity during stem cell differentiation.
January 2026 in “Figshare”