7 citations
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January 1981 in “Springer eBooks” Certain small molecules and polymers can change hair's physical properties and how it feels by affecting the bonds within the hair.
6 citations
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April 2025 in “Plastic and Aesthetic Research” Biomaterial characteristics can influence macrophages to promote healing and improve tissue regeneration.
28 citations
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November 2009 in “Journal of Structural Biology” High flux X-ray beams quickly damage the structure of human hair.
March 2024 in “Organic letters” A new method efficiently modifies alkenes to create useful medicinal compounds.
January 2026 in “PubMed Central” Natural product nanoparticles improve drug absorption but need better stability and production methods.
April 2026 in “Trends in biotechnology” Nanozymes have potential for medical use but face challenges like safety and regulation.
10 citations
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December 2023 in “International Journal of Nanomedicine” Cell membrane-coated nanoparticles could improve gene therapy by enhancing delivery and targeting of nucleic acids.
July 2025 in “Nano Research” Nanotechnology can improve tissue healing by controlling immune responses.
March 2026 in “Bioconjugate Chemistry” Peptide-based PROTACs show promise in targeting hard-to-treat proteins, especially for cancer therapy.
17 citations
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April 2022 in “Bioactive Materials” Continuous microfluidic processes can help scale up microtissue production for industrial and clinical use.
April 2019 in “Journal of Investigative Dermatology” Non-coding RNA boosts retinoic acid production and signaling, aiding regeneration.
47 citations
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January 2017 in “RSC Advances” Keratin peptides can change hair shape gently without harsh chemicals.
2 citations
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January 2015 in “Sen'i Gakkaishi” Washing permed hair after using thioglycolic acid helps reform strong bonds, making hair stronger.
Different crystal forms of drugs can change their effectiveness.
4 citations
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October 2024 in “Tissue Engineering and Regenerative Medicine” 33 citations
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September 2020 in “Current Rheumatology Reports” Targeting adipocyte-to-mesenchymal transition could help treat fibrosis.
January 2005 in “Seibutsu Butsuri/Seibutsu butsuri” Chemical treatments damage hair more than UV exposure, making it thinner and less flexible.
4 citations
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January 2006 in “International Journal of Cosmetic Science” The method shows how hair lipids form specific patterns and their roles in hair structure.
1 citations
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November 2014 in “Elsevier eBooks” Future research should focus on making bioengineered skin that completely restores all skin functions.
15 citations
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May 2009 in “Chemical Physics Letters” A new method accurately measures molecular movement without complex modeling.
52 citations
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February 2005 in “Biopolymers” Chemical hair straightening changes hair proteins and mostly fixes broken bonds.
24 citations
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June 2003 in “Journal of Structural Biology” Sheet formation is key to macrofibril structure differences in wool.
January 2026 in “Frontiers in Drug Discovery” Transforming skin disease treatment requires new strategies, better drug models, and patient-focused research.
35 citations
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February 2024 in “Science Advances” Magnetic fields help create complex 3D soft structures for biomedical use.
April 2026 in “Biomaterials” 
7 citations
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February 2014 in “Talanta” Researchers developed a method to identify and analyze cyclosporin compounds and their structures effectively.
December 2023 in “bioRxiv (Cold Spring Harbor Laboratory)” Actin filaments help stabilize and integrate cell membranes during transfer.
1 citations
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January 2009 in “Journal of S C C J” Changing disulfide bonds in human hair affects its melting behavior and thermal stability.
12 citations
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August 2012 in “ISRN Analytical Chemistry (Print)” Future work on macrolide antibiotic analysis will aim to enhance selectivity, sensitivity, and efficiency using advanced chromatographic methods.
6 citations
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June 2025 in “Nano Biomedicine and Engineering” Smart nano-PROTACs improve cancer treatment by targeting proteins more precisely and reducing side effects.