Human hair: subtle change in the thioester groups dynamics observed by combining neutron scattering, X-ray diffraction and thermal analysis

Research output: Contribution to journalJournal articlepeer-review

  • C. R. R. C. Lima
  • R. J. S. Lima
  • L. D. B. Machado
  • M. V. R. Velasco
  • L. Lakic
  • M. S. Nordentoft
  • L. Machuca-Beier
  • S. Rudic
  • M. T. F. Telling
  • V. Garcia Sakai
  • C. L. P. Oliveira
  • Nunes Bordallo, Heloisa

Hair analysis plays an important role in forensic toxicology and biomonitoring tests. However, cosmetic treatments cause changes to the hair. Thus, a better understanding of the hair's structure and the factors that influence its composition is critical. It is known that oxidative treatments modify the hair chemical, structural and mechanical properties. These treatments also cause degradation of the melanin as well as of the structures present in the hair cuticle and cortex. Considering that the literature is unanimous regarding the increase in hydrophilicity and porosity promoted in human hair by bleaching, in this work we investigated how this oxidative damage is triggered. By combining several techniques, inelastic and quasi-elastic neutron scattering, differential scanning calorimetry, thermal gravimetric analysis and X-ray diffraction, we were able to connect the chemical and structural changes to a subtle dynamic modification of the proton mobility in the hair fibers. In addition, alterations in the thermal behavior evidenced a small denaturation of alpha-keratin intermediate filaments and a slight decrease in the amount of confined water in the hair fibers. Moreover, data obtained by neutron spectroscopy indicated that bleaching attacks the thioester groups of the proteins causing larger proton mobility of the hydrogenous components (water, protein and/or lipids).

Original languageEnglish
JournalEuropean Physical Journal. Special Topics
Volume229
Issue number17-18
Pages (from-to)2825-2832
Number of pages8
ISSN1951-6355
DOIs
Publication statusPublished - 10 Nov 2020

    Research areas

  • STRUCTURAL-CHANGES, KERATIN FIBERS, WATER, RAMAN

ID: 252833349