New Structural Features of Human Hair Discovered
Scientists detect previously unobserved features of human hair by combining a submicron X-ray beam with cross-section geometry at the micro-diffraction beamline X13B at the National Synchrotron Light Source at Brookhaven National Laboratory.
Newswise — WASHINGTON, DC, July 29, 2015 -- A new discovery about the structure of human hair is likely to change the way scientists and researchers, as well as the cosmetics industry, view and explore it in the future.
Human hair structure has been studied extensively for more than 70 years, but a complete picture of its local structure has proven elusive.
But now, by combining a submicron X-ray beam with cross-section geometry, a team of researchers in Brazil and New York has detected new structural features of human hair. During the American Crystallographic Association (ACA) 2015 Meeting, which will be held in Philadelphia from July 25-29, Vesna Stanic, a scientist working at the Brazilian Synchrotron Light Source, will present an abstract, “Local and average structure of human hair,” describing their discovery and methods.
If you’ve heard of “keratin,” you may already know that human hair consists primarily of keratin molecules arranged in a hierarchical sort of structure, in which the fundamental building block is known as an “intermediate filament.”
While studying materials used for hair treatments, Stanic wondered what effect these treatments were having on the diffraction pattern of the hair. X-ray diffraction patterns of a given material can reveal the local arrangement of molecular and atomic structure.
Although diffraction patterns have been examined and reported in several publications in the past, they involved bundles of hair fibers or microdiffraction on single hair fibers -- and, most significantly, the X-ray beam was always oriented perpendicular to the hair fiber axis.
So Stanic decided to take a closer look at the diffraction pattern of the hair by measuring it with an X-ray beam aimed parallel -- rather than perpendicular -- to the hair axis. “I wanted to use a submicron X-ray beam, so I asked colleague Kenneth Evans-Lutterodt to perform an experiment on the microdiffraction beamline at Brookhaven National Laboratory,” she added.
Using a submicron X-ray beam and transmission electron microscopy, they were able to spatially resolve the local structure of the three main regions of human hair: medulla, cortex and cuticle.
“We performed a full diffraction map from a 30-micron-thick cross section of hair, with an incident beam parallel to the hair axis and then compared it to the diffraction map with the beam perpendicular to the hair axis,” noted Stanic.
What they found
The researchers found an additional, previously unobserved structural region in the cortex near the cuticle boundary. “We also discovered that within the cuticle a key diffraction feature of the alpha keratin is absent -- indicating the presence of beta keratin instead of the alpha keratin phase,” said Stanic. Until now, it was believed that keratin in the whole hair had only an alpha conformation, she explained.
The work “provides irrefutable experimental evidence of the hair phase variation across the three main regions of hair and is an important step toward gaining a better understanding of hierarchical ordering of the intermediate filaments of keratin,” she said. “It also highlights the importance of using a submicron X-ray beam to unravel the structures of poorly ordered, multiphase systems such as hair.”
The team believes the cosmetics industry will benefit from their findings. “If the goal of the cosmetics industry is to make new and better products for hair, then it’s absolutely critical for them to understand the local structure of hair and the effects their products are having at the molecular level,” Stanic added.
Abstract 4.2.4.02, "Local and average structure of human hair," by V. Stanic, Jefferson Bettini, Fabiano Emmanuel Montoro, Aaron Stein and K. Evans-Lutterodt will be presented on Wednesday, July 29th, at 2:00 PM in Freedom Ballroom at the Sheraton Philadelphia Downtown Hotel.
MORE ABOUT THE MEETING
More than 700 professionals and students from more than 20 countries and from diverse areas across industry and academia are expected to attend the American Crystallographic Association (ACA) 65th annual meeting in Philadelphia, from July 25-29, the largest crystallography conference of the year in the United States.
All scientific sessions, workshops, poster sessions, and events will be held at the Sheraton Philadelphia Downtown Hotel. To obtain more information or free registration for press, please contact Jason Socrates Bardi at: 240-535-4954 or email@example.com
Main meeting website: http://www.amercrystalassn.org/2015-mtg-homepageScientific program: http://www.amercrystalassn.org/2015-scientific-programHotel: http://www.sheratonphiladelphiadowntown.comTwitter: #ACAPhilly
ABOUT THE SCIENCE OF CRYSTALLOGRAPHY
Crystallography is a field that lies at the crossroads of biology, chemistry, physics and materials science. Researchers from areas as far flung as genomics, geology, medicine and manufacturing use it to uncover the exact arrangements of atoms within molecules and bulk materials -- information of keen interest to modern science because it helps to define the real-life chemical and physical properties of materials. The structures uncovered by crystallography are also of profound importance to humanity because they are routinely used to guide the creation of new lifesaving drugs, improve manufacturing processes and make new materials that impact our economy and our world.
The American Crystallographic Association (ACA) was founded in 1949 through a merger of the American Society for X-Ray and Electron Diffraction (ASXRED) and the Crystallographic Society of America (CSA). The objective of the ACA is to promote interactions among scientists who study the structure of matter at atomic (or near atomic) resolution. These interactions will advance experimental and computational aspects of crystallography and diffraction. They will also promote the study of the arrangements of atoms and molecules in matter and the nature of the forces that both control and result from them. See: http://www.amercrystalassn.org