96                              Handbook of Properties of Textile and Technical Fibres

         Feughelman M, Haly AR: Structural features of keratin suggested by its mechanical properties,
             Biochim Biophys Acta 32:596e597, 1959.
         Feughelman M, Haly AR: The mechanical properties of wool keratin and its molecular
             configuration, Kolloid Z 168:107e115, 1960a.
         Feughelman M, Haly AR: The mechanical properties of the ortho- and para-like components of
             Lincoln wool fibers, Text Res J 30:897e900, 1960b.
         Feughelman M, Reis PJ: The longitudinal mechanical properties of wool fibers and their rela-
             tionship to the low sulfur keratin fraction, Text Res J 37:334e336, 1967.
         Feughelman M, Robinson MS: The relationship between some mechanical properties of single
             wool fibers and relative humidity, Text Res J 37:441e446, 1967.
         Feughelman M, Robinson MS: Some mechanical properties of wool fibres in the “Hookean”
             region from zero to 100% relative humidity, Text Res J 41:469e474, 1971.
         Freney MR, Lipson M: Effects of concentrated aqueous and certain nonaqueous solutions of
             alkali upon wool, Nature 145:25e26, 1940.
         Frydrych I: Relation of single fibre and bundle strengths of cotton, Text Res J 65:513e521,
             1995.
         Ge F, Cai Z, Zhang H, Zhang R: Transglutaminase treatment for improving wool fabric prop-
             erties, Fibers Polym 10:787e790, 2009. https://doi.org/10.1007/s12221-009-0787-0.
         Ghosh A, Grosvenor AJ, Dyer JM: Improving the properties of chemically damaged wool
             fabrics with carbohydrate polymers, J Appl Polym Sci 130:3015e3111, 2013. https://
             doi.org/10.1002/app.39554.
         Gillespie JM: The structural proteins of hair: isolation, characterization, and regulation of
             biosynthesis. In Goldsmith LA, editor: Biochemistry and physiology of the skin, New York,
             1983, Oxford University Press, pp 475e510.
         Gillespie JM: The proteins of hair and other hard a-keratins. In Goldman RD, Steinert PM,
             editors: Cellular and molecular biology of intermediate filaments, New York, 1990,
             Plenum Press, pp 95e128.
         Gourdie RG, Orwin DFG, Randford S, Ross DA: Wool fibre tenacity and its relationship to
             staple strength, Aust J Agric Res 43:1759e1776, 1992.
         Grosvenor AJ, Marsh J, Thomas A, Vernon JA, Harland DP, Clerens S, Dyer JM: Oxidative
             modification in human hair: the effect of the levels of Cu (II) ions, UV exposure and hair
             pigmentation,  Photochem  Photobiol  92:144e149,  2016.  https://doi.org/10.1111/
             php.12537.
         Gullbrandson B: Fiber damage in the stock-dyeing of wool, Text Res J 28:965e968, 1958.
         Habe T, Tanji N, Inoue S, Okamoto M, Tokunaga S, Tanamachi H: ToF-SIMS characterization
             of the lipid layer on the hair surface. I: the damage caused by chemical treatments and UV
             radiation, Surf Interf Anal 43:410e412, 2011. https://doi.org/10.1002/sia.3407.
         Halfaoui R, Chemani B: The influence of cyclic deformation on the strength and elongation at
             break of carded and combed wool yarns, J Textile Inst 104(11):1156e1163, 2013. https://
             doi.org/10.1080/00405000.2013.779057.
         Haly AR, Snaith JW: Differential thermal analysis of wool e the phase transition endotherm
             under various conditions, Text Res J 37:898e907, 1967.
         Haly AR, Feughelman M, Griffith JC: Supercontraction of wool irradiated with ultra-violet light
             or iodinated, Nature 180:1064, 1957.
         Hansford KA, Kennedy JP: The relationship between the proportions of ortho-, meso- and
             paracortex and the fibre diameter and staple strength of Merino wool, Proc Aust Soc Anim
             Prod 18:484, 1990.