Date of Publication:
June 02, 2010

Publication:
Science Learning Hub – Pokapū Akoranga Pūtaiao

Overview:
Cross-section of wool fibre showing paracortical and orthocortical cells – the arrangement of the cells creates the crimp in wool.

Read the rest of the article: https://www.sciencelearn.org.nz/images/984-cross-section-of-wool-fibre

Date of Publication:
October, 1997

Publication:
Woolwise: Australian Education Trust

Excerpt:
The crimp of wool, or the frequency of waves in a wool staple, has been a vital part of the selection of Merino rams and ewes from the early days. Dr Ian Purvis, manager of Program 1 has been studying crimp as part of the Fine Wool Project and reflects on its changing importance in modern wool science. This article is based on a report that he presented in the CSIRO Fine Wool Newsletter.

Read the rest of the article: https://www.woolwise.com/history/publications/the-wool-press/october-1997/2-crimp-how-important-is-it-in-modern-wool/

Date of Publication:
June 2009

Publication:
Animal. 2009 Jun;3(6):838-43

Abstract:
Crimp, a distinguishing feature of sheep fibres, significantly affects wool value, processing and final fabric attributes. Several explanations for fibre bending have been proposed. Most concentrate on relative differences in the physicochemical properties of the cortical cells, which comprise the bulk of the fibre. However, the associations between cortical properties and fibre crimp are not consistent and may not reflect the underlying causation of fibre curvature (FC). We have formulated a mechanistic model in which fibre shape is dictated primarily by the degree of asymmetry in cell supply from the follicle bulb, and the point at which keratinisation is completed within the follicle. If this hypothesis is correct, one would anticipate that most variations in fibre crimp would be accounted for by quantitative differences in both the degree of mitotic asymmetry in follicle bulbs and the distance from the bulb to the point at which keratinisation is completed. To test this hypothesis, we took skin biopsies from Merino sheep from sites producing wool differing widely in fibre crimp frequency and FC. Mitotic asymmetry in follicle bulbs was measured using a DNA-labelling technique and the site of final keratinisation was defined by picric acid staining of the fibre. The proportion of para- to ortho-cortical cell area was determined in the cross-sections of fibres within biopsy samples. Mitotic asymmetry in the follicle bulb accounted for 0.64 (P < 0.0001) of the total variance in objectively measured FC, while the point of final keratinisation of the fibre accounted for an additional 0.05 (P < 0.05) of the variance. There was no association between ortho- to para-cortical cell ratio and FC. FC was positively associated with a subjective follicle curvature score (P < 0.01). We conclude that fibre crimp is caused predominantly by asymmetric cell division in follicles that are highly curved. Differential pressures exerted by the subsequent asymmetric cell supply and cell hardening in the lower follicle cause fibre bending. The extent of bending is then modulated by the point at which keratinisation is completed; later hardening means the fibre remains pliable for longer, thereby reducing the pressure differential and reducing fibre bending. This means that even highly asymmetric follicles may produce a straight fibre if keratinisation is sufficiently delayed, as is the case in deficiencies of zinc and copper, or when keratinisation is perturbed by transgenesis. The model presented here can account for the many variations in fibre shape found in mammals.

Read the rest of the article: https://www.ncbi.nlm.nih.gov/pubmed/22444770

Date of Publication:
October 2004

Publication:
Colorado State University Extension

Overview:
A glossary of wool terms.

Read the rest of the article: https://extension.colostate.edu/docs/pubs/livestk/01400.pdf

Date of Publication:
October 11, 1972

Publication:
The Journal of The Textile Institute, 64:9, 509-514

Abstract:
Measurements are reported of the hygral expansion of yarns extracted from permanently set fabrics made from merino and Lincoln wools. For yarns having similar crimp, the hygral expansion of merino-wool yarn is much greater than that of Lincoln-wool yarn. The values in both cases agree with predictions based on single-fibre behaviour. It seems certain that this difference is caused by the presence of a consistent bilateral structure in merino wool, which is absent from Lincoln wool.

Read the rest of the article: https://www.tandfonline.com/doi/abs/10.1080/00405007308630285

Date of Publication:
unknown

Publication:
Spink & Co

Excerpt:
We all know that wool keeps you warm, but what is it exactly about the properties of wool that differentiate it from cotton or any other common natural fiber?

To help explain what makes wool so different from almost every other material on the planet, we’ve assembled a list of seven interesting properties of wool that you may not know.

Read the rest of the article: https://spinkandedgarusa.com/7-properties-of-wool/

Date of Publication:
unknown

Publication:
University of Leeds

Excerpt:
The principal component of hair is a protein molecule called keratin. All protein molecules consist of long chains of small molecular units, the amino acids, of which there are 20 different kinds. Each keratin molecule in hair consists of many hundreds of amino acid units, arranged in an irregular order, although not a random one by analogy, the letters in this sentence are in an irregular order, but the sentence has meaning. The order in keratin determines how the molecules fit together, giving the hair strength and flexibility.

Read the rest of the article: https://www.leeds.ac.uk/heritage/Astbury/alpha_to_beta_transition/index.html

Date of Publication:
May 24, 2019

Publication:
Textile Course: Online Textile Learning Platform

Excerpt:
Wool fiber:
Like all other protein fibers, wool is also derived from the animal hair. Wool is mainly used as a minor blend (up to 10%) with cotton to introduce special properties to the terry fabric. Raw wool contains a wide variety of impurities, which can account for between 30% and 70% of the total mass. The impurities consist of wool grease, secreted from the sebaceous glands in the skin; suint, produced from the sweat gland; dirt and sand. Wool grease consists chiefly of esters, formed from a combination of sterols and aliphatic alcohols with fatty acids. Suints consist primarily of the potassium salts of organic acids.

Read the rest of the article: https://textilecourse.blogspot.com/2018/05/wool-fiber-properties-wool-quality.html