Felted

Felted is a term variously applied to hairy or otherwise filamentous material that is densely packed or tangled, forming felt or felt-like structures. Apart from fibres in felted fabric manufactured by humans, the term "felted" may apply to the condition of hair such as in the pathological condition known as felted hair, or it may apply to the tangled threads of the tissue of certain fungi, to matted fibres in animal connective tissue, or to the felted outer coat of certain plants. To say that something is felted need not imply that any processes of matting, condensing and pressing fibres have been applied as in the processes for artificial production of felt fabric. Depending on the nature of the felted material, it might rely purely on the scaly or barbed texture of the matted fibres to prevent unraveling, but commonly it will include clayey or sticky materials for its structural integrity, or for increased density.

Zoological use of the term

Examples of the description of animal tissues as "felted" include classes of connective tissue such as the dermis which the classic Gray's Anatomy describes as: "felted connective tissue, with a varying amount of elastic fibers and numerous bloodvessels, lymphatics, and nerves." Also, in describing the external coat or tunica adventitia of an artery, Gray says: "...consists mainly of fine and closely felted bundles of white connective tissue..."[1] In such classes of connective tissue the felted structure is very important; it is versatile in resisting tearing by distributing localised stresses and it imparts strength together with shock absorption and elasticity in two or three dimensions at once, irrespective of the shape of the tissue.[2] In other words, suitable types of felting can yield controllable isotropy or anisotropy in the behaviour of a structure.[3]

Drawing of cuticular surfaces of hairs of dog, cat, and human (left to right). The surface texture affects the felting behaviour of the various hair types
Down (woolly) hair, awn hair and guard hair of domestic cat (left to right).
Felted plant fibre from nest of a Southern African carder bee

Other examples of felted material in animal structures include fibrous structures coating the integument of some insects. Usually such a felted coating is not living tissue, but consists of waxy fibres and is not particularly strong, but serves as protection from either excessive desiccation or moisture. It is particularly common in some families of the Hemiptera. In some species it occurs only as an outer coat of the immature insect, but in others, such as many of the Coccoidea, including the "Australian bug", Icerya purchasi and cochineal, Dactylopius species, it is secreted throughout the life of the insect and serves largely to protect the eggs rather than the insect.[4] In other species, such as many of the "woolly aphids", the Eriosomatinae, the most spectacular fluff is borne on the adult insect itself.[5]

The distinction between felted and other fibrous materials is not always sharp. For example, although truly felted hair on healthy mammals is unusual, many animals, especially in seasonally cold or wet climates or environments, often have a so-called undercoat of down hair plus awn hair that usually lies hidden beneath the outer coat of guard hairs,[6] and may form a mat of lightly felted wool. Such down hairs as a rule are crimped into a finely woolly texture and contain waxy, water-repellent lanolin; in a mass they serve to retain insulating air and exclude water. In many species that live in seasonally frigid zones the winter down hair is shed in clumps during springtime. This is exploited in species such as the muskox; herders collect the wool for commercial purposes without any need for shearing.[7]

Felting activities of animals

Many species of animals actively employ felting behaviour in preparing shelters for themselves or their young. It is not always possible to tell when such felting is purely incidental, but many species show behaviour patterns clearly adapted to the production of felted material suited to shelter and protection. The linings of nests of small rodents and small carnivores are common examples; some mice for example, such as ground-dwelling Mus species in parts of Africa build spherical nests of assorted fibres in burrows or under large flat objects. Some, such as various species of rabbit, in particular Sylvilagus species, use their own fur as a major component of their nesting material.[8] Small predatory mammals such the least weasel largely collect fur from their prey, or occupy prey nests ready lined; such fur commonly forms a felted nest lining.[9]

Common eider nest, with the eggs deep in the loosely piled down.

Birds vary enormously in the nests they make and the materials they use. Among those that use fibres and fibrous materials such as grass for nesting, many tend to weave the nests, but even nests that initially are purely woven, such as those of weaver birds, later are lined with downy materials that largely become felted, both with each other and with the surrounding nest material. Similarly birds such as sparrows, that build large, twiggy nests, line them with downy material. Many kinds of birds however do little weaving in building their nests, but instead construct their nests mainly of fibrous and downy materials such as fine wool, moss, lichen, spiders' nests, tufts of cotton, arachnoid fluff from plants, or bark scales, supported by twigs or the walls of burrows and the like, depending on the circumstances within which they nest. James Rennie remarked: "A circumstance also never neglected, is to bind the nest firmly into the forks of the bush where it is placed, by twining bands of moss, felted with wool, round all the contiguous branches, both below and at the sides. During the nesting season such birds commonly become such avid seekers of suitable materials that down feathers or tufts of wool may be used as bait for trapping them. Birds that concentrate heavily on felted nests include goldfinches (Carduelis species) and related species. Hummingbirds tend to use a lot of spiderweb together with moss and similar material. Small warbler-like birds of many genera such as Prinia and Cisticola make their nests either heavily lined with, or entirely of felted material.[10][11] Ground nesting birds often use felted material rather than woven; it usually suffices and some of the structures can be deceptively sophisticated. For example, the common eider, famous for the valuable down harvested from its abandoned nests, lays its eggs in very lightly felted bowls of its own down; simple though this seems, the thick, soft layer provides exceptional insulation.

Invertebrates

Phyllaphis fagi, Eriosomatinae, woolly beech aphid on a leaf.
Australian bug female on her fibrous waxy protection for the eggs.
Cochineal females. Note that the white waxy fibre does not cover the insect, but rather the eggs.
Spider trapdoor of silk and clay

Various insects also create felted materials, generally forming part of the shelter for their young. Burying beetles are known for stripping the fur or feathers from the carcasses that they prepare for their young, and using the material to line and reinforce the crypt that they dig.[12] it is however unclear whether this habit is anything more than incidental, and also how relatively important it is in the different species of the genus. As long ago as the 19th century at least, Jean-Henri Fabre demonstrated that the species that he investigated most certainly did not depend on feathered or hairy food items, being quite able to utilise reptiles and amphibians and fishes.[13] However, there is no doubt about the use of felted fibre by various species of bees, in particular, those members of the Megachilidae that are known as carder bees build their nests mainly of plant fibre collected from arachnoid plants, though they also might add fibre from other sources, such as animal wool. The sheer amount of the material that they gather often is startling, bearing in mind that the species of bees are not at all large.[14]

Some invertebrates other than insects construct felted structures. Among those spiders are the most conspicuous. Many or most spider egg cases are partly or largely felted silk as well as woven or wound. The lids of various species of trapdoor spider burrows vary in their construction, but they are largely of earth and similar material reinforced with partly felted silk.

Botanical use of the term

Oldenburgia grandis leaves are felted when emerging from the bud, but lose their covering as they mature.
Cephalocereus senilis, showing felted radial spines
Senecio haworthii has permanently felted leaves.

In botanical terminology, felted typically is defined in terms such as "matted with intertwined hairs".[15] However, plants may be covered in several different ways, and several different terms have been coined to describe them. Not all textbooks use the same terms, or use them in the same way. The term felted is commonly used in describing any part of a plant covered with dense white fur, whether tangled or not. Part of the reason is that plants themselves vary so much that there seldom is much practical value to trying to be too precise; for example there is no clear boundary to separate terms such as felt(ed), arachnoid, indumentum and tomentose, and usages vary.

In botany, as opposed to mycology, "felted" seldom refers to internal tissues, but rather to furriness on the outside of leaves or stems. The function of the covering is always protective, sometimes against grazing or browsing animals, sometimes against wind or windblown sand, sometimes against intense sunshine or ultraviolet, and sometimes against drought and desiccation. Two illustrative examples are: Oldenburgia grandis, and Senecio haworthii. The former is a tree that grows in moderately harsh circumstances, but with a reasonable amount of seasonal rain. Its leaves are large, being broad and typically about 30 cm long. While growing to their full size they are vulnerable, so it is quite plausible that being felted protects them from browsers, ultraviolet, drought, and heat. Once their tissues have hardened and become rich in fibre and tannins, they can afford to lose their felt. In this respect they resemble many other plants whose leaves pass through vulnerable phases as they mature, though not all strategies are based on felt.

Senecio haworthii grows under far more dramatically arid conditions than Oldenburgia; its native habitat also is hotter and with a higher irradiation intensity. The plant is fairly poisonous, so it is not much browsed, though some caterpillars will eat its succulent leaves. Accordingly, its need for protection does not change much at any time of the year, and some leaves will survive for several years, retaining their felting throughout.

In Cephalocereus senilis (old man cactus) radial spines grow into a tangled coating of spectacular white hair that conceal both the green tissue and the formidable sharp central spines beneath. It is only marginally felted, but forms a powerful simultaneous protection against intense radiation, wind, frost, and herbivores of various sizes.[16] The woolly masses of fibres on such cacti have been used as stuffing for pillows and for similar applications.[17]

Mycological use of the term

Amanita muscaria growing through the volva, the remnant felted tissue forming spots on the surface

Most fungal tissue is filamentous; its very nature predisposes it to grow into tangles that lend themselves to felting. Whereas vascular plants seldom have cells that grow into forms that can form massive tangles, fungi hardly can form tissues at all except by tangling and felting their hyphal filaments. Practically every mass of mushroom tissue, including cords and membranes, is formed of anastomosed and felted hyphae. The picturesque spots on the caps of Amanita muscaria consist of felted patches of remnant tissue from the volva.[18]

References

  1. Gray, Henry. Anatomy of the Human Body. 20th ed. Revised by Lewis, Warren H. 1918. May be downloaded from https://archive.org/details/anatomyofhumanbo1918gray
  2. Vogel, Steven. Cats' Paws and Catapults. Chapter 5. Penguin 1999. ISBN 0-14-027733-1
  3. Gordon, J. E. Structures, or Why Things Don't Fall Down. Publisher: Da Capo 2003. ISBN 978-0306812835
  4. Alan Weaving; Mike Picker; Griffiths, Charles Llewellyn (2003). Field Guide to Insects of South Africa. New Holland Publishers, Ltd. ISBN 1-86872-713-0.
  5. Costa, James T. The Other Insect Societies. Chapter 9. Publisher: Belknap Press 2006. ISBN 978-0674021631
  6. Robinson, Roy. Genetics for Cat Breeders. Pergamon 1977. ISBN 0-08-021209-3
  7. Feldhamer, George A. Mammalogy: Adaptation, Diversity, Ecology. Publisher: The Johns Hopkins University. ISBN 978-0801886959
  8. Long, Charles A. The Wild Mammals of Wisconsin (Faunistica). Pensoft Publishers 2008. ISBN 978-9546423139
  9. Jackson, Hartley H.T. et al. Mammals of Wisconsin. Publisher: University of Wisconsin 1961. ISBN 978-0299021504
  10. Rennie, James. Natural history of birds : their architecture habits and faculties. Chapter VIII. New York : Harper 1845 May be downloaded from: https://archive.org/details/naturalhistoryof00renn
  11. Phil Hockey; Peter Ryan; Richard Dean. Roberts Birds of Southern Africa. Publisher: John Voelcker Bird Book Fund. 2005 ISBN 9780620340533
  12. Burton, Maurice; Burton, Robert. International Wildlife Encyclopedia. Publisher: Marshall Cavendish 2002. ISBN 978-0761472698
  13. Fabre, Jean-Henri. Tr. Teixeira de Mattos, Alexander. The glow-worm and other beetles Publisher: New York : Dodd, Mead and Company, 1919
  14. Fabre, Jean-Henri; Translated by Alexander Teixeira de Mattos; The Bramble-bees and others; Pub: Dodd, Mead, New York, 1915. Download from: https://archive.org/details/bramblebeesother00fabr
  15. Jackson, Benjamin, Daydon; A Glossary of Botanic Terms with their Derivation and Accent; Published by Gerald Duckworth & Co. London, 4th ed 1928
  16. Mauseth, James D. Structure–Function Relationships in Highly Modified Shoots of Cactaceae. Annals of Botany 98: 901–926, 2006 doi:10.1093/aob/mcl133, available online at www.aob.oxfordjournals.org
  17. Powell, A. Michael, Weedin, James F. Cacti of the Trans-Pecos and Adjacent Areas. Publisher: Texas Tech University Press 2004. ISBN 978-0896725317
  18. Moore, David. Robson, Geoffrey D. Trinci, Anthony P. J. 21st Century Guidebook to Fungi. Publisher: Cambridge University Press 2011 ISBN 978-0521186957
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