Scale (Lepidopteran anatomy)
The presence of scales on the wings of Lepidoptera, comprising moths and butterflies, characterises this order of insects. The name is derived from Ancient Greek λεπίδος (scale) and πτερόν (wing). The wings of Lepidoptera are minutely scaled, which feature gives the name to this order. Scales also cover the head, parts of the thorax and abdomen as well as parts of the genitalia.
The morphology of scales has been studied by Downey & Allyn (1975) and scales have been classified into three groups, namely:
- Hair-like or piliform.
- Blade-like or lamellar.
- Other variable forms.
As per Scoble (2005):
Morphologically, scales are macrotrichia, and thus homologous with the large hairs (and scales) that cover the wings of Trichoptera (caddisflies).
Though there is great diversity in scale form, they are structured similarly. The body or 'blade' of a typical scale consists of an upper and lower lamina. The surface of the lower lamina is smooth whereas the structure of the upper lamina is structured and intricate. Scales are attached to the substrate by a stalk or 'pedicel'.
The colouration of butterfly wings is created by the scales which are pigmented with melanins that give them blacks and browns, but blues, greens, reds and iridescence are usually created not by pigments but the microstructure of the scales. This structural coloration is the result of coherent scattering of light by the photonic crystal nature of the scales. The scales cling somewhat loosely to the wing and come off easily without harming the butterfly.
Scales play an important part in the natural history of Lepidoptera. Scales enable development of vivid or indistinct patterns which help the organism protect itself by concealment and camouflage, mimicry and warning. Besides providing insulation, dark patterns on wings provided by dark colour scales would allow sunlight to be absorbed and thus probably have a role to play in thermoregulation.Bright and distinctive colour patterns in butterflies which are distasteful to predators help communicate their aposematism (toxicity or inedibility) thus preventing a predator from preying on it. In Batesian mimicry, wing colour patterns help edible Lepidopterans mimic inedible models while in Müllerian mimicry inedible butterflies resemble each other to reduce the numbers of individuals sampled by predators.
Scales possibly evolved initially for providing insulation. Scales on the thorax and other parts of the body probably contribute to maintaining the high body temperatures required during flight. The 'solid' scales of basal moths are however not as efficient as those of their more advanced relatives as the presence of a lumen adds air layers and increases the insulation value.
Young adults of myrmecophilous Lepidoptera escape from ant's nests by virtue of the deciduous waxy scales with which they are covered when born. These scales rub off and stick on the ants as they make their way out of the nest after hatching.
Successive close-ups of the scales of a Peacock wing
Photographic and light microscopic images Zoomed-out view of an Inachis io. Closeup of the scales of the same specimen. High magnification of the coloured scales (probably a different species). Electron microscopic images A patch of wing Scales close up A single scale Microstructure of a scale Magnification Approx. ×50 Approx. ×200 ×1000 ×5000
- Scoble, M.J. (2005). The Lepidoptera: Form, Function, and Diversity. Page 63. Accessed through Google books on 21 Aug 2009 
- Powell, Jerry A. Lepidoptera (pp. 631-664) in Resh, V. H. & R. T. Cardé (Editors) 2003. Encyclopedia of Insects. Academic Press.
- Mason, C. W. (1927). The Journal of Physical Chemistry 31 (3): 321. doi:10.1021/j150273a001. Missing or empty
- Vukusic, P., J.R.Sambles, and H. Ghiradella (2000) Optical Classification of Microstructure in Butterfly Wing-scales. Photonics Science News, 6, 61-66 
- Prum, Ro; Quinn, T; Torres, Rh (Feb 2006). "Anatomically diverse butterfly scales all produce structural colours by coherent scattering" (Free full text). The Journal of experimental biology 209 (Pt 4): 748–65. doi:10.1242/jeb.02051. ISSN 0022-0949. PMID 16449568.