American volleyball player Cynthia Barboza wearing spandex shorts

Spandex, Lycra or elastane is a synthetic fiber known for its exceptional elasticity. It is a polyether-polyurea copolymer that was invented in 1958 by chemist Joseph Shivers at DuPont's Benger Laboratory in Waynesboro, Virginia.[1][2][3][4][5]

The name "spandex" is an anagram of the word "expands".[6] It is the preferred name in North America; in continental Europe it is referred to by variants of "elastane", i.e. élasthanne (France), Elastan (Germany, Sweden), elastano (Spain), elastam (Italy) and elastaan (Netherlands), and is known in the UK, Ireland, Portugal, Spain, Latin America, Australia, New Zealand and Israel primarily as Lycra. Brand names for spandex include Lycra (made by Koch subsidiary Invista, previously part of DuPont), Elaspan (also Invista), Acepora (Taekwang Group), Creora (Hyosung), INVIYA (Indorama Corporation), ROICA and Dorlastan (Asahi Kasei), Linel (Fillattice[7]), and ESPA (Toyobo).


DuPont textiles scientist Joseph C. Shivers was determined to find a fiber to replace rubber in garments. He made a breakthrough in the early 1950s when he used an intermediate substance to modify Dacron polyester.[8] This modification produced a stretchy fiber that could withstand high temperatures. After nearly a decade of research the fiber was perfected in 1959. Originally called Fiber K, DuPont chose the trade name Lycra to distinguish its brand of spandex fiber.[9]


Spandex fibers under an optical microscope (cross-polarized light illumination, magnification 100x)
Spandex fiber

Spandex fibers are produced in four ways: melt extrusion, reaction spinning, solution dry spinning, and solution wet spinning. All of these methods include the initial step of reacting monomers to produce a prepolymer. Once the prepolymer is formed, it is reacted further in various ways and drawn out to make the fibers.

Synthesis of polyurethane, THF is used instead of ethylene glycol in Spandex production

The solution dry spinning method is used to produce over 94.5% of the world's spandex fibers,[10] and the process has five steps:

Cyclist wearing a pair of spandex shorts and a cycling jersey
French Ski team (2010) wearing Spandex.

Role in fashion[]

In the post World War II era, DuPont Textiles Fibers Department, which was formed in 1952, became its most popular division, dominating the synthetic fiber market worldwide.[11] At this time, women began to emerge as a significant group of consumers because of their need for underwear and hosiery.[11] DuPont conducted market research to find out what women wanted from textiles, then began developing fibers to meet their needs, including a better fiber for women's girdles, which were commonly made of rubber at the time. DuPont became interested in developing a synthetic elastic fiber in the 1930s, which was perfected by chemist Joseph Shivers in 1959. Spandex's transformative nature allowed it to be incorporated into other garments besides girdles and undergarments. DuPont launched an extensive publicity campaign for its Lycra brand, taking advertisements and full-page ads in top women's magazines such as Vogue, Glamour, Harper's Bazaar, Mademoiselle, McCalls, Ladies Home Journal, and Good Housekeeping.[11] Fashion's original style icon, Audrey Hepburn helped catapult the brand on and off-screen in the late 1950s; models and actress like Joan Collins and Anne-Margret followed Hepburns aesthetic by posing in Lycra clothing for photo shoots and magazine covers.[12]

By the mid-1970s, girdle sales began to drop with the emergence of the Women's Liberation Movement. Girdles came to be associated with anti-independence and emblematic of an era that was quickly passing away.[11] DuPont was not ready to abandon a market that they were significantly reliant on. In response, DuPont reimagined Lycra as the aerobic fitness movement emerged in the 1970s.[11] This expansion furthered at the 1968 Winter Olympic Games when the French ski team wore Lycra garments to compete.[13] This popularized the brand as essential athletic wear because of its flexible and lightweight material. The fiber proved to be especially popular in mid-thigh-length shorts worn by cyclists.[13] By the 1980s, the fitness trend had reached its height in popularity and fashionistas began wearing shorts on the street.[14] Spandex proved such a popular fiber in the garment industry that by 1987 DuPont had trouble meeting worldwide demand. In the 1990s a variety of other items made with Spandex proved popular, including a successful line of body-shaping foundation garments sold under the trade name Bodyslimmers. As the decade progressed, shirts, pants, dresses, and even shoes were being made with spandex blends, and mass-market retailers like Banana Republic were using it for menswear.[14]

Major spandex fiber uses[]

The elasticity and strength (stretching up to five times its length), of spandex has been incorporated into a wide range of garments, especially in skin-tight garments. A benefit of spandex is its significant strength and elasticity and its ability to return to the original shape after stretching and faster drying than ordinary fabrics. For clothing, spandex is usually mixed with cotton or polyester, and accounts for a small percentage of the final fabric, which therefore retains most of the look and feel of the other fibers. In North America it is rare in men's clothing, but prevalent in women's. An estimated 80% of clothing sold in the United States contained spandex in 2010.[15]

A human pyramid of dancers wearing spandex zentai suits

The types of garments which incorporate spandex include:

Harmful environmental impact[]

Today most clothes containing spandex end up as non-recyclable waste once they have been worn out, as fabric blends containing spandex are difficult to recycle.[16] This contributes to the pollution of the environment.

When clothes are washed, hundreds of thousands of microfibres are released into the wastewater, ending up in the oceans, and if clothes contain plastic then they will cause microplastic pollution.[17]

See also[]


  1. ^ U.S. Patent 3,023,192, "Segmented copolyetherester elastomers" filed May 29, 1958, issued Feb 27, 1962
  2. ^ Flynn, Elizabeth and Patel, Sarah (2016) The Really Useful Primary Design and Technology Book: Subject Knowledge and Lesson Ideas New York: Routledge. p.86. ISBN 9781317402565
  3. ^ Teegarden, David M. (2004) Polymer Chemistry: Introduction to an Indispensable Science NSTA Press. p.149. ISBN 9780873552219
  4. ^ Editors of Time-Life (2016) TIME-LIFE American Inventions: Big Ideas That Changed Modern Life Time-Life Books. ISBN 9781683306313
  5. ^ Moskowitz, Sanford L. (2016) Advanced Materials Innovation: Managing Global Technology in the 21st Century Wiley. ISBN 9780470508923
  6. ^ Kadolph, Sara J. (2010) Textiles. Pearson. ISBN 9780135007594
  7. ^
  8. ^ "Wayback Machine" (PDF). 2013-12-03. Retrieved 2018-11-26.
  9. ^ "WHAT'S THAT STUFF? - SPANDEX". Retrieved 2018-12-06.
  10. ^ a b c d "How spandex is made" from How Products Are Made
  11. ^ a b c d e O'Connor, Kaori (2008), "CHAPTER ELEVEN. The Body and the Brand: How Lycra Shaped America", Producing Fashion, University of Pennsylvania Press, doi:10.9783/9780812206050.207, ISBN 9780812206050
  12. ^ Clark, Meaghan. "What Came First: The Yoga Pant Or The Skinny Jean?". Retrieved 2018-12-11.
  13. ^ a b The Sydney Morning Herald, Lycra: a brief history, retrieved 2018-12-11
  14. ^ a b "Spandex - Fashion, Costume, and Culture: Clothing, Headwear, Body Decorations, and Footwear through the Ages". Retrieved 2018-12-11.
  15. ^ Marisa Penaloza (2011-12-11). "Spandex Stretches To Meet U.S. Waistlines". NPR. Retrieved 2012-01-17.
  16. ^ Yunjie Yin; Donggang Yao; Chaoxia Wang; Youjiang Wang (2014). "Removal of spandex from nylon/spandex blended fabrics by selective polymer degradation". Textile Research Journal. Textile Research Journal, Volume 84, Issue 1, January 2014. 84: 16–27. doi:10.1177/0040517513487790.
  17. ^ Napper, Imogen E.; Thompson, Richard C. (15 November 2016). "Release of synthetic microplastic plastic fibres from domestic washing machines: Effects of fabric type and washing conditions". Marine Pollution Bulletin. 112 (1–2): 39–45. doi:10.1016/j.marpolbul.2016.09.025. hdl:10026.1/8163.

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