Antlers are extensions of an animal's skull found in members of the Cervidae (deer) family. Antlers are a single structure composed of bone, cartilage, fibrous tissue, skin, nerves, and blood vessels. They are generally found only on males, with the exception of reindeer/caribou.[1] Antlers are shed and regrown each year and function primarily as objects of sexual attraction and as weapons.[2]
Etymology
editAntler comes from the Old French antoillier (see present French : "Andouiller", from ant-, meaning before, oeil, meaning eye and -ier, a suffix indicating an action or state of being)[3][4] possibly from some form of an unattested Latin word *anteocularis, "before the eye"[5] (and applied to the word for "branch"[6] or "horn"[4]).
Structure and development
editAntlers are unique to cervids. The ancestors of deer had tusks (long upper canine teeth). In most species, antlers appear to replace tusks. However, one modern species (the water deer) has tusks and no antlers and the muntjacs have small antlers and tusks. The musk deer, which are not true cervids, also bear tusks in place of antlers.[7]
In contrast to antlers, horns—found on pronghorns and bovids, such as sheep, goats, bison and cattle—are two-part structures that usually do not shed. A horn's interior of bone is covered by an exterior sheath made of keratin[8] (the same material as human fingernails and toenails).
Antlers are usually found only on males. Only reindeer (known as caribou in North America) have antlers on the females, and these are normally smaller than those of the males. Nevertheless, fertile does from other species of deer have the capacity to produce antlers on occasion, usually due to increased testosterone levels.[9] The "horns" of a pronghorn (which is not a cervid but a antilocaprid) meet some of the criteria of antlers, but are not considered true antlers because they contain keratin.[10]
Each antler grows from an attachment point on the skull called a pedicle. While an antler is growing, it is covered with highly vascular skin called velvet, which supplies oxygen and nutrients to the growing bone.[7] Antlers are considered one of the most exaggerated cases of male secondary sexual traits in the animal kingdom,[11] and grow faster than any other mammal bone.[12] Growth occurs at the tip, and is initially cartilage, which is later replaced by bone tissue. Once the antler has achieved its full size, the velvet is lost and the antler's bone dies. This dead bone structure is the mature antler. In most cases, the bone at the base is destroyed by osteoclasts and the antlers fall off at some point.[7] As a result of their fast growth rate, antlers are considered a handicap since there is an immense nutritional demand on deer to re-grow antlers annually, and thus can be honest signals of metabolic efficiency and food gathering capability.[13]
In most Arctic and temperate-zone species, antler growth and shedding is annual, and is controlled by the length of daylight.[14] Although the antlers are regrown each year, their size varies with the age of the animal in many species, increasing annually over several years before reaching maximum size. In tropical species, antlers may be shed at any time of year, and in some species such as the sambar, antlers are shed at different times in the year depending on multiple factors. Some equatorial deer never shed their antlers.[citation needed]
A 2019 study published in Science identified eight genes active in antler formation that are normally associated with bone cancer, particularly osteosarcoma. Additional tumor-suppressing and tumor-growth-inhibiting genes were determined to be responsible for regulating antler growth. This was taken to indicate that antler formation is more similar to a highly controlled form of cancer growth than to normal bone development.[15]
Antlers function as both weapons in male-male competition and as displays of sexual ornaments for females.[12][16] Because mature antlers are no longer living during combat, antler fractures are incapable of being repaired following competition. A study in 2019 hypothesized that the periodic casting and regrowth of antlers might have evolved as a way to ensure the availability of complete antler sets to display each year.[17] Antler regeneration in male deer ensures that every mating season begins on a clean slate, as an increase in branching size and complexity happens each regeneration cycle in an individual.[14]
Mechanical properties
editBones typically serve a structural purpose, with load bearing abilities that are greater than any other part of an animals body. Bones typically differ in shape and properties to better fit their overall function. [18] Antlers are not structural and typically have different properties when compared to structural bones like femurs.
While antlers are classified as bone, they differ in some ways from human bones and bovine bones. Bone is characterized as being made up of primarily collagen and a mineral phase.[19] In antlers, the mineral content is considerably lower than other examples of bone tissue, while having a high volume of collagen.[20] This leads antlers to having lower yield strength and stiffness, but higher fracture toughness when compared to human cortical bone. Mineral content differs among species and also depends on the food availability. [18] In recent studies, increase in mineral content has been linked to the increase in stiffness with a decrease in fracture toughness. [21]
Further, bones are highly anisotropic due to their hierarchical structure. Thus, mechanical properties are highly dependent on testing conditions and directions. [21] Due to their cylindrical shape, antlers can be tested using bending along three different orientations. Bend testing in these orientations have resulted in different mechanical properties. In samples from antler bone taken in the transverse direction, an elastic modulus of 8.92-10.02 GPa was reported. For the longitudinal and radial orientations, the elastic modulus was 7.19-8.23 and 4.01-4.27 GPa respectively. [21] The transverse direction was overall found to be the stronger orientation with higher mechanical properties. The ultimate tensile strength of 262.96-274.38 MPa in the transverse direction was statistically significant when compared to the longitudinal and radial directions' values of 46.91-48.55 and 41.75-43.67 MPa. [21]
Tensile testing of antler bones has also been conducted to compare to bovine femur results. The antler samples were tested in dry and wet conditions as done in other studies. The wetness of a sample resulted in a difference in mean maximum strain: 1.46% and 2.2%, dry and wet respectively. Further, the ultimate tensile strength of wet, dry and bovine difference showed differences as well: 188 MPa, 108 MPa, and 99.2 MPa for dry, wet and bovine samples respectively. Similarly, the elastic modulus for dry samples was 17.1 GPa, 7.5 GPa for wet samples, and 17.7 GPa for bovine femur. [22] This difference in elastic modulus is due to the difference in function of a bovine femur versus an antler. Bovine femurs must withstand greater stresses, holding up the body of the animal, whereas an antler is used for sexual selection and competition.
Function
editSexual selection
editThe principal means of evolution of antlers is sexual selection, which operates via two mechanisms: male-to-male competition (behaviorally, physiologically) and female mate choice.[11] Male-male competition can take place in two forms. First, they can compete behaviorally where males use their antlers as weapons to compete for access to mates; second, they can compete physiologically where males present their antlers to display their strength and fertility competitiveness to compete for access to mates.[11] Males with the largest antlers are more likely to obtain mates and achieve the highest fertilization success due to their competitiveness, dominance and high phenotypic quality.[11] Whether this is a result of male-male fighting or display, or of female choosiness differs depending on the species as the shape, size, and function of antlers vary between species.[23]
Heritability and reproductive advantage
editThere is evidence to support that antler size influences mate selection in the red deer, and has a heritable component. Despite this, a 30-year study showed no shift in the median size of antlers in a population of red deer.[24] The lack of response could be explained by environmental covariance, meaning that lifetime breeding success is determined by an unmeasured trait which is phenotypically correlated with antler size but for which there is no genetic correlation of antler growth.[24] Alternatively, the lack of response could be explained by the relationship between heterozygosity and antler size, which states that males heterozygous at multiple loci, including MHC loci, have larger antlers.[25] The evolutionary response of traits that depend on heterozygosity is slower than traits that are dependent on additive genetic components and thus the evolutionary change is slower than expected.[25] A third possibility is that the costs of having larger antlers (resource use, and mobility detriments, for instance) exert enough selective pressure to offset the benefit of attracting mates; thereby stabilizing antler size in the population.
Protection against predation
editIf antlers functioned only in male–male competition for mates, the best evolutionary strategy would be to shed them immediately after the rutting season, both to free the male from a heavy encumbrance and to give him more time to regrow a larger new pair. Yet antlers are commonly retained through the winter and into the spring,[26] suggesting that they have another use. Wolves in Yellowstone National Park are 3.6 times more likely to attack individual male elk without antlers, or groups of elk in which at least one male is without antlers.[26] Half of all male elk killed by wolves lack antlers, at times in which only one quarter of all males have shed antlers. These findings suggest that antlers have a secondary function in deterring predation.
Female antlers in reindeer
editReindeer (Rangifer tarandus) are the only cervid species that inhabit the Arctic and subarctic regions of the globe, yet their most striking distinction is the presence of pedicles after birth and antlers in both males and females.[27][28] One possible reason that females of this species evolved antlers is to clear away snow so they can eat the vegetation underneath.[7] Another possible reason is for female competition during winter foraging.[23] Espmark (1964) observed that the presence of antlers on females is related to the hierarchy rank and is a result of the harsh winter conditions and the female dominated parental investment.[29] Males shed their antlers prior to winter, while female antlers are retained throughout winter.[30] Also, female antler size plateaus at the onset of puberty, around age three, while males' antler size increases during their lifetime.[31] This likely reflects the differing life history strategies of the two sexes, where females are resource limited in their reproduction and cannot afford costly antlers, while male reproductive success depends on the size of their antlers because they are under directional sexual selection.[31] In other species of deer, the presence of antlers in females indicates some degree of intersex condition, the frequency of which has been seen to vary from 1.5%[32] to 0.02%.[33]
Antenna for hearing
editIn moose, antlers may act as large hearing aids. Equipped with large, highly adjustable external ears, moose have highly sensitive hearing. Moose with antlers have more sensitive hearing than moose without, and a study of trophy antlers with an artificial ear confirmed that the large flattened (palmate) antler behaves like a parabolic reflector.[35]
Diversification
editThe diversification of antlers, body size and tusks has been strongly influenced by changes in habitat and behavior (fighting and mating).[23]
Capreolinae
edit-
A mule deer with relatively large antlers
-
Moose
Cervinae
edit-
Young red deer, with velvet
-
Fallow deer
-
American elk, or wapiti
-
Sambar deer with thick, forked beams for antlers.
Homology and evolution of tines
editAntlers originated once in the cervid lineage.[36] The earliest fossil remains of antlers that have been found are dated to the early Miocene, about 17 million years ago. These early antlers were small and had just two forks.[36] As antlers evolved, they lengthened and gained many branches, or tines, becoming more complex.[36] The homology of tines has been discussed since the 1900s and has provided great insight into the evolutionary history of the Cervidae family.[37][38][39]
Recently, a new method to describe the branching structure of antlers was developed.[40] It is by using antler grooves, which are formed on the surface of antlers by growth, projecting the branching structure on the burr circumference, and making diagrams. Comparing the positional order among species on the diagram, the tine on the same position is homologous. The study revealed that three-pointed structures of Capreolinae and Cervini are homoplasious, and their subclades gained synapomorphous tines.
Exploitation by other species
editEcological role
editDiscarded antlers represent a source of calcium, phosphorus and other minerals and are often gnawed upon by small animals, including squirrels, porcupines, rabbits and mice. This is more common among animals inhabiting regions where the soil is deficient in these minerals. Antlers shed in oak forest inhabited by squirrels are rapidly chewed to pieces by them.[41][42]
Trophy hunting
editAntlered heads are prized as trophies with larger sets being more highly prized. The first organization to keep records of sizes was Rowland Ward Ltd., a London taxidermy firm, in the early 20th century. For a time only total length or spread was recorded. In the middle of the century, the Boone and Crockett Club and the Safari Club International developed complex scoring systems based on various dimensions and the number of tines or points, and they keep extensive records of high-scoring antlers.[43] Deer bred for hunting on farms are selected based on the size of the antlers.[44]
Hunters have developed terms for antler parts: beam, palm, brow, bez or bay, trez or tray, royal, and surroyal. These are the main shaft, flattened center, first tine, second tine, third tine, fourth tine, and fifth or higher tines, respectively.[45] The second branch is also called an advancer.
In Yorkshire in the United Kingdom roe deer hunting is especially popular due to the large antlers produced there. This is due to the high levels of chalk in Yorkshire. The chalk is high in calcium which is ingested by the deer and helps growth in the antlers.[46]
Shed antler hunting
editGathering shed antlers or "sheds" attracts dedicated practitioners who refer to it colloquially as shed hunting, or bone picking. In the United States, the middle of December to the middle of February is considered shed hunting season, when deer, elk, and moose begin to shed. The North American Shed Hunting Club, founded in 1991, is an organization for those who take part in this activity.[41]
In the United States in 2017 sheds fetch around US$10 per pound, with larger specimens in good condition attracting higher prices. The most desirable antlers have been found soon after being shed. The value is reduced if they have been damaged by weathering or being gnawed by small animals. A matched pair from the same animal is a very desirable find but often antlers are shed separately and may be separated by several miles. Some enthusiasts for shed hunting use trained dogs to assist them.[47] Most hunters will follow 'game trails' (trails where deer frequently run) to find these sheds or they will build a shed trap to collect the loose antlers in the late winter/early spring.
In most US states, the possession of or trade in parts of game animals is subject to some degree of regulation, but the trade in antlers is widely permitted.[48] In the national parks of Canada, the removal of shed antlers is an offense punishable by a maximum fine of C$25,000, as the Canadian government considers antlers to belong to the people of Canada and part of the ecosystems in which they are discarded.[49]
-
A shed moose antler in Denali National Park and Preserve, Alaska (2010)
-
Antlers found shortly after being shed by a whitetail deer in eastern Oklahoma
Carving for decorative and tool uses
editAntler has been used through history as a material to make tools, weapons, ornaments, and toys.[50] It was an especially important material in the European Late Paleolithic, used by the Magdalenian culture to make carvings and engraved designs on objects such as the so-called Bâton de commandements and the Bison Licking Insect Bite. In the Viking Age and medieval period, it formed an important raw material in the craft of comb-making. In later periods, antler—used as a cheap substitute for ivory—was a material especially associated with equipment for hunting, such as saddles and horse harness, guns and daggers, powder flasks, as well as buttons and the like. The decorative display of wall-mounted pairs of antlers has been popular since medieval times at least.[citation needed]
The Netsilik, an Inuit group, made bows and arrows using antler, reinforced with strands of animal tendons braided to form a cable-backed bow.[51] Several Indigenous American tribes also used antler to make bows, gluing tendons to the bow instead of tying them as cables. An antler bow, made in the early 19th century, is on display at Brooklyn Museum. Its manufacture is attributed to the Yankton Sioux.[52]
Through history large deer antler from a suitable species (e.g. red deer) were often cut down to its shaft and its lowest tine and used as a one-pointed pickax.[53][54]
Ceremonial roles
editAntler headdresses were worn by shamans and other spiritual figures in various cultures, and for dances; 21 antler "frontlets" apparently for wearing on the head, and over 10,000 years old, have been excavated at the English Mesolithic site of Starr Carr. Antlers are still worn in traditional dances such as Yaqui deer dances and carried in the Abbots Bromley Horn Dance.[citation needed]
Dietary usage
editIn the velvet antler stage, antlers of elk and deer have been used in Asia as a dietary supplement or alternative medicinal substance for more than 2,000 years.[55] Recently, deer antler extract has become popular among Western athletes and body builders because the extract, with its trace amounts of IGF-1, is believed to help build and repair muscle tissue; however, one double-blind study did not find evidence of intended effects.[56][57]
Elk, deer, and moose antlers have also become popular forms of dog chews that owners purchase for their pet canines.
Shed hunting with dogs
editDogs are sometimes used to find shed antlers. The North American Shed Hunting Dog Association (NASHDA)[58] has resources for people who want to train their dogs to find shed antlers and hold shed dog hunting events.
References
edit- ^ "Arctic Wildlife – Arctic Studies Center". naturalhistory.si.edu. Archived from the original on May 1, 2018. Retrieved May 1, 2018.
- ^ "What are antlers and what is their purpose?". Ace Antlers. January 14, 2019. Retrieved June 21, 2023.
- ^ Brown, Leslie (1993). The New Shorter Oxford English Dictionary, Volume 1. Clarendon Press. ISBN 0-19-861271-0.
- ^ a b Harper, Douglas (2010). "Online Etymology Dictionary". Dictionary.com. Archived from the original on November 8, 2010. Retrieved November 8, 2010.
- ^ "antler". CollinsDictionary.com. Collins English Dictionary – Complete & Unabridged 11th Edition. Retrieved October 27, 2012. Archived from the original on October 28, 2012.
- ^ "Dictionary.com Unabridged". Dictionary.com. 2010. Archived from the original on November 8, 2010. Retrieved November 8, 2010.
- ^ a b c d Hall, Brian K. (2005). "Antlers". Bones and Cartilage: Developmental and Evolutionary Skeletal Biology. Academic Press. pp. 103–114. ISBN 0-12-319060-6. Retrieved November 8, 2010.
- ^ Love, Heather. "What Is The Difference Between Horns And Antlers?". A Moment of Science – Indiana Public Media. Retrieved December 5, 2020.
- ^ Antlered Doe Archived February 29, 2012, at the Wayback Machine
- ^ "Mammals: Pronghorn". San Diego Zoo. Retrieved June 27, 2013.
- ^ a b c d Malo, A. F.; Roldan, E. R. S.; Garde, J.; Soler, A. J.; Gomendio, M. (2005). "Antlers honestly advertise sperm production and quality". Proceedings of the Royal Society B: Biological Sciences. 272 (1559): 149–57. doi:10.1098/rspb.2004.2933. PMC 1634960. PMID 15695205.
- ^ a b Whitaker, John O.; Hamilton, William J. Jr. (1998). Mammals of the Eastern United States. Cornell University Press. p. 517. ISBN 0-8014-3475-0. Retrieved November 8, 2010.
- ^ Ditchkoff, Stephen S.; Lochmiller, Robert L.; Masters, Ronald E.; Hoofer, Steven R.; Bussche, Ronald A. Van Den (2007). "Major-Histocompatibility-Complex-Associated Variation in Secondary Sexual Traits of White-Tailed Deer (Odocoileus Virginianus): Evidence for Good-Genes Advertisement". Evolution. 55 (3): 616–25. doi:10.1111/j.0014-3820.2001.tb00794.x. PMID 11327168. S2CID 10418779.
- ^ a b Rössner, Gertrud E.; Costeur, Loïc; Scheyer, Torsten M. (December 16, 2020). "Antiquity and fundamental processes of the antler cycle in Cervidae (Mammalia)". The Science of Nature. 108 (1): 3. doi:10.1007/s00114-020-01713-x. ISSN 1432-1904. PMC 7744388. PMID 33326046.
- ^ Pennisi, Elizabeth (June 20, 2019). "Cancer genes help deer antlers grow". Science. American Association for the Advancement of Science. Retrieved November 4, 2023.
- ^ Morina, Daniel L.; Demarais, Steve; Strickland, Bronson K.; Larson, Jamie E. (April 1, 2018). "While males fight, females choose: male phenotypic quality informs female mate choice in mammals". Animal Behaviour. 138: 69–74. doi:10.1016/j.anbehav.2018.02.004. ISSN 0003-3472. S2CID 3942922.
- ^ Landete-Castillejos, T.; Kierdorf, H.; Gomez, S.; Luna, S.; García, A. J.; Cappelli, J.; Pérez-Serrano, M.; Pérez-Barbería, J.; Gallego, L.; Kierdorf, U. (2019). "Antlers - Evolution, development, structure, composition, and biomechanics of an outstanding type of bone". Bone. 128: 115046. doi:10.1016/j.bone.2019.115046. hdl:10578/30778. ISSN 1873-2763. PMID 31446115. S2CID 201751091.
- ^ a b Landete-Castillejos, T.; Currey, J. D.; Estevez, J. A.; Gaspar-López, E.; Garcia, A.; Gallego, L. (November 2007). "Influence of physiological effort of growth and chemical composition on antler bone mechanical properties". Bone. 41 (5): 794–803. doi:10.1016/j.bone.2007.07.013. PMID 17822969 – via Elsevier Science Direct.
- ^ Chen, Poyu; Stokes, A. G.; McKittrick, Joanna M. (February 2009). "Comparison of the structure and mechanical properties of bovine femur bone and antler of the North American elk (Cervus elaphus canadensis)". Acta Biomaterialia. 5 (2): 693–706. doi:10.1016/j.actbio.2008.09.011. PMID 18951859 – via Elsevier Science Direct.
- ^ Picavet, P. P.; Balligand, M. (September 12, 2016). "Organic and mechanical properties of Cervidae antlers: a review". Veterinary Research Communications. 40 (3–4): 141–147. doi:10.1007/s11259-016-9663-8. PMID 27618827 – via Springer Link.
- ^ a b c d Fang, Zhongqi; Chen, Bin; Lin, Shiyun; Ye, Wei; Xiao, Hang; Chen, Xi (December 2018). "Investigation of inner mechanism of anisotropic mechanical property of antler bone". Journal of the Mechanical Behavior of Biomedical Materials. 88: 1–10. doi:10.1016/j.jmbbm.2018.07.043. PMID 30114597 – via Elsevier Science Direct.
- ^ Rajaram, A.; Ramanathan, N. (December 1982). "Tensile properties of antler bone". Calcified Tissue International. 34 (3): 301–305. doi:10.1007/BF02411255. PMID 6809293 – via Springer Link.
- ^ a b c Gilbert, Clément; Ropiquet, Anne; Hassanin, Alexandre (2006). "Mitochondrial and nuclear phylogenies of Cervidae (Mammalia, Ruminantia): Systematics, morphology, and biogeography". Molecular Phylogenetics and Evolution. 40 (1): 101–17. Bibcode:2006MolPE..40..101G. doi:10.1016/j.ympev.2006.02.017. PMID 16584894.
- ^ a b Kruuk, Loeske E. B.; Slate, Jon; Pemberton, Josephine M.; Brotherstone, Sue; Guinness, Fiona; Clutton-Brock, Tim (2002). "Antler Size in Red Deer: Heritability and Selection but No Evolution". Evolution. 56 (8): 1683–95. doi:10.1111/j.0014-3820.2002.tb01480.x. PMID 12353761. S2CID 33699313. Archived (PDF) from the original on September 16, 2016.
- ^ a b Perez-Gonzalez, J.; Carranza, J.; Torres-Porras, J.; Fernandez-Garcia, J. L. (2010). "Low Heterozygosity at Microsatellite Markers in Iberian Red Deer with Small Antlers". Journal of Heredity. 101 (5): 553–61. doi:10.1093/jhered/esq049. PMID 20478822.
- ^ a b Metz, Matthew C.; Emlen, Douglas J.; Stahler, Daniel R.; MacNulty, Daniel R.; Smith, Douglas W. (September 3, 2018). "Predation shapes the evolutionary traits of cervid weapons". Nature Ecology & Evolution. 2 (10): 1619–1625. Bibcode:2018NatEE...2.1619M. doi:10.1038/s41559-018-0657-5. PMID 30177803. S2CID 52147419.
- ^ Nasoori, Alireza (2020). "Formation, structure, and function of extra-skeletal bones in mammals". Biological Reviews. 95 (4): 986–1019. doi:10.1111/brv.12597. ISSN 1464-7931. PMID 32338826. S2CID 216556342.
- ^ Lin, Zeshan; Chen, Lei; Chen, Xianqing; Zhong, Yingbin; Yang, Yue; Xia, Wenhao; Liu, Chang; Zhu, Wenbo; Wang, Han; Yan, Biyao; Yang, Yifeng; Liu, Xing; Sternang Kvie, Kjersti; Røed, Knut Håkon; Wang, Kun (June 21, 2019). "Biological adaptations in the Arctic cervid, the reindeer ( Rangifer tarandus )". Science. 364 (6446): eaav6312. Bibcode:2019Sci...364.6312L. doi:10.1126/science.aav6312. ISSN 0036-8075. PMID 31221829. S2CID 195191761.
- ^ Espmark, Yngve (October 1, 1964). "Studies in dominance-subordination relationship in a group of semi-domestic reindeer (Rangifer tarandus L.)". Animal Behaviour. 12 (4): 420–426. doi:10.1016/0003-3472(64)90061-2. ISSN 0003-3472.
- ^ Schaefer and Mahoney (December 2001). "Antlers on Female Caribou: Biogeography of the Bones of Contention". Ecology. 82 (12): 3556–3560. doi:10.2307/2680172. JSTOR 2680172.
- ^ a b Melnycky; et al. (December 2013). "Scaling of antler size in reindeer (Rangifer tarandus): sexual dimorphism and variability in resource allocation". Journal of Mammalogy. 94 (6): 1371–1379. doi:10.1644/12-mamm-a-282.1. S2CID 86047535.
- ^ Wishart, William (1985). "Frequency of Antlered White-Tailed Does in Camp Wainwright, Alberta". Journal of Wildlife Management. 49 (2): 386–388. doi:10.2307/3801538. JSTOR 3801538.
- ^ Donaldson, John; Doutt, J. Kenneth (1965). "Antlers in Female White-Tailed Deer: A 4-Year Study". Journal of Wildlife Management. 29 (4): 699–705. doi:10.2307/3798545. JSTOR 3798545.
- ^ "Moose as a domestic animal". The Kostroma moose farm. Archived from the original on December 10, 2016.
- ^ Bubenik, George A.; Bubenik, Peter G. (2008). "Palmated antlers of moose may serve as a parabolic reflector of sounds". European Journal of Wildlife Research. 54 (3): 533–5. doi:10.1007/s10344-007-0165-4. S2CID 44737101.
- James Randerson (March 20, 2008). "Moose's sharp hearing is attributed to antlers". The Guardian.
- ^ a b c Heckeberg, Nicola S. (February 18, 2020). "The systematics of the Cervidae: a total evidence approach". PeerJ. 8: e8114. doi:10.7717/peerj.8114. ISSN 2167-8359. PMC 7034380. PMID 32110477.
- ^ Garrod, A. Notes on the visceral anatomy and osteology of the ruminants, with a suggestion regarding a method of expressing the relations of species by means of formulae. Proceedings of the Zoological Society of London, 2–18 (1877).
- ^ Brooke, V. On the classification of the Cervidæ, with a synopsis of the existing Species. Journal of Zoology 46, 883–928 (1878).
- ^ Pocock, R. The Homologies between the Branches of the Antlers of the Cervidae based on the Theory of Dichotomous Growth. Journal of Zoology 103, 377–406 (1933).
- ^ Samejima, Y., Matsuoka, H. A new viewpoint on antlers reveals the evolutionary history of deer (Cervidae, Mammalia). Sci Rep 10, 8910 (2020). https://doi.org/10.1038/s41598-020-64555-7
- ^ a b George A. Feldhamer; William J. McShea (January 26, 2012). Deer: The Animal Answer Guide. JHU Press. pp. 32–. ISBN 978-1-4214-0387-8.
- ^ Dennis Walrod (2010). Antlers: A Guide to Collecting, Scoring, Mounting, and Carving. Stackpole Books. p. 46. ISBN 978-0-8117-0596-7.
- ^ Bauer, Erwin A.; Bauer, Peggy (2000). Antlers: Nature's Majestic Crown. Voyageur Press. pp. 20–1. ISBN 978-1-61060-343-0.
- ^ Laskow, Sarah (August 27, 2014). "Antler Farm". Medium (service). Archived from the original on September 3, 2014. Retrieved August 28, 2014.
- ^ "Wildlifeonline – Questions & Answers – Deer". Archived from the original on January 15, 2012. Retrieved March 1, 2012.
- ^ Fieldsports Britain (August 28, 2009). "Fieldsports Britain: Grouse on the Glorious Twelfth, roebucks and". fieldsportschannel.tv. Archived from the original on December 11, 2021. Retrieved October 30, 2012.
- ^ Dennis Walrod (2010). Antlers: A Guide to Collecting, Scoring, Mounting, and Carving. Stackpole Books. pp. 44–52. ISBN 978-0-8117-0596-7.
- ^ Dennis Walrod (2010). Antlers: A Guide to Collecting, Scoring, Mounting, and Carving. Stackpole Books. pp. 46–47. ISBN 978-0-8117-0596-7.
- ^ Susan Quinlan (November 18, 2011). "Parks Canada reminds visitors you can look, but don't touch". Prairie Post West. p. 3. Archived from the original on February 6, 2015. Retrieved December 5, 2011.
- ^ Bauer, Erwin A.; Bauer, Peggy (2000). Antlers: Nature's Majestic Crown. Voyageur Press. p. 7. ISBN 978-1-61060-343-0.
- ^ Balikci, Asen (1989). The Netsilik Inuit. Waveland Press. pp. 38–39.
- ^ "Bow, Bow Case, Arrows and Quiver". Brooklyn Museum.
- ^ "Deer-antler pick, used in flint mining from Grimes Graves". Archived from the original on March 8, 2012. Retrieved July 6, 2012.[full citation needed]
- ^ "970747.JPG". DK Images. Archived from the original on July 25, 2011. Retrieved December 28, 2022.
- ^ "Velvet Antler – Research Summary". www.vitaminsinamerica.com. Archived from the original on October 18, 2017. Retrieved May 1, 2018.
- ^ DiSalvo (September 18, 2015). How to Squeeze Snake Oil from Deer Antlers and Make Millions. [1] forbes.com
- ^ Sleivert, G; Burke, V; Palmer, C; Walmsley, A; Gerrard, D; Haines, S; Littlejohn, R (2003). "The effects of deer antler velvet extract or powder supplementation on aerobic power, erythropoiesis, and muscular strength and endurance characteristics". International Journal of Sport Nutrition and Exercise Metabolism. 13 (3): 251–65. doi:10.1123/ijsnem.13.3.251. PMID 14669926.
- ^ North American Shed Hunting Dog Association
This article incorporates text from a publication now in the public domain: Chambers, Ephraim, ed. (1728). "antler". Cyclopædia, or an Universal Dictionary of Arts and Sciences. Vol. 1 (1st ed.). James and John Knapton, et al. p. 113.