Antlers


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Antler Growth Cycle

 The annual casting and growth of new antlers is an important part of the whitetail's mystique. Antlers grow rapidly from their pedicle (base) while in velvet during the spring and summer, as fast as 3/4 inch/week for yearlings and 1 1/2 inches per week for adults during peak growth (Jacobson and Griffin 1983). Growth rate slows dramatically during late summer while mineralization of the antler is completed. Restriction of blood supply around the autumn equinox causes the velvet's death; when dry enough, velvet is removed in as little as 24 hours by thrashing on vegetation.

 Well after the breeding season, cells called osteoclasts de-mineralize the bone along an abscission line where the pedicle meets the antler.

Pedicle and Abscission Line

Diagram of a growing antler tip illustrating the main anatomical regions.Adapted from Price et al. (2005).

 This weakened attachment combined with the weight of the antler causes it to drop off or be cast. Although described as an abscission "line," the surface of the detached antler base is rough in texture. The resulting surface may be either flush with or extend beyond the burr or coronet.

Abscission Surface

Abscission line at the antler — pedicle interface. A) showing the rough texture due to attenuated spicules of bone, B) showing a line flush with the antler base, C) showing a line that would have extended from the base into the pedicle, and D) showing the likely effect of a brain abscess or bacterial infection (note dried puss at arrow).Photo Credit S. Demarais.

 Brain abscesses, resulting from secondary infection following injury to the frontal bone or pedicle, may result in a jagged abscission line projecting deep into the pedicle and frontal bone.

 Once the antler is cast, the top of the pedicle can be considered an open wound. This area reacts like any wound, bleeding for a short period and developing a scab-like covering called a "wound epithelium" within 2-3 weeks. Antler growth begins shortly after completion of the wound epithelium in white-tailed deer and most members of the deer family; in contrast, moose antlers do not begin growth until two — three months after antler casting.

 Beneath the wound epithelium are cells which will create the antler growth zones.

Stages of Antler Growth

Stages of antler growth.
A) one day after antler shed,
B) 15 days after shed, scab still attached,
C) 30 days after shed, scab is shed (A, B, C same animal),
D) about three months after shed by different animal,
E) about five months after shed antler growth is completed, with one additional month used to complete hardening and drying of velvet (D and E same animal), and
F) hardened antler with shreds of dried velvet on a third animal.Photo Credits A-E, Steve Demarais, F, Dave Hewitt.

 The covering of the growing antler takes on the appearance of shiny velvet because sparse hairs grow straight out and are coated with oily secretions from the hair follicle. Beneath the velvet epidermis and dermis of the growing antler is a thick, fibrous protective membrane, called perichondrium when it covers the cartilagenous growth stage and periosteum when it covers the boney stage of the growing antler. Beneath the velvet and perichondrium lies the mesenchyme growth zone, an area of rapid cell generation and growth. In the chondroprogenitor region these young cells begin to differentiate into chondrocytes and to form the columnar structure characteristic of cartilage and bone. The enlarged and columnar chondrocytes then begin the process of mineralization. Once mineralized, chondroclasts resorb the cartilage, and bone is laid down on the remaining "scaffold" by osteoblasts. For more details on this process see the review by Price et al. 2005.

 There are two types of bone within an antler, spongy bone and compact (cortical) bone. Spongy bone makes up the inner portion and is less dense, softer, and weaker. Spongy bone is highly vascularized during growth, which allows the transport of nutrients and growth regulating hormones. Compact bone forms the outer shell of the antler, and its greater density and stiffness provide strength for fighting. Spongy bone makes up about half the diameter of an average antler (McDonald et al. 2005), although there is considerable variation among animals.

X-Cut Of Base

X-ray of cross sections at the antler base showshows the range of variation in relative amount of spongy (dark center) and compact bone.
A) average composition,
B) minimal spongy bone, and
C) maximal spongy bone.


Antler Conformation

 Antler shape or form, known as conformation, is highly variable and depends on age, genetics, and nutrition. Points or tines are classified as typical (points generally symmetric and arising from the top of the main beam) and abnormal or non-typical (points arising from other than the top of the main beam or asymmetrical with the other side).

Antler Terminology

 Abnormalities include kicker points projecting laterally from a tine or beam, drop tines projecting downward from a main beam, extra main beams, palmation of the main beam or between tines, and clustered tines.

Antler Conformation

These examples of antler conformations and their gross and net Boone and Crockett scores are all deer harvested in Mississippi.

A) typical: gross 173 7/8, net typical 172 0/8
B) typical with sticker points: gross 192 3/8, net typical 171 4/8
C) drop tines: gross 214 1/8, net non-typical 201 3/8
D) double main beam: gross 192 4/8, net non-typical 178 7/8
E) palmated: gross 190 4/8, net non-typical 175 5/8
F) cluster points: gross 312 4/8, net non-typical 295 6/8.
Photo Credit Magnolia Records Program, Mississippi Department of Wildlife, Fisheries and Parks and Mississippi Wildlife Federation.

Antler Conformation Variation

Some deer antlers exhibit annual variation in conformation, and a deer's last antler set may be quite abnormal. The same deer at 10 years (A) and at 14 years of age, just prior to his death (B). Another deer at maturity (C) and the year of his death (D).

Antler Conformation Consistency

Antlers from the same deer at ages 3, 4, and 5 years showing consistency of general conformation, annual variation in presence of tines (a), and abnormal points increasing at older ages (b).

 The frequency of abnormal points increases with age, and are rarely seen at 1 and 2 years of age. White-tailed deer antlers usually have more prominent brow tines and lack the bifurcated branching present in mule deer. However, abnormal points arising from the second tine, similar to the bifurcated branching of mule deer, are relatively common in mature whitetails, perhaps indicative of the close taxonomic relationship of the two species. A similar situation occurs in the other direction, in that Sitka black-tailed deer antlers resemble those of white-tailed deer.