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AGING
DEER
Learn how to forensically age your own deer, 2 years old or younger! Deer aging video.
Watch Henry Chidgey on YouTube show how to do this.
"Wow, he's
huge!", "I wonder how old he is?", "She looks
old, how old do you think she is?", "I wonder how many
years that old boy has been around here?" The list goes on.
One of the challenges hunters like I have had over the years is
knowing, for sure, how old the deer they harvested was. I had bought
all the books, wall charts, and aging wall plaques that promised
to teach and show an exact way of aging based on looking at the
molars in a deer’s jaw. Well, this seemed to work well for
fawns and 1 ½ year olds, because the number and type of teeth
seemed to accurately place these age classes. But beyond that, my
confidence that what the charts, books, and “experts”
told me could be accurately applied to the jaw I had in my hand
was very low.
Later, I discovered
three new pieces of knowledge. The first was that there had been
formal studies done by two different organizations/ researchers
to verify the accuracy (or lack thereof) of aging deer by looking
at the molars and their wear. The second was that there was a physiological
mechanism that occurred in all mammals every year. A layer of cementum
is deposited around the portion of the teeth located beneath the
gum. In addition to this there was and is a forensic laboratory
method that allows histologists to prepare these teeth so that the
rings of cementum can be counted under a high powered microscope
as easily and accurately as counting the growth rings of a tree.
 So
let’s look into these bits of new knowledge in more depth.
First, the studies revealed that the molar wear technique did not
work, even for trained experienced wildlife biologists that had
looked at thousands of deer. In the Journal
of Wildlife Management 64(2):441-449 Kenneth Hamlin and 4 other
wildlife professionals from the Montana Fish, Wildlife, and Parks
concluded (based on a study of 53 known age mule deer and 21 known
age whitetail by eruption-wear and 108 known age mule deer and 74
known age whitetail by cementum annuli) “The accuracy provided
by the cementum annuli method is necessary to determine whether
various physical and population parameters change significantly
with age of the animal…. Ages assigned by eruption–wear
criteria were not reliable for comparing physical measurements and
population parameters by age among populations…. Accuracy
for a sample of known-age mandibles aged by eruption-wear criteria
was 62.3% for mule deer, 42.9% for whitetails, and 36% for elk”.
“The accuracy for individual biologists ranged from 54.7-71.7%
for mule deer and 23.8-66.7% for whitetail deer” “This
aging was done by 4 biologists from Montana and 2 from Washington
considered to be experienced in aging deer used eruption-wear to
age these mandibles…”. Cementum annuli aging yielded
a 92.6% accuracy rate for mule deer (with no error over 1 year),
85.1% accuracy rate for whitetails (only 2 in error over 1 year)
and 97.3% accuracy rate for elk.
Ken Gee, a wildlife
biologist at the 2,947 acre Noble Foundation Wildlife Unit (NFWU)
said at the conclusion of a study he did in 1996 “These results
indicate that this widely used technique (sic eruption-wear) is
very inaccurate for classifying adult deer into specific year age-classes
on the NFWU….(it)only allows us to confidently place deer
into three age classes: fawn, yearling, and adult.” The study
was done using “34 practicing, established, well respected
deer biologists from the southeastern U.S. that commonly use the
technique (sic eruption-wear).”
Now,
the second bit of new knowledge was around the thing called cementum.
The following information comes from The University of Manitoba:
Dental cementum
grows continuously during an organisms' lifetime without reabsorbing
(as bone and other dental tissues like dentine and enamel do). This
means that dental cementum offers a complete record of individual
growth. For this reason, dental cementum is particularly interesting
to archaeologists.
Composition of dental cementum:
Dental cementum is a mineralized tissue closely related to bone.
Both are composed of approximately 65% inorganic components and
about 35% organic components, with relatively few cells per volume/mass
of mature tissue. Cells in cement, cementocytes, are secreted by
cementoblasts embedded in the tissue. The organic matrix which forms
the basic structural component of bone and cement is composed of
collagen fibres.
Cementum growth pattern:
Cementum growth, or deposition, is most simply described as a two-phase
process: the first phase is the production of the organic matrix,
followed by the mineralization phase. Growth is appositional and
results in a banded structure, implying the existence of structural
variations in the deposited tissues.
The layering observable in dental cementum corresponds to the presence
of growth layers, composed of growth
zones, annuli and lines of arrested growth, or LAGs. A number
of possible explanations for the optical and physical expression
of growth layers in bone and cement have been offered: changes in
mineral density; cellular density; histochemical differences; and
collagen fibre orientation. Organization of the collagen fibre matrix
is currently believed to be the source of the observed major structural
variations between growth layers.
Biologists have investigated growth
marks in a wide variety of vertebrate species from different
environments. They have empirically identified a yearly cycle of
cementum formation, consisting generally of a single paired growth
zone + annulus/LAG. These empirical observations, based on studies
of control
groups of animals of known age and season at death, are supported
by experimental studies involving the use of fluoromarkers as "benchmarks"
to record the position of cement growth at precise intervals. The
fact that several different types of bony tissue form incremental
lines in synchrony, i.e., dentine, cement and periosteal bone, supports
this identification.
Another piece from this work
says:
“Stained, Histological Thin Section:
Demineralized, stained sections, thin sectioned while frozen with
the use of a microtome saw, mounted in an aqueous medium, have also
been used to investigate banding in bone and cement. When stained
with Ehrlich's haematoxylin, for example, cement and primary cortical
bone show alternate bands of wide, poorly stained tissue and thin,
darkly stained tissue. The thin, chromophile bands correspond to
annuli or, more often, to LAGs. In stained, decalcified sections,
the importance of the orientation of the fibre matrix in determining
the characteristics of the increment is apparent. A number of different
staining agents, e.g., Mayer's haemalin and silver nitrate, have
been used to produce dichromism highlighting the histochemical differences
between annuli and growth zones in these tissues.”
So, we now know what cementum is and that there is a forensic laboratory
histological process that allows us to accurately determine the
length of time a tooth has been in a mammal’s mouth. We also
know that most all mammals (humans too!) deposit discrete layers
of cementum around the portion of the tooth located beneath the
gum line. If you carefully slice the tooth in thin sections, stain
these sections, and place them on a slide under a high power microscope,
you can then count the rings (annuli) of cementum and know the length
of time that tooth was in that deer’s jaw. It is just like
counting the rings on a tree to determine it’s age. The teeth
we choose to use in a deer’s mouth for aging are the two front
center teeth (center incisors). The reason for this choice is that
these teeth are in place by the time the fawn is 4-6 months old
and remain in place through out the deer’s life. These teeth
and the first molar are the first permanent teeth a fawn gets. The
center incisors are much easier to remove than a jaw bone and especially
a molar out of the jaw bone. So, forensic cementum annuli aging
is typically performed on the two center incisors, but may also
be performed on the M1 molar, the fourth tooth from the front of
the 3 premolar, 3 molar teeth in a mature whitetail’s jaw.
The next part of this story is what I did next, armed with these
new tidbits of knowledge. I went searching for a lab to age my trophies.
What I discovered was that there was only one private (not government
or University) lab that did this commercially. Also, none of the
labs seemed to be focused on quick reliable turn around. So I tried
a lab (actually a middleman that used another lab) and was disappointed
by the way the results were reported and the length of time it took
to get the results. I sent the four specimens in the first week
of February and received a call on July 18th in which I was told
the results over the telephone. No e-mail, fax, or letter confirming
the results, just a phone call and it took over 5 months.
Well, I decided that if someone was going to meet the needs of clients
like me, I was going to have to do it. So, I obtained every research
paper I could find on cementum annuli aging of any mammal, engaged
an experienced histologist, set up a well equipped laboratory, and
created Wildlife Analytical Laboratories—Home of www.DeerAge.com
, to meet the needs and desires of clients like myself. Those needs
are- Accuracy of Results and Great Customer Service. We have developed service offerings targeted for and now serve Ranchers, Wildlife Stewards, & Hunters Worldwide.
So, What is a REAL Trophy Whitetail? Depends, but for me it is that
whitetail doe or buck who has successfully eluded predators and
hunters for many years, taken with the most challenging weapon I
have proficiency with. That is the buck or doe that goes up on my
wall, with a Certificate of Aging™ right next to it.
Equally as important, I want to keep developing and fine tuning
my skills at aging my deer before I squeeze the trigger or loose
the arrow. That’s why I will be a lifelong student of aging.
How I will do that is to forensic cementum age every deer I harvest
and compare their actual age to what I estimated before the harvest.
I am committed to mastery of this important whitetail management
skill.
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