Harris 2005.2


43

Dental anthropologists—building on classic 
anatomical nomenclature—have a precise lexicon 
of terms for designating specific teeth.  There is, for 
example, no confusion when describing a human’s 
“permanent maxillary right central incisor.”  Such 
labels are, however, lengthy and cumbersome, no more 
so than in the dental clinical setting where a dentist 
needs to expeditiously document voluminous details 
on numerous patients in a concise manner (Schwartz 
and Stege, 1977).

The practical need for conciseness, precision and 
brevity has led clinicians to develop a variety of tooth 
coding systems, some of which are intuitive while others 
are refractory without some clues.  The purpose of this 
note is to delineate the common clinical systems of tooth 
coding in order to familiarize dental anthropologists 
with the clinical nomenclature.

Permanent dentition

It is common knowledge that the adult human 
dentition consists of 32 teeth arrayed into four 
morphological classes in each quadrant (e.g., Todd, 1918; 
LeGros Clark, 1959).  This leads to the dental formula

 
I

2
2

C
1
1

P
2
2

M
3
3  

or, simply,
 

2 1 2 3
2 1 2 3

which is a symbolic denotation that there normally are 
2 incisors, 1 canine, 2 premolars, and 3 molars in each 
of the four quadrants of the mouth.  The etymologies 
of these dental terms are all from the Latin.  Incisor (L. 
incidere = to cut into) alludes to the incisors’ function 
of incising and nipping; incisors are the “cutting 
teeth.”  Canines (L. canis = dog, hound) derives from 
the prominent, well-developed teeth in the family 
Canidae (dogs), though their value for prehension has 
been considerably diminished in humans, where these 
teeth function essentially as incisors.  Most clinical 
dentists use the term cuspid in place of canine, since 

Tooth-Coding Systems in the Clinical Dental Setting
Edward F. Harris*

Department of Orthodontics, University of Tennessee, Memphis, Tennessee

these teeth normally consist of one large primary 
cusp.  “Premolars” merely recognizes the anatomical 
position of these teeth in front of the molars.  Clinicians 
commonly use the term bicuspid in place of premolar, 
since these teeth commonly (but certainly not always) 
possess two cusps (cf. Kraus and Furr, 1953).  Molars (L. 
molaris = millstone) refers to the grinding, triturating 
function of these teeth with their substantial occlusal 
surfaces.

Zsigmondy-Palmer system

The most popular system of tooth designation 
for much of the 20th century was developed by the 
Viennese dentist Adolph Zsigmondy (Zsigmondy, 1861, 
1874).  He broke with tradition, substituting numbers for 
the eight teeth in each quadrant in place of the lengthy 
Latin names in use to that time (Schwartz and Stege, 
1977; Peck and Peck, 1993). The correspondence is:

1 ...................... Central incisor
2 ...................... Lateral incisor
3 ...................... Canine (cuspid)
4 ...................... First premolar (bicuspid)
5 ...................... Second premolar (bicuspid)
6 ...................... First molar
7 ...................... Second molar
8 ...................... Third molar (dens sapientiae;
 wisdom tooth)

Zsigmondy combined his tooth numbering system 
with a graphical device to specify the quadrant of the 

mouth.  An L-shaped mark ( ) was used, with the 

*Correspondence to:  Edward F. Harris, Department of 
Orthodontics, College of Dentistry, The Health Science 
Center, 875 Union Avenue, University of Tennessee, 
Memphis, TN  38163.
E-mail:  eharris@utmem.edu

ABSTRACT     Clinical dentists have developed a variety 
of tooth-coding systems for efficiently recording a 
patient’s dental status. The coding systems may not be 
self-evident to dental anthropologists lacking dental 
training.  The purpose of this note is to review the 
tooth designation systems currently in common use.  
The nature of the charting systems and brief historical 
origins of three systems are reviewed, namely (1) the 

Zsigmondy-Palmer system that is becoming largely 
of historical interest, (2) the Universal system that is 
common in the United States, and (3) the FDI two-digit 
system that has been adapted throughout the rest of 
the world. Use of these three systems is described 
for the permanent and primary dentitions. Dental 
Anthropology 2005;18(2):43-49.



44

vertical line segment being the subject’s midline and 
the horizontal segment his occlusal plane that separates 
the upper and lower arcades.  The clinician could, then, 
easily code a specific tooth, such as the lower left canine 

3  or the upper right first molar 6 .  Confusion is pretty 
much limited to the novitiate’s need to remember that 
the codes refer to the patient’s left or right side.

History then becomes a bit conflicted because the 
Ohio dentist Corydon Palmer (Palmer, 1870, 1891) 
argued for his independent invention of the same coding 
system.  Palmer contended that the natural division of 
the dentition into quadrants was a well-known, obvious 
device (Fig. 1).  Indeed, Palmer was quite testy in his 

1891 paper that he be given all credit for the scheme’s 
development (Fig. 2).  The quadrant is denoted by the 

shape of the symbol, like  for mandibular left, and 
the tooth position is numbered from 1 (central incisor) 
through 8 (third molar).  The scheme has a naturalness 
and simplicity such that independent invention seems 
probable.  In any event, most American dentists have 
been taught the notation as being Palmer’s (though also 
termed the “quadrant system” by some; Sharma and 
Wadhwa, 1977).  The Palmer system also has been labeled 
the “angular system” and the “grid system” because of 
the horizontal and vertical line segments that denote the 
tooth’s quadrant.

The obvious down-side of the Zsigmondy-Palmer 
notation is that, while it is easy to sketch the tooth codes 
in a patient’s record, it is tedious to type or verbalize 

them.  For instance, there is no word for the symbol  or 

. Gustafson (1966), O’Connor (1983) and others have 
commented that Palmer’s angle symbol denoting side 
and arch probably was the system’s undoing.  While it is 

no effort at all to jot down 5  or 7  in a patient’s record, 

there is no natural analog for 3  with an embedded 
digit on a typewriter or word-processor.  Indeed, it was 
the need to computerize the dental recording system 
that marshaled-in the FDI system—and incidentally 
promoted the use of the Universal system in the United 
States.  Coding a tooth numerically, as #16 or 28, lends 
itself to word processing.

Desiderata

There are a few other items of note that developed 
contemporaneous with Zsigmondy and Palmer but do 
not warrant full-blown descriptions here.  The Latin terms 

E.F. HARRIS

Fig. 1. Facsimile of a diagram by Palmer (1891) showing 
the division of the dentition into four quadrants.  The 
vertical and horizontal line segments are used in this 
charting method to specify a tooth’s quadrant. Facing 
the patient, as here, the quadrants are numbered clock-
wise from the upper left of the figure, so the patient’s 
quadrants are (1) upper right, (2) upper left, (3) lower 
left, and (4) lower right.

Fig 2. The Zsigmondy-Palmer tooth designation system, where lines define the four quadrants and the teeth are 
numbered from 1 to 8 in each quadrant (modified from Palmer, 1891).



45

superiore (sup.) and inferiore (inf.) will be encountered 
in the older literature, referring to the maxillary and 
mandiblar jaws, respectively.  Likewise, the Latin words 
dextral (dext.) and sinistral (sin.) commonly were used to 
denote a tooth in the right or left arcade, respectively.  So, 
for example, de Terra (1905:5) uses the code “I1 sup. sin.” 
to denote the maxillary left I1 (central incisor).

Also, Haderup’s (1891) tooth designation system 
experienced popularity for some decades after its 

introduction.  In place of Zsigmondy’s angle (e.g., ), 
Haderup used a plus sign (+) to denote a maxillary tooth 
and a minus sign (–) for a mandibular tooth, and the sign 
was placed mesial to the tooth being referred to, so a 

right upper second molar would be 7+ and a left lower 
first premolar would be –4.

FDI system

Dentists throughout the world—notably excepting 
the United States—now use the FDI two-digit system 
(Fédération Dentaire Internationale).  This scheme was 
developed by a “Special Committee on Uniform Dental 
Recording” and passed as a resolution of the FDI Gen-
eral Assembly at its 1970 meeting in Bucharest, Romania 
(Keiser-Nielsen, 1971a,b,c).  While the FDI labeled this 
the “Two-Digit System,” it is more commonly referred to 
as the FDI system.  It is useful to consider the five crite-

Fig. 3. The FDI two-digit scheme for tooth designations of the permanent dentition. The view is oriented as if you 
are looking at the subject, so the person’s right side (quadrants 1 and 4) are to the left of the page.

Fig. 4. The Universal scheme for tooth designations of the permanent dentition.

CLINICAL TOOTH DESIGNATION SYSTEMS



46 E.F. HARRIS

ria that, according to the Committee, are attained by this 
two-digit system of designating teeth:
1. Simple to understand and to teach.
2. Easy to pronounce in conversation and dictation.
3. Readily communicable in print.
4. Easy to translate into computer output.
5. Easily adapted to standard charts used in general 

practice.
As diagrammed in Figure 3, the first digit denotes 

the quadrant of the mouth, the second digit defines the 
tooth’s normal position in the mouth, front to back.

In all of these systems, the tooth’s “number” is its 
normal, expected position in the arch.  Expectation is that 
there are two incisors, one canine, two premolars, and 
three molars in each quadrant.  “Missing” teeth (due to 
congenital absence, impaction, extraction, etc.) are taken 
into account when identifying a tooth’s number. When a 
tooth is not present, its designation has to be determined 

from the positions of the extant teeth.  For example, 
permanent mandibular second premolars are congenitally 
absent in roughly 3% of modern humans (Stritzel et al., 
1990; Larmour et al., 2005), but determination of whether 
it actually is the first or second premolar that is missing 
in a particular case depends on the clinician’s differential 
diagnosis based on teeth that are present and related 
criteria. Conversely, there is no accommodation in any of 
these systems for supernumerary teeth; these rare events 
are simply written-out in the chart.

Most dentists, as with most dental anthropologists, are 
right handed, so quadrant 1 (maxillary right) is closest to 
the dentist when examining a patient and is scored first, 
then the upper left quadrant, then one drops down to 
the lower left quadrant, finishing with teeth in the lower 
right quadrant (Fig. 1).  More formally, the quadrants 
are numbered “in a clockwise sequence … starting on 
the upper right side” when viewing the subject from 

Fig. 5. The Palmer tooth designation system for the primary dentition. The five tooth types in each quadrant are 

denoted by letters. The quadrant is coded by using the symbol , , , or .

 Upper Right Upper Left

   E D C B A A B C D E 

 8 7 6 5 4 3 2 1 1 2 3 4 5 6 7 8 

 8 7 6 5 4 3 2 1 1 2 3 4 5 6 7 8 

   E D C B A A B C D E 

 Lower Right Lower Left

Fig. 6. Arrangement of the permanent tooth codes in the Zsigmondy-Palmer system along with the corresponding 
codes (letters) for the primary teeth. Such a chart is commonly found in older dental settings (Sharma and Wadhwa, 
1977), though it is being upgraded to the more easily computerized Universal or FDI systems.



47CLINICAL TOOTH DESIGNATION SYSTEMS

the front (Keiser-Nielsen, 1971a:105).  This is to say that 
the upper right side (quadrant 1) is the patient’s upper 
right side.  The FDI’s description also suggests how 
to verbalize the system, namely “The digits should be 
pronounced separately; thus, the permanent canines are 
teeth one-three, two-three, three-three, and four-three” 
(1971a:1034).

The FDI committee fully recognized that it was 
combining Zsigmondy-Palmer’s tooth numbering 
system with the prefix number denoting the quadrant.  
The committee termed this a “compromise” system.  
The committee also pointed out that its quadrant-
numbering sequence adopted the same pattern used by 
the Universal system, making it familiar to U.S. dentists.  
With this logical system, there is no ambiguity as to side, 
quadrant, or arcade.

Universal Numbering System

What has become the Universal system was proposed 
by J. Perreidt in 1882. Perreidt disliked the redundancy 
and potential confusion of Zsigmondy’s use of tooth 
numbers 1 through 8 in all four quadrants.  Instead, he 
numbered the permanent teeth 1 through 32, starting at 
the upper right and continuing to the upper left, then the 
lower left to the lower right (Fig. 4).  The main benefit 

is that Zsigmondy and Palmer’s angular symbol (
) is irrelevant, each tooth having its unique numerical 
designation.

Today, the “Universal”system of tooth-coding is 
an interesting misnomer, because it is only used in the 
United States.  The ADA (American Dental Association) 
by a unanimous decision of its Council on Dental Care 
Programs adopted the Universal System of numbering 

teeth on April 18, 1975 (Schwartz and Stege, 1977).  
Numerous dentists subsequently have editorialized about 
the unnatural, illogical nature of the Universal system—
not to mention the unheeded complaints from fledgling 
dental students.  The universal system is disarmingly 
simple in concept, just number the 32 permanent teeth 
from 1 through 32 (Fig. 4). The difficulty is in learning 
to associate specific teeth with their numbers.  Once 
learned, of course, the system is effortless. Starting with 
the third molar in the upper right quadrant (tooth #1), 
the teeth are numbered around the arch so the maxillary 
left third molar is tooth #16.  One then drops down to the 
mandibular left third molar (#17) and numbers the teeth 
around the lower arcade, finishing with the mandibular 
right third molar (#32).

There is no easy way to relate these 32 numbers to 
the natural, anatomic arrangement of the teeth.  There 
is, for instance, no way to know intuitively that the 
second premolars are #4, #13, #20 and #29.  One simply 
has to learn the system by rote. The compelling value 
of the Universal system (as with the FDI system) is the 
ease of computerizing the data, which is its singular 
selling point for automating office systems (“paperless 
offices”), completing insurance and other third-party 
reimbursement forms (certainly a financial incentive), 
and accelerating communication (providing that both 
parties understand the codes).

With both the FDI and Universal systems, each tooth 
has a unique identifier.  This can be invaluable when 
irreversible procedures such as extractions or endodontic 
treatment are requested by one dentist from another.

Primary dentition

The primary teeth are ephemeral in that they only 

Fig. 7. The Universal system for the primary dentition, coding each tooth with a letter. As with all of these sys-
tems, the orientation refers to the patient’s own right and left sides, so the patient’s maxillary right quadrant is to 
the upper left of this diagram.



48

need to function for a few years before being replaced 
by (generally) larger and better-constructed permanent 
teeth with greater longevity.  Typically, the first primary 
teeth (the incisors) erupt through the oral mucosa at 7 
or 8 months of age (e.g., Tanguay et al., 1984), and the 
last primary teeth are exfoliated around 12 years of age, 
when the primary molars are replaced by the permanent 
premolars (e.g., Hurme, 1949; Moorrees et al., 1963).  There 
are 20 succedaneous permanent teeth that “succeed” and 
replace the 20 primary teeth; the three permanent molars 
in each quadrant erupt distal to the primary teeth, so they 
are additional rather than replacement dental elements.  
“Primary” would seem to be the preferred term here, but 
common synonyms are the deciduous teeth, the baby 
teeth, and the milk dentition.  Morphologically, the 20 
primary teeth are categorized into three tooth types, 
incisors, canines, and molars, with the dental formula 
of 2:1:2 in each quadrant.  Fewer clinical coding systems 
have been developed for the primary dentition, but there 
still are plenty to provide confusion for the uninitiated.  
The three systems analogous to those described above 
for the permanent dentition are presented here.

Palmer analog.  Letters have commonly been used to 
denote the primary teeth; some systems use lower-case 
letters (perhaps mimicking the subadult nature of these 
teeth; Churchill, 1932), but capital letters are encountered 
more often (Fig. 5).  Again, the side and arcade are denoted 

by line segments: B  is the maxillary right lateral incisor, 

and E  is the mandibular left second molar.
Primary teeth have also been designated by Roman 

numbers (I—V), which can further confuse the novice 
(Churchill, 1932; Sharma and Wadhwa, 1977), particularly 
since still other systems have used Roman numerals to 
designate quadrants in the permanent dentition.  A chart 

as in Figure 6 commonly is used in dental offices, and 
inspection shows that the numerals conform to Palmer’s 
notation for the permanent teeth. while the capital letters 
are for the primary teeth.

Universal system.  The 20 primary teeth are coded 
alphabetically from A through T (Fig. 7).  There is no 
anatomic parallel with this system.  One simply has 
to memorize the system by rote.  If using this system 
infrequently, it helps to remember that A, J, K and T are 
the second molars (at the distal ends of the quadrants) 
and that E, F, O and P are the central incisors.  Since 
there are only five teeth per quadrant, one can generally 
visualize the other tooth codes.

FDI system.  So much clinical attention is spent on 
the permanent teeth that they are coded as quadrants 1 
through 4.  The convention is to use numbers 5 through 
8 to code the four primary quadrants even though they 
develop first (Fig. 8).  This numerical oddity was the 
subject of considerable discussion by the FDI committee, 
but it was reasoned that, “mainly because deciduous 
teeth function for such a short time in comparison with 
permanent teeth that the bulk of dental data to be collected 
and computerized in the future would obviously concern 
permanent teeth” (Keiser-Nielsen, 1971a:1035).

Overview

There are two major motivations to develop a 
tooth-coding system.  One is to conserve energy and 
communicate telegraphically.  Writing or speaking 
(or typing) “the permanent mandibular right second 
premolar” is much more taxing than referring to this 
tooth as #29 or 45, especially if teeth consume one’s 
professional life.  There is the need to be specific but also 
to be as concise as practical.  The other, recent driving 
force is to computerize ever-increasing masses of data, 

Fig. 8. The FDI system for the primary dentition. Quadrants for the primary dentition are numbered 5 through 8. 
Quadrant numbers 1 through 4 are used for the permanent dentition, primarily because the dentist’s attention on 
the permanent dentition is so much greater than with the primary dentition.

E.F. HARRIS



49

and numeric codes (and their alphabetic equivalents) 
lend themselves to this end. The greatest emphasis 
has been from third-party payment systems with the 
need for the dentist to code the services rendered for 
reimbursement.

One minor spin-off of the trend toward globalization 
is the need for standardization—so all of the participants 
understand the same set of “rules” and can communicate 
effectively.  The FDI system seems to be the solution in 
terms of dental-coding systems.  This leaves the U.S. 
“Universal” system as an anachronism, but it doubtlessly 
will persist as a system paralleling the FDI system until 
the U.S. also converts to the metric system—which is 
moving glacially, at best.  In scientific circles, though, 
an increasing number of dental journals is requiring its 
authors to use of the FDI system for tooth designations.

Only the three most common and long-lived systems 
are described here.  Numerous others have been proposed 
and may be encountered (see reviews in Gustafson, 1966, 
and Schwartz and Stege, 1977).

REFERENCES CITED

Churchill HR. 1932. Human odontography and histology. 
Philadelphia:  Lea & Febiger.

Gustafson G. 1966. Forensic odontology. New York: 
American Elsevier Publishing Company, Inc.

Hurme VO. 1949. Ranges of normalcy in the eruption of 
permanent teeth.  J Dent Child 16:11-15.

Keiser-Nielsen S. 1971a. Fédération Dentaire Internationale 
two-digit system of designating teeth. Int Dent J 
21:104-106.

Keiser-Nielsen S. 1971b. Two-digit system of designating 
teeth.  Br Dent J 130:215-216.

Keiser-Nielsen S. 1971c. Federation Dentaire 
Internationale. J Amer Dent Assoc 82:1034-1035.

Kraus BS, Furr ML. 1953. Lower first premolars. I. A 
definition and classification of discrete morphologic 
traits. J Dent Res 32:554-564.

Larmour CJ, Mossey PA, Thind BS, Forgie AH, Stirrups 
DR. 2005. Hypodontia—a retrospective review of 
prevalence and etiology. Quintessence Int 36:263-270.

Le Gros Clark WE. 1959. The antecedents of man.  New 
York:  Harper & Row.

Moorrees CFA, Fanning EA, Hunt EE Jr. 1963. Formation 
and resorption of three deciduous teeth in children. 
Am J Phys Anthropol 21:205-213.

O’Connor JT. 1983. Let’s really standardize our tooth 
numbering system.  Oper Dent 8:73-74.

Palmer C. 1891. Palmer’s dental notation. Dent Cosmos 
33:194-198.

Peck S, Peck L. 1993. A time for change of tooth numbering 
systems.  J Dent Ed 57:643-647.

Parreidt J. 1882. Zählung der Zähne und Benennung 
der verschiedenen Zahnsorten. Zahnärzliche 
Mitteilungen aus der chirurgischen Universitäts-
poliklnik zu Leipzig, Arthur Felix, p 10-15 [cited in 

Gustafson, 1966].
Schwartz  S, Stege D. 1977. Tooth numbering systems: a 

final choice. Ann Dent 36:99-106.
Sharma PS, Wadhwa P. 1997. Evaluation of the FDI two-

digit system of designating teeth.  Quintessence Int 
10:9-101.

Stritzel F, Symons AL, Gage JP. 1990. Agenesis of the 
second premolar in males and females:  distribution, 
number and sites affected. J Clin Pediatr Dent 15:39-
41.

Tanguay R, Demirjian A, Thibault HW. 1984. Sexual 
dimorphism in the emergence of the deciduous teeth. 
J Dent Res 63:65-68.

de Terra M. 1905 Beitrage zu einer Odontographie den 
Menschenrassen.  Berlin:  Berlinishche Verlagsanstalt.

Todd TW. 1918. An introduction to the mammalian 
dentition.  St Louis:  CV Mosby Company.

Zsigmondy A. 1861. Grundzüge einer praktischen 
Methode zur raschen und genauen Vormerkung der 
zahnärztlichen Beobachtungen und Operationen. 
Deutsch Viertel Zahnhk 1:209-211.

Zsigmondy A. 1874. A practical method for rapidly 
noting dental observations and operations.  Br J Dent 
Sci 17:580-582.

CLINICAL TOOTH DESIGNATION SYSTEMS

A Brief Survey
G. Richard Scott and I are updating the history of 

dental anthropology that appeared in our 1988 review 
article on dental anthropology in the Annual Review 
of Anthropology, and in the history section of our 1997 
book, The Anthropology of Modern Human Teeth. We 
would like to add a table indicating who is teachin 
dental antrhopology and where the courses are being 
taught. The Dental Anthropology Association member-
ship seems like the best group at which to direct such 
an inquiry.

If you have in the last 15 years taught a course 
titled dental anthropology, or an anatomical or osteo-
logical course with a significant dental anthropology 
component, could you please let us know. You can 
either e-mail me, or fill out the enclosed question-
naire.   If you use the questionnaire, please return to 
Dr. Christy G. Turner II, 2208 N. Campo Alegre Dr., 
Tempe, AZ 85287-1105. In the latter case, if you have a 
short syllabus, we would be grateful to have a copy.

Thank you.

Christy G. Turner II
Regents’ Professor Emeritus of Anthropology
College of Human Evolution and Culture Change
Arizona State University
Tempe, AZ 85287-2402

E-mail:  chrstygturner@aol.com