Harris and Couch 2006.6


87

Human tooth crown dimensions exhibit little sexual 
dimorphism, which detracts for their usefulness for 
sex determination (Ditch and Rose, 1972; De Vito and 
Saunders, 1990).  Garn et al. (1967) showed that sexual 
dimorphism in a sample of American whites is only 
on the order of 3-5%, making them substantially less 
dimorphic than any of the other higher primates (e.g., 
Swindler, 2002; Koppe and Swindler, 2004).  The canines 
characteristically are the most dimorphic (ca. 6%), 
notably their buccolingual widths.

Sexual dimorphism in tooth size is useful in forensic 
settings (Teschler-Nicola and Prossinger, 1998) and also 
in archeological settings when the more informative 
skeletal elements are immature or absent (Krogman 
and Iscan, 1986; Ubelaker, 1999).  That sex differences 
occur at all in the primary and permanent teeth is of 
interest because they depend on hormonal differences 
that preferentially develop size and shape in one sex 
over the other well before the onset of steroid-mediated 
adolescence (Tanner et al., 1959; Manning, 2002).

We have collected incisor crown and root dimensions 
from a contemporary sample of American whites, and 
the purpose of this paper is to assess the relative sexual 
discriminating effectiveness of these crown and root 
variables.

MATERIALS AND METHODS

Incisor dimensions were obtained from standardized 
periapical radiographs using a computer assisted 
measurement system.  Data were collected from 148 
adolescent American white adolescents (57 males, 91 

The Relative Sexual Dimorphism of Human Incisor 
Crown and Root Dimensions

Edward F. Harris* and W. Max Couch, Jr.

Department of Orthodontics, University of Tennessee, Memphis, TN 38163

ABSTRACT:   Teeth are unusual structures in that their 
dimensions are sexually dimorphic even though they 
form early in life, several years before steroid-mediated 
adolescence.  These size differences make teeth attractive 
as indicators of a specimen’s sex.  Alternatively, the 
magnitude of sexual dimorphism in humans is low, so 
there is considerable overlap in sizes between the two 
sexes.  Prior studies suggest that tooth root dimensions 
are more dimorphic than crown dimensions, so roots 
would be more useful for sex determination.  To 
explore this, we measured the four incisor tooth types 
from standardized periapical radiographs in a sample 

(n = 148) of living American white adolescents.  Root 
lengths are somewhat more dimorphic than crown 
sizes in this sample (ca. 6% vs. 2%), and this translates 
into somewhat higher discriminatory power.  The 
hindrance, however, is that all crown and root sizes 
are positively intercorrelated, so there is effectively 
just one dentition-wide axis of “tooth size” variation.  
Statistically, at least for these incisor tooth types, there 
is no added discriminatory power in the crown sizes 
once root dimensions have been accounted for, though 
the addition of data from other tooth types might 
improve discrimination somewhat.  Dental Anthropology 
2006;19(3):87-95. 

females).  These were healthy, phenotypically normal 
teenagers (mean age 14 years).  All of the teeth were 
caries-free, and none had been treated orthodontically, 
which typically reduces root length due to external apical 
root resorption (Brezniak and Wasserstein, 1993a,b).  
Subjects were old enough to ensure root apexification, 
which is completed for the incisors around 10 years of age 
(Harris and McKee, 1990).  Radiographs had been taken 
by an experienced dentist using a long-cone paralleling 
technique.  Teeth with rotations or angulations affecting 
tooth-to film orientations were omitted from analysis.  
Radiographs give a proper measure of crown height 
since the cementoenamel junction is not obscured by the 
gingiva (cf. Rhee and Nahm, 2000).

Radiographs were digitized at 1,200 dpi and 256-
greyscale.  SigmaScan 5.0 (SPSS Inc., Chicago, IL) was 
used to obtain crown and root dimensions, which were 
corrected for magnification prior to statistical analysis.  
The screen image of each tooth was magnified several-
fold, which enhances landmark location but does not 
affect the dimensions obtained.  The tooth with better 
image quality and alignment was chosen from each 
left-right pair. If there was no difference, the tooth in 
the left quadrant was analyzed, so sample sizes are of 
individuals, not teeth.

*Correspondence to: Edward F. Harris, Department of 
Orthodontics, University of Tennessee, Memphis, TN 
38163.
E-mail: eharris@utmem.edu



88

present study, the average of these two distances was 
used as root length.  This distance was subtracted on 
an individual basis from tooth length to yield crown 
height. In sum, tooth length equals crown height plus 
root length.

Sexual dimorphism was assessed statistically using 
factorial analysis of variance (Winer et al., 1991) and 
stepwise multivariate discriminant functions analysis 
(Cooley and Lohnes, 1971). Principal components 
analysis (Gorsuch, 1983) was performed to evaluate the 
statistical associations among the variables.  Statistics 
were calculated using the JMP software package (SAS 
Institute Inc., Cary, NC).

RESULTS

Tooth Dimensions
Of the four incisor tooth types, mesiodistal crown 

diameter of just the upper central incisor (U1) exhibits 

TABLE 1. Descriptive incisor dimensions, by sex, and tests for sexual dimorphism1

 Males Females % Sex Adjusted Analysis of Variance
Tooth n x  sd sem n x  sd sem Dimorphism r2 % F-ratio P value

Crown Width
 U1 57 9.23 0.81 0.11 91 8.91 0.59 0.06 3.69 4.61 8.10 0.0051
 U2 55 6.98 0.60 0.08 90 6.90 0.62 0.06 1.15 (-0.30)# 0.57 0.4497
 L1 56 5.41 0.46 0.06 91 5.32 0.40 0.04 1.82 0.54 1.79 0.1828
 L2 57 6.07 0.51 0.07 90 5.97 0.39 0.04 1.72 0.64 1.93 0.1666

Tooth Length
 U1 57 26.36 2.49 0.33 91 25.21 2.14 0.22 4.56 5.11 8.91 0.0033
 U2 56 25.15 2.42 0.32 90 23.78 1.95 0.21 5.76 8.29 14.11 0.0002
 L1 56 22.48 2.22 0.30 91 21.60 1.86 0.19 4.08 3.76 6.70 0.0106
 L2 57 23.90 2.54 0.34 91 23.04 1.87 0.20 3.71 2.99 5.54 0.0199

Crown Height
 U1 57 8.40 1.00 0.13 91 8.24 0.86 0.09 1.93 0.04 1.06 0.3042
 U2 56 7.45 0.86 0.11 90 7.14 0.69 0.07 4.31 3.10 5.64 0.0189
 L1 56 7.05 1.01 0.14 91 7.14 0.86 0.09 -1.19 (-0.49)# 0.30 0.5874
 L2 57 7.23 0.95 0.13 91 7.23 0.81 0.08 -0.01 (-0.69)# 0.00 0.9961

Root Length
 U1 57 17.95 1.98 0.26 91 16.96 1.86 0.20 5.84 5.45 9.47 0.0025
 U2 56 17.70 1.99 0.27 90 16.64 1.75 0.18 6.38 6.70 11.41 0.0009
 L1 56 15.43 1.70 0.23 91 14.47 1.38 0.14 6.68 8.34 14.29 0.0002
 L2 57 16.67 1.96 0.26 91 15.81 1.39 0.15 5.41 5.55 9.64 0.0023

Crown-Root Ratio
 U1 57 0.47 0.07 0.01 91 0.49 0.07 0.01 -3.95 1.19 2.77 0.0981
 U2 56 0.42 0.06 0.01 90 0.43 0.06 0.01 -2.14 (-0.09)# 0.86 0.3542
 L1 56 0.46 0.07 0.01 91 0.50 0.06 0.01 -7.17 5.98 10.29 0.0016
 L2 57 0.44 0.06 0.01 91 0.46 0.05 0.01 -4.80 3.20 5.86 0.0168

1Tooth codes are maxillary central (U1) and lateral (U2) incisor and mandibular central (L1) and lateral (L2) inci-
sor.  Sexual dimorphism is calculated from the means, ((M-F)/F) times 100. Ajusted r2 is the variation in the tooth 
dimension accounted for by sexual dimorphism (the independent variable) in the analysis of variance.
#The r2 is close to zero, and the adjustment caused the estimate to be negative, though this has no statistical inter-
pretation (and should be set to zero).

Full-mouth dental casts were taken along with the 
periapical radiographs, and we measured the maximum 
mesiodistal crown dimensions of the teeth using sliding 
calipers, which provide an absolute measure of tooth size 
as well an internal check of the radiographic method.  
Four dimensions are evaluated here, (1) mesiodistal 
crown width, (2) overall tooth length, (3) crown height, 
and (4) root length.

Overall tooth length was measured from the root 
apex coronally to the mediolateral midpoint of the 
tooth’s incisal edge (Fig. 1).  Root length—from the root 
apex to the cementoenamel junction (CEJ)—is not an 
invariant distance because the CEJ undulates around 
the tooth’s periphery (Zeisz and Nuckolls, 1949), with 
the CEJ higher (more occlusal) on the tooth’s mesial and 
distal aspects than labially or lingually. We measured 
the straight-line distance from the root apex separately 
to the mesial and the distal margins of the CEJ.  For the 

E. F. HARRIS AND W. M. COUCH



89

TABLE 2. Matrix of Pearson correlation coefficients for the 16 incisor dimensions studied1

 U1 U2 L1 L2 U1 U2 L1 L2 U1 U2 L1 L2 U1 U2 L1 L2
 CW CW CW CW TL TL TL TL CH CH CH CH RL RL RL RL

U1 CW 1.00 0.55 0.62 0.58 0.35 0.32 0.43 0.44 0.45 0.35 0.35 0.39 0.21 0.23 0.35 0.36
U2 CW 0.55 1.00 0.52 0.54 0.27 0.34 0.19 0.22 0.29 0.38 0.23 0.32 0.19 0.23 0.11 0.11
L1 CW 0.62 0.52 1.00 0.68 0.27 0.23 0.48 0.44 0.41 0.31 0.48 0.42 0.13 0.14 0.34 0.34
L2 CW 0.58 0.54 0.68 1.00 0.21 0.18 0.38 0.38 0.31 0.26 0.44 0.43 0.11 0.11 0.23 0.27
U1 TL 0.35 0.27 0.27 0.21 1.00 0.67 0.51 0.51 0.56 0.38 0.26 0.33 0.93 0.62 0.51 0.49
U2 TL 0.32 0.34 0.23 0.18 0.67 1.00 0.54 0.53 0.35 0.51 0.23 0.32 0.64 0.94 0.56 0.51
L1 TL 0.43 0.19 0.48 0.38 0.51 0.54 1.00 0.88 0.36 0.26 0.67 0.59 0.45 0.51 0.90 0.82
L2 TL 0.44 0.22 0.44 0.38 0.51 0.53 0.88 1.00 0.35 0.32 0.62 0.67 0.45 0.48 0.78 0.93
U1 CH 0.45 0.29 0.41 0.31 0.56 0.35 0.36 0.35 1.00 0.48 0.46 0.44 0.21 0.21 0.19 0.22
U2 CH 0.35 0.38 0.31 0.26 0.38 0.51 0.26 0.32 0.48 1.00 0.32 0.38 0.24 0.18 0.15 0.22
L1 CH 0.35 0.23 0.48 0.44 0.26 0.23 0.67 0.62 0.46 0.32 1.00 0.77 0.10 0.13 0.28 0.40
L2 CH 0.39 0.32 0.42 0.43 0.33 0.32 0.59 0.67 0.44 0.38 0.77 1.00 0.19 0.22 0.31 0.35
U1 RL 0.21 0.19 0.13 0.11 0.93 0.64 0.45 0.45 0.21 0.24 0.10 0.19 1.00 0.63 0.51 0.48
U2 RL 0.23 0.23 0.14 0.11 0.62 0.94 0.51 0.48 0.21 0.18 0.13 0.22 0.63 1.00 0.58 0.50
L1 RL 0.35 0.11 0.34 0.23 0.51 0.56 0.90 0.78 0.19 0.15 0.28 0.31 0.51 0.58 1.00 0.82
L2 RL 0.36 0.11 0.34 0.27 0.49 0.51 0.82 0.93 0.22 0.22 0.40 0.35 0.48 0.50 0.82 1.00

1Variable codes are crown width (CW), tooth length (TL), crown height (CH), and root length (RL). Sample 
size was 148 individuals for all correlations, so coefficients above 0.16 are statistically significant (P < 0.05; 
Rohlf and Sokal, 1981).

TABLE 3. Results of principal components analysis on 16 
incisor dimensions, without rotation

 Eigenvectors
 Tooth I II III IV

Crown Width
 U1 0.061 0.044 0.038 0.177
 U2 0.038 -0.019 -0.010 0.198
 L1 0.034 0.048 0.029 0.112
 L2 0.028 0.042 0.029 0.116

Tooth Length
 U1 0.418 -0.405 0.497 0.108
 U2 0.382 -0.276 -0.535 0.248
 L1 0.367 0.409 0.027 0.000
 L2 0.371 0.423 0.073 0.065

Crown Height
 U1 0.083 -0.015 0.144 0.427
 U2 0.063 -0.026 0.006 0.313
 L1 0.087 0.182 0.094 0.361
 L2 0.086 0.121 0.063 0.330

Root Length
 U1 0.335 -0.390 0.353 -0.320
 U2 0.319 -0.250 -0.542 -0.065
 L1 0.280 0.228 -0.067 -0.361
 L2 0.285 0.302 0.010 -0.265

Eigenvalue 21.164 5.475 2.785 1.836

Percent 61.847 16.000 8.138 5.365

Cumulative
Percent 61.847 77.847 85.986 91.351

Fig. 1. Labial view of a maxillary right central incisor 
showing measurements of root length determined 
separately on the medial and lateral aspects (from root 
apex to CEJ) and tooth length (from root apex to midpoint 
of incisal edge).  Crown height was operationalized as 
tooth length minus root length (i.e., average of medial 
and lateral distances), which yields a longer root length 
(and shorter crown height) than if the labial or lingual 
level of the CEJ had been used.

CROWN AND ROOT SEXUAL DIMORPHISM

MedialLateral



90

significant sexual dimorphism (Table 1).  Percentage-
wise, mean size for males is only 1-2% larger than 
for females. The other crown dimension assessed 
here, crown height, comparably exhibits little sexual 
dimorphism. Just the mean size difference for U2 is 
significant statistically (a 4% difference), and crown 
heights of the mandibular incisors are virtually identical 
in the two sexes.

It seems noteworthy that overall tooth lengths of all 
four incisors are appreciably more dimorphic.  All four 
ANOVA tests are significant (Table 1).  Percent sexual 
dimorphism is lower but not trivial in the mandible 
(ca. 3%) and higher (ca. 5 to 8%) in the upper arch.  This 
greater sexual dimorphism likewise is reflected in the 
coefficients of determination (r2) that can be read as the 
percentage of the variation in tooth length accounted for 
in the statistical sense by “sex.”  Percentages are lower 
for the two mandibular incisor types than in the maxilla, 
or, perhaps more correctly, the maxillary lateral incisor 
tooth length is comparatively highly dimorphic (r2 = 
14%).

It is evident that tooth length is composed of crown 
height and root length and, since sex differences in 
crown height are minor, most of the dimorphism 
obviously is due to sex differences in root length (Table 
1). Indeed, sexual dimorphism in incisor root lengths 
is in the range of 5 to 8%, which is noticeably higher 
than for crown widths or heights. Also, unlike crown 
dimensions, percentage sex differences are not smaller 
for the mandibular root dimensions.

Crown-Root Ratios

Incisor crown-root ratios (Table 1) were here 
assessed for completeness. The ratio is simply crown 
height divided by root length, so the larger the ratio the 
more crown height contributes to overall tooth length. 
Ratios are 50% or less, showing that incisor root lengths 
characteristically are more than twice their crown 
heights. Mean crown-root ratios are slightly larger in 
the mandible because the mandibular root lengths are 
proportionately shorter.  Sexual dimorphism for these 
ratios is trivial in the maxillary incisors, whereas both 
tests are significant for the mandibular incisor types. 

These mandibular differences are due to longer roots 
in males (whereas the crown heights are very similar in 
men and women).

Correlation Matrix

Several studies have shown that tooth crown 
diameters are positively intercorrelated (reviewed, e.g., 
in Henderson, 1975), and Garn et al. (1978a) showed 
that root lengths within individuals likewise covary in 
a positive fashion.  These expectations are evident in the 
present data (Table 2) where all 120 pairwise correlations 
are positive and most are significantly different from 
zero statistically.  Given the uniform sample size of 148 
cases, correlations above 0.16 are significant (P < 0.05) 
and those above 0.21 are highly significant (P < 0.01).

Scanning the matrix, the weakest correlations 
are between crown widths and root lengths, and the 
strongest are between tooth lengths and root lengths.  
These latter are predictable, however, because root 
length is the major constituent of tooth length.  Pearson 
and Davin (1924; also see Solow, 1966) term these 
sorts of correlations of a dimension plus part of itself 
“spurious” in the sense that they are correlated simply 
because of their geometric association, which need not 
be biological.

Ideally, one would like to find statistically 
independent axes of variation so that the sexual 
dimorphism exhibited by some tooth dimensions is not 
duplicative of that of other dimensions. Separate “axes” 
of variation would provide greater statistical power for 
discriminating between the sexes using multiple tooth 
dimensions. Given the consistently positive, generally 
high correlations here (Table 2) suggests that there is 
effectively just a single statistical (and, by inference, 
biological) axis of sexual dimorphism.

Principal Components Analysis

PCA (Gorsuch, 1983) was used to assess the 
relationships among the crown and root dimensions.  
Four dimensions for each of the four incisor tooth types 
were used in the analysis, namely (1) crown width, (2) 
tooth length, (3) crown height, and (4) root length.  Four 
components were extracted with eigenvalues exceeding 

TABLE 4. Descriptive statistics for the principal components scores and tests for sexual dimorphism1

 Males Females Adjusted Analysis of Variance
 Axis n x  sd sem n x  sd sem r2 % F-ratio P value

 PC I 54 1.582 4.886 0.665 89 -0.960 4.160 0.441 6.563 10.97 0.0012
 PC II 54 -0.136 2.537 0.345 89 0.082 2.223 0.236 (-0.503)# 0.29 0.5912
 PC III 54 -0.152 1.792 0.244 89 0.092 1.593 0.169 (-0.198)# 0.72 0.3977
 PC IV 54 -0.195 1.446 0.197 89 0.118 1.291 0.137 0.562 1.80 0.1815

1Variable  codes are principal component scores for axes I through IV.
#The r2 is close to zero, and the adjustment caused the estimate to be negative, though this has no statistical inter-
pretation (and should be set to zero).

E. F. HARRIS AND W. M. COUCH



91

U
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PC I

PC II

PC III

PC IV

Fig. 2. Plots of the variable weights on the first four principal components extracted from the covariance matrix 
of 16 crown and root dimensions.  These “weights” of variables with each canonical axis can be interpreted as the 
correlation coefficient of the variables with the axis.

CROWN AND ROOT SEXUAL DIMORPHISM



92

one (Kaiser, 1970), and these were evaluated without 
matrix rotation (Table 3).  These four axes account for 
most (91%) of the variation, and, within these, just 
the first axis is responsible for most (62%) of the total 
variance.

PC I is controlled by tooth length, with slightly higher 
weightings on the two maxillary dimensions (Fig. 2).  
Probably because root lengths are major constituents of 
tooth length (Fig. 1), root lengths also have comparatively 
high weights on this component.

PC II reflects the high loadings of tooth lengths and 
root lengths, but here there are polarities (opposite 
signs) for variables in the maxilla and the mandible.  
As with the first component, crown widths and heights 
have only minor loadings (correlation coefficients) with 
PC II.

PC III is a further orthogonal axis of variation for root 
length and, by association, tooth length.  Here just the 
maxillary variables exhibit high loadings, with polarities 
between the central and lateral incisors.  In other words, 
having accounted for the variances of PC I and II, the 

remaining major axis of variation is a contrast between 
root lengths of the two maxillary incisor types.

Highly weighted variables for PC IV are restricted 
to crown heights and root lengths (Fig. 2).  Within a 
variable (crown height or root length), all four weights 
are of the same sign.

When tested for sexual dimorphism (Table 4), PC 
I scores, which depend primarily on root lengths, are 
highly significant. In contrast, none of the other three 
axes seems to be of any value for sex discrimination.

Discriminant Analysis

When the eight crown size variables (4 widths, 4 
heights) were subjected to stepwise linear discriminant 
function analysis, just one variable—crown width of 
U1—was significantly predictive. Correct allocation 
was 47% overall, though somewhat higher in girls (56%) 
than boys (37%).

When the other eight variables were analyzed (4 
tooth lengths, 4 root lengths), again there was just 
one significant predictor because of the considerable 

0.00

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51 (56%) correctly assigned

57 males
21 (37%) correctly assigned

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91 females
58 (64%) correctly assigned

57 males
31 (54%) correctly assigned

Maxillary I1 Crown Width

Mandibular I1 Root Length

Fig. 3. Sequenced arrays of the probabilities of group assignment. Probabilities above 50% are the cases correctly 
assigned; cases with probabilities below 50% were allocated to the wrong sex.  The height of the symbol above the 
0.5 line is a measure of how confident the researcher can be that the case is correctly classified. The shallow slop 
of the distributions illustrates the weak sexual dimorphism even of these selected variables. Top. Arrays using U1 
crown width, which is the one statistically significant crown size predictor of sex from among the 8 tested. Bottom. 
Arrays using mandibular I1 root length, which is the one significant root size predictor of sex in this sample from 
among the 8 tested.

E. F. HARRIS AND W. M. COUCH



93

statistical redundancy of these dimensions. Here, 
mandibular central incisor (L1) root length was most 
discriminating, with 60% correct assignment (54% for 
males; 64% for females). This is an improvement over 
using crown widths alone, but the increase in correct 
assignment (60% vs. 49%) is modest. One can see from the 
very gradual slope of probabilities of correct assignment 
(Fig. 3) that there is considerable overlap in crown and 
in root dimensions between the two sexes.

We supposed that there would be enough statistical 
independence between crown and root dimensions 
that they could be used in combination to improve sex 
determination. This was not the case.  Once the greater 
dimorphism of root length was entered (specifically, 
inclusion of L1 root length at step 1) and statistics of 
the other variables were adjusted to account for root 
length, none of the other dimensions had significant 
independent power to be added.  With hindsight, this is 
because all 16 of the variables studied here are positively 
intercorrelated, and even the weakest associations 
(between crown widths and root lengths) are still on the 
order of 0.1 to 0.2.

DISCUSSION

Tooth root size and morphology have been studied far 
less than crown size (e.g., Kovacs, 1971; Thomas, 1995), 
largely because of their inaccessibility and, additionally, 
in archeological specimens, their comparative fragility.  
So too, little is known about the genetic control of root 
size and morphology.  Most root formation occurs 
prior to tooth emergence (Carlson, 1944), which may 
be protective against forces of mastication until teeth 
are in function.  Unlike enamel, a root’s configuration 
is subject to surface remodeling. Root resorption can 
be instigated with orthodontic forces (Harris, 2000) or 
with jiggling forces that are common consequences of 
pathological loss of supporting crestal bone (Nyman et 
al., 1978; Harris et al., 1993).

The accretion of cementum, in contrast, increases 
root dimensions in an age-progressive manner (Wittwer-
Backofen et al., 2004), though the annual depositions 
are too small to be visualized on conventional 
radiographs. Cementum accumulation typically is 
thickest in the bifurcations of multirooted teeth, though 
hypercementosis occasionally occurs periapically (e.g., 
Halstead and Hoard, 1991).

The normal age-progressive periapical accumulation 
of cementum needs to be studied in more detail; 
researchers have reported on an increase in root 
length—supposedly by cementum apposition—as an 
age-progressive event.  Most such studies have been 
cross-sectional (Levers and Darling, 1983; Whittaker et 
al., 1990), though there is some longitudinal evidence for 
root lengthening with age (Bishara et al., 1999).

The prime focus in the present study was to test 
whether root lengths exhibit greater sexual dimorphism 
than crown dimensions, where sex differences are too 

subtle to be definitive in most cases (Ditch and Rose, 
1972; Kieser and Groeneveld, 1989).  Precisely because 
sexual dimorphism is modest in humans, most studies 
that have developed discriminant functions capitalize on 
sex differences specific to their own sample; applications 
to other groups generally exhibit much weaker 
frequencies of correct sex assignment.  The problem is 
intrinsic to the crown size data, not to sophistication 
of the statistical techniques.  There are two synergistic 
problems, (1) there is little sexual dimorphism (the 
canines, especially buccolingually, seem to be the most 
dimorphic; Sciulli et al., 1977) and (2) even though 
teeth are numerous within a person, crown sizes all are 
significantly, positively intercorrelated, so there are few 
axes of novel information to exploit (e.g., Moorrees and 
Reed, 1964; Potter et al., 1968; Harris and Bailit, 1988); 
the sexual dimorphism seen among crown dimensions 
is statistically redundant.

These observations seem to have motivated Garn and 
coworkers (1979) and others to look for independent axes 
of variation.  Tooth roots seem to offer two advantages 
here:  (1) the dimensions are at least partially uncoupled 
from crown size (Fig. 2), so the data are not repetitive 
(statistically redundant) with crown dimensions, and 
(2) root lengths are a bit more dimorphic than crown 
dimensions (Table 1).

The present study has clear precedents in the work 
of Stanley Garn and colleagues (1978a,b, 1979) who 
measured root lengths in a sample of living American 
white teenagers using 45° oblique-jaw radiographs.  
They measured five mandibular tooth types (C, P1, P2, 
M1, M2) omitting the incisors that are distorted in this 
radiographic view.  While their methodological details 
differ from ours, there are some key similarities.  One, 
we examined different teeth than Garn’s group, but our 
intertooth correlations (Table 2) for tooth lengths are in 
the same range, about 0.5 to 0.6, and the correlations 
within an arch are higher than between arches.  Two, 
the correlations between crown size (here we tested 
mesiodistal incisor crown widths) and root lengths 
are low (ca. 0.1 to 0.2) but consistently positive.  Garn 
et al. (1978b) found the same low level of crown-root 
integration.

Garn and coworkers (1979) tested the sex 
discriminatory power of numerous combinations of 
crown and root dimensions.  Scrutiny of their presentation 
shows, however, that they made no effort to show that 
each variable in each discriminant function contributed 
significant statistically information.  Alternatively, the 
simple addition of more variables typically will improve 
discrimination of individuals in the sample used to 
generate the formulae (discriminant functions) because 
using more variables capitalizes on variation unique to 
that sample.  Unfortunately, amassing variables (1) does 
not improve the statistical significance of the predictive 
equation and (2) detracts from the generalizability of the 
results to other samples (Kieser and Groeneveld, 1989).  

CROWN AND ROOT SEXUAL DIMORPHISM



94

In other words, “percentage correct allocation” should 
not be the driving criterion for developing discriminant 
functions because that criterion commonly is specific to 
the sample used to develop the functions—that criterion 
promotes exploiting male-female differences specific to 
that sample, not to sex differences in size relationships 
at large.

Tooth roots serve several functions (Shafer et al., 
1983), including the important function of transmitting 
the forces of occlusion to the supporting alveolar bone.  
Given the significantly larger bite forces in males than 
females, especially after the onset of puberty (e.g., Bakke 
et al., 1990; Julien et al., 1996), the tendency for larger 
roots (with larger surface areas) in men probably is 
adaptive.  As Garn noted (1978b, p 636):

It is impressive that the crowns of permanent 
teeth that begin to form by the second trimester 
of prenatal life and that complete their size-
attainment in the second to fifth year of postnatal 
life thus “anticipate” the length of still-to-be-
completed roots by 10 years or more.

CONCLUSIONS

This study of incisor crown-root dimensions in 
a contemporary American white sample shows that 
root lengths are somewhat more sexually dimorphic 
than crown dimensions and, thus, are somewhat more 
useful for sex determination.  The statistical associations 
are higher among crown dimensions than between 
crowns and roots, but all correlations are positive.  
Our discriminant function analysis (that relied just on 
incisor tooth types) does not support the supposition 
that combinations of crown and root dimensions are any 
more useful for sex determination than root dimensions 
alone—because the dimensions all seem to reflect the 
same statistical information.  Perhaps the use of more 
tooth types, notably the canine, would somewhat 
improve correct sex assignment from tooth dimensions.

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