Background
In animal studies of the effects of hormonally active agents, measurement of anogenital distance (AGD) is now routine
Although measurement of AGD in humans has been discussed in the literature
Methods
Subjects
A cross-sectional study was conducted among the newborn children of women admitted for delivery to the Dr. Ernesto Meana San Román General Hospital in Jojutla, Morelos, Mexico, in 1999. This hospital provides medical care to low socioeconomic status and uninsured populations. The study included 87 newborn infants, none of whom had congenital defects or had been admitted to the neonatal intensive care unit. All infants were born at term (≥38 weeks gestation), except for one (32 weeks). The infants were of both sexes and were born after spontaneous cephalic delivery or caesarean section. Within 6 hours of birth, a structured questionnaire about family background and obstetric history was administered to the mothers, and anthropometric measurements were taken on the newborns.
Anthropometry
Anthropometric measurements were taken of weight, length, head circumference, and AGD. AGD was measured as follows: the newborn infant was in the dorsal decubitus position; both hips were flexed and light pressure was exerted on the infant's thighs until the examiner's hand touched the subject's abdomen. Measurements were made with Vernier calipers. Distance was measured from the center of the anus to the posterior convergence of the fourchette (where the vestibule begins) in female infants
Schematic Diagram of Measurements Done, by Sex
Schematic Diagram of Measurements Done, by Sex
Reliability
Before any contact with the 87 subjects in the main study, the personnel performing the anthropometry examined 20 other neonates; all of whom were born after ≥38 weeks gestation. In this standardization training, 7 female infants and 13 male infants were measured twice by each observer. A sufficient time interval (30 minutes) was allotted between each measurement so that the second would not be influenced by the observer's memory of the first. These data were used to examine the reliability of measures and sources of variance.
Statistical analysis
The reliability of the anthropometric measures was calculated as the Pearson correlation coefficient between the paired measures. The observations taken by the two observers were not statistically different when compared using a paired t-test (results not shown). Analysis of variance (ANOVA) with a random effect term for subject was used to estimate between-subject, between-observer, and within-observer components of variance, by sex.
For the main study, a linear regression analysis was used to evaluate birth weight, birth length, and gestational age as predictors of AGD. Age of the mother, number of pregnancies, and time elapsed between birth and measurement were not important predictors (or confounders) of AGD in univariate or multivariate models and were not considered further in the analysis. To examine influential values and the overall fit of the model, we conducted an analysis of residuals, but found nothing of note.
The protocol was approved by human subjects committees at the National Institute of Public Health in Mexico and the National Institute of Environmental Health Sciences in the U.S.
Results
Among the 20 subjects in the standardization exercise, the between-subject coefficient of variation was greater for measures of AGD in females than for the other measures (Table
Mean, coefficient of variation (CV), and reliability of anthropometric measurements in 20 newbornsa
Measurement
Mean
CV
Reliability
Weight (kg)
3.01
0.13
1.00
Length (cm)
48.9
0.03
0.97
Head Circumference (cm)
34.2
0.03
0.98
Anogenital distance
18
0.31
0.91
Female
11
0.27
0.50
Male
21
0.09
0.64
a 7 females and 13 males.
Among the 87 subjects in the main study, the birth weight, length, and head circumference were as expected in a population from southern Mexico (Table
Distribution of selected characteristics in 87 newborns, Mexico, 1999a
Variable
Female n = 42
Male n = 45
Anogenital distance (mm)
Mean
11
21
SD
2
3
Median
11
22
25th percentile
10
20
75th percentile
11
23
Weight (g)
Mean
3070
3060
SD
408
440
Median
3060
3110
25th percentile
2870
2800
75th percentile
3310
3290
Length (cm)
Mean
48.6
48.7
SD
1.4
2.2
Median
48.6
48.7
25th percentile
47.5
48.0
75th percentile
49.6
49.9
Head circumference (cm)
Mean
337
341
SD
10.9
16.7
Median
337
341
25th percentile
330
334
75th percentile
345
350
aSD, standard deviation
Distribution of Anogenital Distance (AGD), by Sex
Distribution of Anogenital Distance (AGD), by Sex
In the crude models of AGD in females, weight, length, and gestational age all appeared to be predictive (Table
Regression coefficients for anogenital distance as a function of characteristics at birth, femalesa
Variable
Crude
Adjustedb
Coefficient
95%
CI
R2
Coefficient
95%
CI
R2
Birth weight
0.002
0.002
0.003
0.000
0.41
0.002c
0.001
0.003
0.000
0.43
Birth length
0.319
-0.005
0.642
0.061
0.09
0.141c
-0.189
0.471
0.407
0.22
Gestational age
1.296
0.516
2.076
0.002
0.21
0.501d
-0.282
1.283
0.217
0.43
aUnits for regression coefficients are mm of AGD per unit characteristic (g, cm, or weeks). Results based on 42 females. CI, confidence interval.
b Multivariate adjusted regression coefficients (adjustment factors listed below).
c Adjusted for gestational age.
d Adjusted for weight of newborn infant.
Regression coefficients for anogenital distance as a function of characteristics at birth, malesa
Variable
Crude
Adjustedb
Coefficient
95%
CI
R2
Coefficient
95%
CI
R2
Birth weight
0.003
0.001
0.005
0.001
0.23
0.004c
0.002
0.006
0.001
0.27
Birth length
0.671
0.348
0.995
0.000
0.28
0.914c
0.499
1.329
0.000
0.33
Gestational age
0.356
-0.258
0.971
0.262
0.03
-0.560d
-1.284
0.165
0.137
0.27
aUnits for regression coefficients are mm of AGD per unit characteristic (g, cm, or weeks). Results based on 45 males. CI, confidence interval.
b Multivariate adjusted regression coefficients (adjustment factors listed below).
c Adjusted for gestational age.
d Adjusted for weight of newborn infant.
Discussion
The AGD measures employed in the present study reflect the location of the caudal border of the genital swelling, an embryologic structure that differentiates into the labia majora in females and the scrotum in males. After the indifferent stage of the external genitalia, the critical events determining the sexual dimorphism of AGD in humans begin when, relative to the anus, the genital swelling, urethral folds, and possibly the genital tubercle, move ventrally under the influence of androgens
Direct comparison of our results with those in the two other studies with measures of anus-to-fourchette (AF) distance in female newborns
Compared with established anthropometric measures on newborns, the reliability of the AGD measures were lower. The lower reliability of the AGD measures is likely due to several factors. The AGD measures depend on indistinct landmarks on soft tissues. Structures such as "the center of the anus" or the posterior fourchette are not clearly demarcated. Any slight traction or pressure applied to the perineum or surrounding structures could alter measures. Finally, compared with established anthropometric measures on newborns, the AGD dimensions are smaller, thus measures done with the naked eye on a subject unlikely to hold still are inherently at a disadvantage. Use of two observers, one to restrain the subject and one to do the measurements could result in improved reliability compared to our approach, which employed one observer.
Compared with adult humans, the size of the genitals at birth is large relative to the body overall
A complete assessment of AGD in humans would include more measurements than were done in our study. In neonatal rodents, measurement of AGD is relatively straightforward and is the distance from the genital tubercle to the anus. In older animals or humans of any age, however, questions arise as to which measure is most informative. For example, in human males, rather than a genital tubercle, the presence of the phallus and testicles at birth means that a number of measurements are possible. The measurement in the present study, from the posterior scrotal-perineal junction, represents only one such measurement. Ideally we would have done genital tubercle measurements in males and females, but we did not. Whether sexual dimorphism exists in the distance from the anus to the genital tubule (penile base in males) would be useful to know. While one might expect that penile length may be a good measure of androgenization among males, difficulties obtaining a reliable measure mean that alternative measures, such as AGD, are worth investigating.
Effects of endocrinopathies on AGD in humans have been described, but only to a limited degree. A rare form of congenital adrenal hyperplasia that causes incomplete masculine development has been reported to cause decreased AGD in boys
The purported mechanism by which androgens increase AGD in females is by inducing "labioscrotal fusion" (in normal males fusion begins caudally and proceeds ventrally, presumably androgens in females act the same way)
Conclusions
In summary, we have shown that an aspect of genital dimension that reflects migration of the genital swelling is sexually dimorphic in humans. Whether this particular measure, or other measures of AGD in humans, has any utility as markers of exposure
Abbreviations
AF: anus-fourchette
AGD: anogential distance
ANOVA: analysis of variance
CI: confidence interval
Competing interests
None declared.
Authors' contributions
ES participated in the design of the study, carried out the measurements, and wrote the first draft of the manuscript. PR participated in the study coordination and data management. EY carried out and coordinated the measurements. ML originated the idea that AGD measurements in human males may be useful, revised the manuscript, and analyzed the data. MH conceived of the study and participated in its design and coordination. All authors read and approved the final manuscript.