Lower-Extremity Rotational Problems in Children - The Journal of ...

ABSTRACT: We studied 1,000 normal lower extrem 

ities of children and adults in order to establish normal 

values for the rotational profile. The intrauterine posi 

tion of the fetus molds the femur by rotating it laterally 

and molds the tibia by rotating it medially These mold 

ing effects usually resolve spontaneously during infancy, 

and then genetically 

are unmasked. 

determined individual differences 

Rotational prob'ems should be clinically evaluated 

and the findings compared with the normal values pro 

vided by this study. Out-toeing in infants, medial tibial 

torsion in toddlers, and medial femoral torsion in young 

children are extremes of a normal developmental pat 

tern In the vast majority, these rotational variations fall 

within the broad range of normal and require no treat 

ment. 

Variations and deformities ofthe lower limbs involving 

rotation in the transverse plane are associated with many 

clinical problems. ranging from harmless in-toeing in chil 

dren to disabling osteoarthritis of the hip in adult pa 

tients''2'2t3435. 

In the past. rotational problems in the transverse plane 

have often been ignored because they are difficult to assess. 

This is in contrast to frontal-plane and sagittal-plane de 

formities. which are easily visualized and measured on con 

ventional radiographs. These difficulties in assessment have 

led to varied opinions and controversy regarding the eval 

uation and management of rotational problems. These prob 

hems are likely to attract increasing attention because 

accurate assessment is now possible using computerized 

transverse-plane tomography and optical and electronic 

techniques of motion analysis. 

For routine clinical evaluation, physical examination 

remains the primary method for assessment. To be useful, 

this examination must include measurements of each limb 

segment and give acceptably reproducible results that can 

be compared with an established range of normal values. 

However, previous studies have failed to meet these require 

ments@794SR222327333. 

The present investigation was designed to establish 

normal values for the rotational profile29 by studying I .000 

* Department of Orthopedics. Childrens Orthopedic Hospital and 

Medical Center, P.O. Box C537l. Seattle. Washington 98105. 

1@Department of Orthopedics. University of Washington School of 

Medicine. 1959 N.E. Pacific Street. Seattle, Washington 98105. 

Copyright 1985 by The Journal of Bone and Joint Surgery. Itmcorporated 

lower limbs of normal subjects of varying ages. Given this 

information, the clinician could manage the comtiion ro 

tational problems of childhood with more objectivity . and 

could quantitatively document deformity in the transverse 

plane when treating serious problems such as congenital 

dysplasia ofthe hip. club foot. and neuromuscular disorders. 

In this study. we have used the terniinology recoin 

mended by the Pediatric Orthopaedic Society1. Normal is 

defined as that which occurs within two standard deviations 

of the mean. Rotational problems with values within the 

normal range are termed rotational variations' 

outside the normal range are referred to as @torsional de 

formities''. 

@ and those 

VOL. 67-A, NO. I. JANUARY 1985 

Lower-Extremity Rotational Problems in Children 

NORMAL. VALUES TO GUIDE MANAGEMENT 

BY LYNN T. STAHELI, M.D.*, MARILYN (ORBETT, B.S.t. CRAIG WYSS. P11.1).1', AND 

HOWARD KING. M.D.t, SEATTLE. WASHINGTON 

!@?Ofli the Deporttnetmt of Oit/iopedie.s. CImi/dre,is ()ii/mopedi Hospital iou! ,%1('(/i((,I Center. Seattle 

Materials and Methods 

The I .000 limbs included in this study were both lower 

extremities ofSOO subjects (279 female and 221 male rang 

ing in age from less than one year to seventy years (Fig. 

1). These subjects were white and had no history of mus 

culoskeletal abnormality. They were selected from hospital 

personnel and siblings of children seen in non-orthopaedic 

outpatient clinics. 

The 500 subjects were divided into twenty-two groups 

based on chronological age (Fig. I ). The first group Colli 

prised infants who were less than one year old. Subjects 

aged one through fourteen were divided into fourteen 

groups, one for each chronological year; that is. one-year 

olds, two-year-olds. and so on. Subjects fifteen through 

nineteen years old comprised @henext group. while those 

between twenty and sixty-nine years old were divided into 

five groups, one for each decade. The final group comprised 

individuals aged seventy and older. The number of limbs 

in each group ranged from eighteen to ninety-eight (average. 

forty-five). 

The average for both limbs fc'r each subject was used 

in all measurements. One of us (M. C.) made the following 

measurements on each of the 500 subjects. 

Foot-progression angle: This was defined as the an 

gular difference between the long axis of the foot and the 

line of progression. In order to assess it, the subjects dusted 

their feet with chalk and then walked across the study area 

on a long strip of paper. We measured the angles of six 

footprints (three from each limb) and recorded the average 

for each subject. A plus sign denoted an out-toeing angle 

and a minus sign. an in-toeing angle. Infants were not inca 

sured for foot-progression angle. 

39

40 I.. T. STAEIII.I, MARIlYN (ORBETT. (â€˜RAft;WYSS. AND HOWARD KIN(I 

RI) 

C 

a 

0 

0 

.0 E 

C 

50 

25 

0 

(n500) 

.5 1 2 3 4 5 6 7 8 9 10 11 12 131415- 203040506070 

19 

years of age 

Fi. I 

Distribution of suh@ects according to the twenty-two age groups studied. Forty-etght subjects soere less than one year old: elesen. one to tsoo years 

old: twenty-tour. two) to three @earsold: and 50)Ofl. There were ut) subjects between sixteen and tssemty sears old in the soad@ population. Subjects 

who were more than twenty years old were divided into) six ten-year age groups. as shown. 

Hip rotation: This was measured with the patient prone 

and the knees flexed to 90 degrees. With the pelvis level. 

the thighs were rotated to the angle that would be maintained 

by gravity alone. We photographically recorded the posi 

Lions of the legs using a camera located distally and directed 

cephalad in line with the axes of the thighs. Medial and 

lateral rotations were measured with a goniometer on an 

eight by ten-inch (twenty by twenty-five-centimeter) neg 

ative image projected by a photographic enlarger. 

Thighâ€”footci@igle(1,1(1(lFli,'/@? (.)f the lraFl.vtnalleol(ir a.vis: 

These were used to determine transverse-plane rotational 

variations of the tibia and foot. They were measured with 

the subject prone. the knees flexed to 90 degrees. and the 

ankles in neutral position. The center point ofeach malleolus 

was marked, and these points were joined by a line across 

the plantar aspect of the heel. This line was used to ap 

proximate the transmalleolar axis. A photograph was made 

with the camera positioned above each foot and aimed in 

line with the tibiae. The measurements made from the pro 

jected photographic negative were as follows: ( 1) thigh-foot 

angle â€”¿the angular difference between the axis of the foot 

and the axis of the thigh. and (2) angle of the transmalleolar 

axis â€”¿the angular difference between a line projected 

toward the heel at right angles to the transmalleolar axis 

and the axis of the thigh. In-toeing angles were given neg 

ative values and out-toeing angles. positive values. 

Intro -Examiner (111(1lizter-Exarni,u'r Variability 

Standard deviations and mean errors were computed 

to assess the intra-examiner and inter-examiner variabilities 

in the measurements of medial and lateral rotation of the 

hip. thigh-foot angle, and angle of the transnialleolar axis 

made on the photographic negatives and by direct clinical 

examination (Table I). 

Intra-examiner variability was assessed by one exam 

iner (a pre-medical student). who made photographic mea 

surements of three subjects (a twenty-seven-year-old man. 

a twenty-two-year-old man. and a forty-six-year-old worn 

an) on three separate occasions over a two-week period. 

The average standard deviations. in degrees. for the pho 

ErrorPhotographicMedial 

.48Lateral rotation3.812.652.07I 

rotation4.243.481.521.11Thigh-foot 

angle3.652%1.671.24Angle 

thetransmalleolar of 

16IClinical*Medial axis4.073.222. 

rotation4.9))3.33Lateral 

rotation5.814.50Thigh-foot 

angle6.31)5.02Angle 

thetransmalleolar of 

axis8.906.78 

TABL,F; I 

INTER-EXAMINER ANt) IN1RA-Ex.ASIINI:R \â€˜ARisitii iTtilS 

IN THE MEASUREMENTS (IN [)EaRI:rs 01 Mt:I)t.st 

AND LATERAl. ROTATION (IF TIlE Hip. TEIIGII.FooT AN(i I 

AND ANGIE OF THE TRANsSIAI,I.Ioi AR Axis 

Interâ€”Lx 

Standard Mean 

I)eviationaniinerErrorI 

ntraâ€”Ex 

Standard Meami 

I)eviation@initner 

* Intraâ€”examiner variability in clinical nieasuremcmits so as not loves 

tigated. 

tographic measurements were 2.07 for n@edialrotation. I .52 

for lateral rotation. 1.67 for thigh-foot angle. and 2. 16 for 

transmalleolar axis. The over-all average standard deviation. 

in degrees, for all measuretilents was I .86. The mean errors 

for these measurements were 1.48. 1.11. 1.24. and 1.56 

for medial and lateral rotation of the hip. thigh-foot angle. 

and angle of the transmalleolar axis. respectively. 

THE JOURNAL OF BONE AND JOINT SURGERY

Inter-examiner variability was assessed by six exam 

iners (the director of the orthopaedic departtiient. two or 

thopaedic residents. two medical students, and a pre 

medical student). Each of the six examiners measured the 

medial and lateral rotation of the hip. thigh-foot angle. and 

transmalleolar axis on the same three subjects (a twenty 

seven-month-old girl. an eleven-year-old boy. and a forty 

one-year-old woman). In addition, we compared the inca 

surements made on the photographic negatives and during 

20â€ 

@ ., 0 

100 

0 

@100 

0 

LOWER-EXTREMITY ROTATIONAl. PROBlEMS IN (IIII.I)REN 

0 

0 

0 

@ 0 

P@, 

0 

0 a 

the clinical examinations. Clinical measurements of rotation 

of the hip were made with a gravity goniometer. and the 

thigh-foot angle and transmalleolaraxis were measured with 

a protractor. The standard deviations and mean errors for 

the photographic and clinical measurements are shown in 

Table I. An F test of equality of variances of the photo 

graphic and clinical measurements showed no significant 

differences (p > 0.05). Thus. inter-examiner variabilities 

in the photographic and clinical measurements were similar. 

@ ,@bH@: 

@ 2SD 

@0 

Â±L. 

@ :@: . D 

0 0 

0 

0 

1 3 5 7 9 11 13 15-19 

a. 

0 

0 25D 

0 

0 0 Q â€˜¿I 

1 3 5 7 9 11 13 15-19 30's 50's 70+ 

0 

0 

a 

\ 

0 

30's 50's 70+ 

Figs. 2â€”Athrough 2â€”F:The five measurements plotted as the mean salites plus or tuititis Isoa stamdard deviations for each of the tsoentv-two age 

groups. The solid lines show the mean changes with age: the shaded areas. the miormualranges: the solid circles. the mueamimeasuremilents for the different 

age groups: and the open circles. plus or minus two standard deviations t@r the samiiemean miicasureniemits. 

Fig. 2-A: Foot-progression angle. 

80Â° 

60Â° 

40Â° 


0 

0 

Age (years) 

Fi. 2-A 

0@ 

0 

Age (years) 

Fii@.2-B 

Medial rotation of the hip in male subjects. 

0 

0 

0 

2 SD 

2 SD 

41

@ 

42 I.. T. STAFIELI. MARIlYN (ORBETI. (RAI(i WYSS, ANI) HOWARD KING 

Findings 

Data on male and female subjects were compared for 

each Of the five measurements: foot-progressIon angle. me 

dial and lateral rotation of the hip. thigh-foot angle. and 

angle of the transmalleolar axis. Medial rotation of the hip 

was significantly different (p < ().05 in male and female 

subjects. Therefore. separate graphs for medial rotation 

were prepared. one for each sex. For all other measurements 

there were fl() significant diftCrences (p > ().05 between 

80Â° 

@ 0 

T\ 

60Â° 

40Â° 

20Â° 

0 

100Â° 

80Â° 

60Â° 

40Â° 

20Â° 

0 

0 

0 

0 

0 

a 

a 0 

@ 0 

0 

0 

3 

0 

00 

@0 

0 

a 

0 

0 

male and female subjects. and their data were pooled for 

analysis. 

For each of the twenty-two age groups we computed 

the mean and standard deviation of each of the measure 

ments. These calculations were plotted on graphs (Figs. 

2-A through 2-F) showing the means and the points for plus 

and minus two standard deviations as functions of the mean 

ages for the twenty-two groups. Smooth lines were drawn 

through the data points by computing quadratic functions 

using a non-linear least-squares fitting algorithm. 

0 

0 0 

a 0 

5 11 13 15-19 

Age (years) 

Fi( . 

Niedmal rotation oil the hip mifcmiiale suh@ects. 

O'9 

0 

3 5 7 9 11 13 15-19 30's 50's 70+ 

Age (years) 

Fi.. 2-I) 

I.ateral rotatiomi(if the limpin mii@mIe and femiialesubjects conibined 

0 

0 

0 

0 

a 

70+ 

2 SD 

2 SD 

2 SD 

THEJOURNALOF BONEANDJOINTSURGERY

@ 

@ 

LOWER-EXTREMITY ROTATIONAl. PROBLEMS IN (HII.DRIN 

Foot-progression angle (Fig. 2-A): This angle was 

greatest and most variable during infancy. During childhood 

and adult life it showed little change. with the mean re 

maining approximately + 10 degrees and the normal range 

being between â€”¿ 3 and + 20 degrees. 

Medicil rotation of the hip (Figs. 2-B and 2-C): Since 

medial rotation was greater in female than in male subjects 

by a mean difference of 7 degrees. separate graphs for the 

sexes were constructed. Medial rotation was greatest in early 

childhood and then declined throughout later childhood and 

adulthood. From the middle of childhood on. for tiiale sub 

jects the mean was about 50 degrees and the normal range 

0 

0 

0 

was from 25 to 65 degrees. For female subjects the mean 

was about 40 degrees and the normal range was froni I5 to 

60 degrees. 

Lateral Fotatioll @?tt11(' hi/) (Fig. 2â€”D): Unlike medial 

rotation, lateral rotation of the hip showed flO sex-related 

difference. so all values were pooled. Lateral rotation was 

greatest during infancy. declined throughout childhood. and 

then remained relatively constant during adult IlIC. From 

the middle ofchildhood on. the mean was about 45 degrees 

and the normal range was from 25 to 65 degrees. 

Thigh-foot angle (Fig. 2-E): This angle increased and 

became less variable throughout childhood. From the middle 

0 

0 

0 0 

0 

0 

0 a 

2 SD 

40Â° 

20Â° 

-20Â° 

-40Â° 

0 

0 

3 5 7 9 11 13 15-19 30s 50s 70+ 

0 

0 

0 

Age (years) 

i) 

Ft(. 2-I: 

Thmiihâ€”fonitatigle. 

0 

Age (years) 

0 

Fmo. 2@F 

Angle of the transnial leolar axis. 

a 

0 

0 

0 0 

0 

0 

0 

@ 

@ 

0 

0 

0 

0 

0 

2 SD 

VOL.67-A,NO. I. JANUARY1985 

0 

0 

.0 

3 5 7 9 11 13 15-19 

rz. 

0 

0 

0 

â€˜¿I 

2 SD 

0 2SD 

43

@ 

44 L. T. STAHELI, MARILYN CORBETT, CRAIG WYSS, AND HOWARD KING 

ErrorPresent 

* Averages are in parentheses. 

Inter-ExaniinerIntra-ExaniinerStandardMeanStandard 

MeanL)eviationErrorDeviation 

studyPhotographic3.81-4.252.65-3.481.52-2.16 

1.11-1.56(3.941(3.081(l.86( 

(1.35)Clinical. 

investigated(6.481(4.911Other 

over-all4.9()-8.9()3.33-6.78Not 

studiesAshton 

1.70(hip)(8.40)Bocmne 

et al.6.01-I 

TABLE II 

RANGES AND AVERAGES* FOR INTER-EXAMINER AND INTRA-EXAMINER 

VARIABILITIES IN MEASUREMENT (IN DEGREES) DETERMINED IN THIS ANt) OTHER STUDIES 

.4(shoulder. and Aze&0.2-I 

.0)forearm. elbow .I I 

hip.knee. wrist. 

footBooneankle. 

al.1.5-4.60.6-1.4(shoulder. 

et 

elbow.(2.9)(1.0)wrist. 

knee.tOot)Ekstrand 

hip. 

al.'2.5-5.5(hip. et 

ankle)(3.7)Low knee. 

(elbow. wrist 14.4-7. 7 

(5.62)3.3-6.3 (4.6)0.69-3.69 

of childhood on, the mean angle remained approximately 

10 degrees and the range of normal values was from â€”¿ 5 

to 30 degrees. 

Angle of the transnialleolar O.V1S(Fig . 2-F): The angle 

of this axis increased and became slightly less variable with 

age. The mean angles and the normal ranges of the trans 

malleolar axis were greater than those of the thigh-foot 

angle. From the middle of childhood on. the mean approx 

imated 20 degrees and the ranges of normal were from zero 

to 45 degrees. 

Discussion 

As shown in Table II, the inter-examiner and intra 

examiner variabilities, standard deviations, and mean errors 

were used to compare the examiner variabilities in the cur 

rent study with the findings in other reliability studies'5 

The findings in our study compare favorably with the values 

reported in other studies (Table II). For the intra-examiner 

variabilities in the present study. the over-all average stan 

dard deviation was within the range of the average standard 

deviations in other studies ( 1.0 to 37)2.3.5.215The mean error 

values for these variabilities were also within the range of 

0.6 to 3.3 found in Low's study2. For the inter-examiner 

variabilities in the current study. the over-all standard de 

viations were within the range reported in other studies 

(over-all average standard deviations ranging from 2.9 to 

8.4)225. and the mean errors were within the range of 3.3 

to 6.3 reported by Low2. As would be expected, in the 

present study the inter-examiner variabilities were greater 

than the intra-examiner variabilities, a finding that was con 

sistent with those in previous studies22. 

Inter-examiner variabilities of the measurements that 

0.06-3.3 

(2.24) (1.9) 

were made on the photographs were similar to those of the 

measurements that were made during clinical examinations. 

Thus, similar accuracy of measurement can be obtained 

using either method. 

Foot-Progression Angle 

In the current study. the foot-progression angle varied 

with age (Fig. 2-A). In young children the mean was higher 

and the range was broader than in older children. This early 

relative out-toeing was apparently due to the greater lateral 

rotation of the hip in this age group. During adult life lateral 

rotation again occurred, presumably due to progressive loss 

of medial rotation of the hip. 

The data for the foot-progression angle in the current 

study were consistent with those in previous reports. Scrut 

ton and Robson, in their study of fifty normal children. 

found that in 94 per cent of the children who were one to 

three years old the mean was + 6 degrees and the range 

was from â€”¿ 5 to + 15 degrees. while in the children who 

were older than four the mean was 4 degrees and the range 

was from â€”¿ 2 to + 12 degrees. Eighteen per cent of these 

fifty children had in-toeing on one side27. Schwartz et al., 

in a study of adults. found that the mean was between 5 

and 9 degrees, with more out-toeing occurring in subjects 

who were more than sixty years old26. 

The foot-progression angle may be normal in patients 

with torsional deformity because medial femoral torsion is 

often associated with compensating lateral tibial torsion. 

This association was found by Fabry et al.75 in 30 per cent 

of the patients in their series and it was also found by 

Kobyhiansky et al.7 in their study ofdried 

from the same limbs. 

tibiae and femora 

THEJOURNALOF BONEANDJOINTSURGERY

Femur 

Our study showed that in early infancy lateral rotation 

of the femur is greater than medial rotation, but that with 

advancing age lateral rotation decreases while medial ro 

tation increases (Figs. 2-B. 2-C, and 2-D). The findings in 

this study were consistent with previous findings for mean 

values during childhood4Â°@53.15.25but in addition provided 

a range of normal values. This normal range is great at all 

ages. with the upper limit of medial rotation being about 

65 degrees in male subjects and 60 degrees in female sub 

jects (Figs. 2-B and 2-C). The lower limit of lateral rotation 

is about 25 degrees for both sexes. 

Severity of medial femoral torsion may be graded as 

follows: mild if medial rotation is between 70 and 80 degrees 

and lateral rotation is between 10 and 20 degrees (two or 

three standard deviations from the mean). moderate if me 

dial rotation is between 80 and 90 degrees and lateral ro 

tation is between zero and 10 degrees (three or four standard 

deviations), and severe if medial rotation is greater than 90 

degrees and no lateral rotation is possible (more than four 

standard deviations). The degree of joint laxity influences 

these values, and both medial rotation and lateral rotation 

will be increased in a child with joint laxity. 

The relationship between rotation of the hip and ra 

diographically measured femoral anteversion was studied 

by Staheli et al.32. A reasonable correlation was found, 

although other factors, such as acetabular inclination. can 

affect rotation of the hip. 

Tibia 

Tibial rotation is defined as the relationship beween 

the axis of rotation of the knee and the transmalleolar axis2'. 

In 1909. le Damany measured the rotation in 100 dried 

tibiae'1. In the newborn. the average angle of the trans 

malleolar axis was 4 degrees of medial rotation. Thereafter. 

lateral rotation gradually increased throughout childhood 

40e 

200 

0 

-20Â° 

-40Â° 


LOWER-EXTREMITY ROTATIONAl. PROBLEMS IN (I-IILDREN 45 

Ft;. 3 

until the mean rotation was 23 degrees of lateral rotation. 

with a range of zero to 40 degrees in @idults. 

Later studies confirmed this early work. Nachlas oh 

served that medial rotation of the tibia is common in the 

orangutan and gorilla. and suggested that medial tihial tor 

sion is an atavistic variation4. Hutter and Scott measured 

forty adult skeletons and found that the mean lateral tihial 

rotation was 21 degrees on the right and 19 degrees Ofl the 

leftâ€. They then studied fifty children, two to three years 

old, and found that 30 per cent had in-toeing. usually due 

to medial tibial torsion. The prevalence was 8 to 10 per cent 

in the five to seven-year age group and 8 to 9 per cent in 

early adolescence, with a nearly equal sex distribution. They 

also found that 3 per cent of 200 adults whom they studied 

showed persistence of significant medial torsion. hut this 

was not defined. They considered this to be a serious prob 

lem in about 1 per cent. 

Wynne-Davies. using a special caliper to measure tihial 

rotation in normal adults5@' found that it ranged froni zero 

to 40 degrees of lateral rotation. the mean being 20 degrees. 

Khermosh et al. studied tibial rotation in 230 children in 

infancy and early childhood and found that the mean lateral 

rotation was 2 degrees at birth and 10 degrees at the age of 

five years'4. Staheli and Engel used a caliper method to 

survey 160 normal children5. They found a gradual increase 

from 5 to 14 degrees of lateral rotation between the ages of 

one and thirteen years. while Ritter et al. found the increase 

to be from 4 degrees at birth to I 1 degrees at two years@. 

Malekafzali and Wood, in 200 adult subjects. found the 

normal range to be from 7 to 20 degrees of lateral rotation. 

with a mean of 14 degrees21. 

The current study demonstrated that the angle of the 

transmalleolar axis and the thigh-foot angle become pro 

gressively larger lateral angles throughout growth (Figs. 

2-E and 2-F). The findings relative to the angle of the trans 

malleolar axis were comparable with those found in other 

studies. From the middle of childhood through adult life. 

. . . 

1 3 5 7 9 11 13 15-19 30's 50's 

Age (years) 

Comiiparison of the angle of the transmalleolar axis ITMA) amidthe thigh-fiat angle (TFA). 

70+ 

IMA 

TFA

46 L. T. STAHELI, MARILYN CORBETT, CRAIG WYSS, AND HOWARD KING 

the normal range is from about zero to 45 degrees of lateral 

rotation, with a mean of 25 degrees. 

The thigh-foot angle is a composite measurement that 

reflects rotation of both the tibia and the hind part of the 

foot3 . This angle roughly parallels the angle of the trans 

malleolar axis, but its mean value is lower (Fig. 3). 

The thigh-foot angle is easier to measure than the angle 

of the transmalleolar axis and is the most practical mea 

surement of the usual torsional deformity. However, for 

more complex torsional deformities, such as the torsion 

associated with a club foot, measurements of both the trans 

malleolar axis and the thigh-foot angle are useful. These 

measurements clarify the anatomical location of the de 

formity. Thus, torsional deformity of the tibia is assessed 

by the angle of the transmalleolar axis; deformity of the 

hind part of the foot is assessed by the difference between 

the angle of the transmalleolar axis and the thigh-foot angle; 

a combined deformity of both the tibia and the hind part of 

the foot, by the thigh-foot angle; and finally, deformity of 

the middle and distal portions of the foot, by the difference 

between the clinical measurements ofthe hind and fore parts 

of the foot. 

Foot 

Deformities of the foot were not assessed in this study. 

The most common foot deformities affecting the rotational 

profile are metatarsus adductus producing in-toeing and the 

hypermobile flat foot producing out-toeing. 

Lateral rotation caused by eversion of the foot is see 

ondary to joint laxity or muscle imbalance. Such foot de 

formities are detectable during the physical examination and 

should be the last entries in the rotational profile. 

Conclusions 

During infancy. the rotational profile appears to be 

References 

influenced by the effects of intrauterine molding. The hips 

are flexed and laterally rotated in utero, resulting in greater 

lateral than medial rotation of the hips and femora. The feet 

are medially rotated, producing medial rotation of the tibia 

and sometimes metatarsus adductus. The spontaneous res 

olution of molding results in equalization of medial and 

lateral rotation of the hip, lateral rotation of the tibia, and 

decreasing variability in the foot-progression angle during 

the second year of life. 

Genetic factors effect the rotational profile during early 

childhood. Medial femoral torsion becomes evident at the 

age when medial rotation is greatest. Continued lateral ro 

tation of the tibia corrects residual medial tibial-torsion an 

gulation. 

During late childhood, medial rotation of the hip di 

minishes, correcting in-toeing due to femoral torsion. Con 

tinued lateral rotation of the tibia, however, may aggravate 

a lateral tibial-torsion deformity. During adult years. the 

rotational profile is relatively constant except for medial 

rotation of the hip, which decreases, presumably due to a 

generalized loss of joint mobility with age. 

The graphs showing normal values for the rotational 

profile of the lower limbs will allow the clinician to deter 

mine the location and severity of torsional problems. In the 

past, many infants and children with normal rotational val 

ues were treated with splints. braces, exercises, or even 

surgery. 

Such treatment is both harmful to the child and ex 

pensive for the parents. 

In evaluating children with torsional deformity. the 

potential for long-term disability in the absence of treatment 

and the risks of treatment should be weighed. Non-operative 

treatments are usually ineffective. Rotational osteotomies 

of the femur or tibia are effective but are associated with 

significant complication rates. 

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Med. and Child Neurol. . 20: 87-94. 1978. 

2. BOONE. D. C. . and AZEN. S. P.: Normal Range of Motion of Joints in Male Subjects. J. Bone and Joint Surg. , 61-A: 756-759, July 1979. 

3. BooNE, D. C.: AZEN, S. P.: 

Ther.. 58: 1355-1360. 1978. 

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