SA Orthopaedic Journal  Summer 2016 | Vol 15 • No 4 Page 47

Clinical anatomy of the anterior 

cruciate ligament and pre-operative

prediction of ligament length
Mrs R van Zyl,1,2 MSc Anatomy

Dr A-N van Schoor,2 PhD Anatomy

Dr PJ du Toit,3 PhD Physiology

Dr EM Louw,4 PhD Statistics
1 Lecturer, Department of Basic Medical Sciences, School of Medicine, Faculty of Health Sciences, 

University of Free State, South Africa
2 Senior lecturer, Department of Anatomy, School of Medicine, Faculty of Health Sciences, University of Pretoria, South Africa

3 Professor, Department of Physiology, School of Medicine, Faculty of Health Sciences, 
Associate of the Institute for Food, Nutrition and Well-being, Associate of the Institute for Cellular and Molecular Medicine,

Associate of the Exercise Smart Team, University of Pretoria, South Africa
4 Senior lecturer, Department of Statistics, Faculty of Natural and Agricultural Sciences, University of Pretoria, South Africa

Corresponding author:
Mrs Reinette van Zyl

Department of Basic Medical Sciences (G25)
Faculty of Health Sciences

University of Free State
PO Box 339

Bloemfontein, 9300, 
South Africa. 

Tel: +27 (0)51 401 7362
Fax: +27 (0)51 401 9134

Email: ebersohnr@ufs.ac.za

Abstract

Background: Ligament grafts used in anterior cruciate ligament (ACL) reconstruction need to be the correct length
for proper functioning. If the graft length is incorrect, the patient could risk knee instability, loss of range of motion,
or failure of graft fixation. Easier and time-efficient reconstruction will be facilitated if the length of the ACL is
predicted in advance. 

Apart from examining the morphological properties of the ACL, this study aimed to determine whether the
epicondylar width of an individual can be used to predict ACL length and thereby assist in restoring the normal
anatomy of the ACL.

Methods: Ninety-one adult cadavers were studied. Patellar ligament (PL) length, ACL length, ACL width and the
maximum femoral epicondylar width (FECW) were measured. 

Results: The morphology of the ACL and PL was determined. The results revealed that FECW was the most
reliable predictor of ACL length. A linear regression formula was developed in order to determine ACL length by
measuring maximum FECW.

Conclusions: ACL and PL morphology compared well with the results found in previous studies. An individual’s
FECW can be used to predict ACL length pre-operatively. These results could improve pre-operative planning of
ACL reconstruction.

Key words: anterior cruciate ligament, femoral epicondyles, ligament graft, reconstruction

http://dx.doi.org/10.17159/2309-8309/2016/v15n4a7

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Results

All data were symmetrically distributed. The descriptive
analysis results are shown in Table I. The Pearson’s corre-
lation coefficient results can be seen in Table II. The
Pearson’s correlation coefficient r-value was determined
to suggest which of the four independent variables
demonstrated a significant positive or negative linear
relationship with the dependent variable, ACL length.
(Table II). If the p-value of the Pearson’s correlation coeffi-
cient test was p<0.05, it was considered as a statistically
significant correlation.

Statistical inference followed after the completion of the
descriptive statistics in order to predict ACL length. By
means of backward elimination using a multiple
regression model, it was observed that both height and
FECW had a statistically significant correlation to ACL
length. However, FECW was a more reliable predictor for
estimating ACL length than height (r=0.36 against r=0.31,
respectively). On the basis of this estimation, no additional
variables were used to compile an equation for pre-
operative ligament length estimation. 

A linear regression formula was developed for
predicting ACL length and, therefore, optimum final graft
length to re-establish the intra-articular length of the torn
ACL. The following equation (Equation 1) can be used to
predict ACL length by measuring the maximum FECW: 

ACL length = 0.25 (FECW) + 11.18 (1)
where ACL=anterior cruciate ligament;
FECW=femoral epicondylar width

Discussion

The mismatch of grafts can be minimised by more accurate
prediction of ACL intra-articular length and the required
graft length for ACL reconstruction. The first aim of this
study was to determine the morphology of the ACL and
PL. This study has shown that the mean intra-articular
ACL length of this sample was 32.4 mm, with a range
between 22.9 and 45.1 mm. The literature has shown
different results for the mean length of the ACL, namely:
20 mm,24 31 mm,25 32 mm,5,7,9 38 mm,8 and 39 mm.26 The
ACL length has exhibited some variability, with reported
ranges of 20–25 mm,13 22–41 mm,9 22–44 mm,7 25–35 mm,25

and 37–41 mm.26 The mean width of the ACL calculated in
the current study was 8.2 mm, ranging from 5.1–13.7 mm.
This measurement differs slightly from the range of 7–12
mm as determined by Bicer et al.,7 Zantop et al.5 and
Odensten and Gillquist.25 Previous authors found the ACL
to have a mean width of 10 mm25 and 11 mm.8

The PL mean length of this sample was 45.7 mm, ranging
between 31.6 mm and 59.2 mm. These measurements were
similar to results from previous studies: Brown et al.13

recorded a range of 45–50 mm and Denti et al.24 a mean
length of 45.5 mm. On average, the PL is 14 mm longer
than the ACL in this study and is therefore sufficient 
in length to allow effective fixation of the graft. 

Variation in PL length could explain the occurrence of
graft mismatch found with ACL reconstructive surgery.
Lastly, the slight differences between both the ACL and PL
measurements from this sample and other reported
measurements could be attributed to the respective
population differences of the samples studies. The
comparisons were made between the current sample
(South African), an Italian sample24 and a North American
sample.13 The measuring technique used could also
account for the dissimilarities found among the studies
referred to by Brown et al.13 and Denti et al.24

ACL length and PL length demonstrated no significant
statistical correlation (p=0.92), as was the case between
ACL length and ACL width (p=0.26). The significant corre-
lation between ACL length and height (p=0.01) was not
unexpected. Brown et al.13 in 2007 found a strong corre-
lation on a large magnetic resonance imaging (MRI) study
sample consisting of 414 knees, and concluded that patient
height can predict the required length of the BTB graft
used for ACL reconstruction. In contrast, Denti and co-
workers,24 using 50 reconstructed and nine cadaver knees,
were unable to confirm this relationship between ACL
length and patient height. ACL length and FECW revealed
a significant correlation of p<0.01 in this study. 

table i: Simple descriptive statistics of the patellar

ligament (PL) and anterior cruciate ligament (ACL)

length and the ACL width measurements 

Variables

PL length

(mm)

ACL length

(mm)

ACL width

(mm)

Mean 45.66 32.44 8.23

SD 5.71 4.06 1.96

Minimum 31.56 22.90 5.10

Maximum 59.17 45.10 13.74

ACL=anterior cruciate ligament; PL=patellar ligament; SD=standard deviation

table ii: Correlation matrix to indicate associations

between the dependent (ACL length) and independent

variables

Independent 

variables

ACL length

p-value r-value

Height .01a 0.31

PL length 0.92 0.01

FECW 0.00a 0.36

ACL width 0.26 0.14

a Statistically significant correlation
ACL=anterior cruciate ligament; FECW= femoral epicondylar width; PL=patellar
ligament

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SA Orthopaedic Journal  Summer 2016 | Vol 15 • No 4 Page 51

It was also statistically determined that FECW could
account for the other three independent variables in
predicting ACL length as FECW had a strong correlation
with all other variables. Femoral epicondylar width was
found to be the most reliable predictor of ACL length
(r=0.36) as opposed to height, which had an r-value=0.31. A
significant model was developed for the estimation of ACL
length when FECW is known. The R2-value of 0.13
indicated that 13% of variation found in ACL length
(among the cadavers) could be accounted for by Equation
1. Therefore, measuring the FECW of the patient might
allow for pre-operative estimation of the length of the ACL
by using the previously mentioned linear regression
formula. These values could then be utilised to predict the
required graft length to replace the torn or ruptured ACL. 

Maximum FECW was used in the current study to
correlate with ACL length. Patient height is often unknown
and FECW is a practical measurement, as it is commonly
available on X-ray and MRI.13,24 In this sample, FECW has
also proven to be a slightly more reliable predictor than
height for ACL length estimation. When comparing ACL
length and FECW, a definite positive correlation between
the measurements (p<0.05) was noticed. However, the low
R2-value of the linear regression indicates that in the South
African cadaver sample examined in the current study, the
FECW cannot be the sole predictor of ACL length. Pre-
operative mismatch of the graft length could occur if the
FECW is measured without the incorporation of additional
imaging modalities. Intra-operative measurements may
also assist to determine ACL length and therefore the
required graft length.

The weak positive correlation observed for predicting
ACL length using the maximum FECW could be explained
by remnants of soft tissue covering the epicondyles after
dissection, which may have led to inaccurate measurement
of the maximum FECW. Dissection of the ACL was also
problematic because the ligament coursed diagonally
within the knee joint. The measurement was therefore
taken blindly, which could have resulted in inaccurate
measurements of the true ACL length.

Utilising imaging modalities could allow clinicians a
greater degree of accuracy in estimating ACL length from
measuring the FECW of the patient. Future studies could
therefore be designed to investigate whether the corre-
lation between the ACL length and the FECW could be
improved when measured on MRIs. These findings should
be verified in the clinical setting.

Conclusion

The anatomy of the ACL and PL of this South African
cadaver sample compared favourably with results reported
in previous studies conducted on other population groups.
Similar to some of these studies, a correlation was found
between the intra-articular ACL length and the height of
the cadaver. It was also found that the maximum FECW of
a patient can predict the length of the intra-articular ACL

more reliably than the height of the patient can. Using
FECW as a possible predictor provides an additional
method for estimating the pre-operative length of the graft
required for ACL reconstruction and minimising the
chance of graft mismatch.

Acknowledgements

The financial assistance of the Research Development
Programme (RDP) toward this research is hereby
acknowledged. Opinions expressed and conclusions
arrived at are those of the authors and are not necessarily
attributed to the RDP. Mrs Joyce C Jordaan is greatly
thanked for her assistance with the conduction of statis-
tical analyses. Barbara English of the research office of the
University of Pretoria’s Faculty of Health Sciences is
thanked for her language editing. Medical editor, Ms
Theanette Mulder, of the Support School of Medicine of
the University of Free State is deeply thanked. Finally, the
authors kindly thank all the body donors without whom
this research would not have been possible.

Compliance with ethics guidelines

• Conflict of interest

The enclosed manuscript has been read and approved
by all authors. The authors, Mrs Van Zyl and Drs Van
Schoor, Du Toit and Louw, have no conflict of interest
to declare.

• Benefits

No benefits of any form have been received from a
commercial party related directly or indirectly to the
subject of this article.

• Ethics statement
Ethical clearance (Ethics reference number 151/2013)
was obtained from the Research Ethics Committee,
Faculty of Health Sciences, University of Pretoria. All
cadaveric material used in this study was handled in
accordance with the requirements of the South African
National Health Act, Act 61of 2003.

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