South African Orthopaedic Journal

PAEDIATRIC ORTHOPAEDICS

DOI 10.17159/2309-8309/2022/v21n1a5Mwelase SM et al. SA Orthop J 2022;21(1)

Citation: Mwelase SM, Maré PH, 
Thompson DM, Marais LC.  
The Fassier technique for correction 
of proximal femoral deformity 
in children with osteogenesis 
imperfecta. SA Orthop J 
2022;21(1):34-38. http://dx.doi.
org/10.17159/2309-8309/2022/
v21n1a5

Editor: Dr Greg Firth, University of 
the Witwatersrand, Johannesburg, 
South Africa

Received: January 2021

Accepted: February 2021

Published: March 2022

Copyright: © 2022 Mwelase SM. 
This is an open-access article 
distributed under the terms of the 
Creative Commons Attribution 
Licence, which permits unrestricted 
use, distribution and reproduction in 
any medium, provided the original 
author and source are credited.

Funding: No funding was secured 
for this research.

Conflict of interest: The authors 
declare they have no conflicts of 
interest that are directly or indirectly 
related to the research.

Abstract
Background
Children with osteogenesis imperfecta frequently present with coxa vara. Skeletal fragility, severe 
deformity and limited fixation options make this a challenging condition to correct surgically. 
Our study aimed to determine the efficacy of the Fassier technique to correct coxa vara and 
determine the complication rate.

Methods 
We retrospectively reviewed the records of a cohort of eight children (four females, 12 hips) with 
osteogenesis imperfecta (6/8 Sillence type III, 2/8 type IV) who had surgical treatment with the 
Fassier technique for proximal femoral deformity between 2014 and 2020.

Results
The mean age at operation was 5.8 years (range 2–10). The mean neck-shaft angle (NSA) was 
corrected from 96.8° preoperatively to 137º postoperatively. At a mean follow-up of 38.6 months, 
the mean NSA was maintained at 133°, and 83% (10/12) of hips had an NSA that remained 
greater than 120°. There was a 42% (5/12) complication rate: three Fassier–Duval rods failed to 
expand after distal epiphyseal fixation was lost during growth; one Rush rod migrated through 
the lateral proximal femur cortex with recurrent coxa vara; and one Rush rod migrated proximally 
and required rod revision.

Conclusion
The Fassier technique effectively corrected coxa vara in children with moderate and progressively 
deforming osteogenesis imperfecta. The deformity correction was maintained in the short term. 
The complication rate was high, but mainly related to the failed expansion of the Fassier–Duval 
rods. Further studies are required to determine the long-term outcome of this technique. 
Level of evidence: Level 4
Keywords: osteogenesis imperfecta, coxa vara, Fassier–Duval, neck-shaft angle, deformity

The Fassier technique for correction of proximal femoral 
deformity in children with osteogenesis imperfecta  
Sandile M Mwelase,¹*  Pieter H Maré,² David M Thompson,¹ Leonard C Marais³ 

1 Department of Orthopaedic Surgery, Grey’s Hospital, School of Clinical Medicine, University of KwaZulu-Natal, South Africa
² Clinical Unit Paediatric Orthopaedics, Department of Orthopaedic Surgery, Grey’s Hospital, School of Clinical Medicine, University of KwaZulu-Natal, 
  South Africa
³ Department of Orthopaedic Surgery, School of Clinical Medicine, University of KwaZulu-Natal, South Africa

*Corresponding author: sandilemwelase@gmail.com

Introduction
Osteogenesis imperfecta (OI) is a rare genetic disorder charac-
terised by abnormal type 1 collagen production. The condition 
manifests as varying degrees of skeletal fragility and deformities of 
the axial and appendicular skeleton. Coxa vara (CV) is a deformity 
of the proximal femur defined as an abnormally decreased femur 
neck-shaft angle (NSA). There is a relatively high prevalence of 
CV in children with severe OI.1 The proximal femoral deformity in 
OI is thought to be due to the soft-tissue tension during growth and 
recurrent insufficiency fractures.2

The proximal femoral deformity results in abnormal stresses on 
the femur, leading to progressive deformity and an increased risk 
of fracture. The deformed proximal femur also causes a limp and 
leg length discrepancy if it is asymmetrical, leading to functional 
impairment. The surgical treatment of CV aims to improve these 

functional deficits and to prevent progressive deformity and 
fracture.

Standard plate and screw constructs used to stabilise the 
osteotomies to correct CV from other causes are not advised in OI 
due to the resultant stress risers and the likelihood of peri-implant 
fractures.3 Several authors have described, adapted and combined 
surgical techniques to achieve deformity correction, improve 
fixation of the proximal segment and allow intramedullary fixation 
in CV due to OI.2,4-6 These studies are all limited by small numbers 
without confirmation of external validity. 

The proximal femoral deformity in OI is also complex. Severe 
procurvatum may result in an apparently decreased NSA, so-called 
‘false coxa vara’.2 Proximal control and fixation are also essential 
during deformity correction of these cases. The Fassier technique 
provides increased proximal control during deformity correction, 
and improved fixation, compared to an intramedullary rod alone.2 

https://orcid.org/0000-0001-9952-0986


Page 35Mwelase SM et al. SA Orthop J 2022;21(1)

Our study aimed to evaluate the Fassier technique of correction 
of the proximal femoral deformity in OI. Our primary objectives 
were to determine the magnitude of correction as measured by the 
NSA, and to determine whether this correction was maintained at 
the latest follow-up. The secondary objective was to determine the 
short-term complication rate of this technique.

Patients and methods
Following ethical approval from our institution’s research ethics 
committee, we used non-probability purposive sampling to identify 
all patients treated with the Fassier technique at our tertiary 
paediatric orthopaedic unit between 2014 and 2020. All OI patients 
younger than 18 years who were treated for proximal femoral 
deformity with or without visible stress fractures with expandable 
Fassier–Duval rods or Rush rods and K-wire fixation utilising the 
Fassier technique as the primary procedure were included. 

The study cohort included eight children (four females, 12 
hips) with a proximal femoral deformity corrected with the Fassier 
technique after one hip was excluded from analysis as surgery 
was done to revise a failed valgus osteotomy and plating of the 
right hip. The plating resulted in severe translation and distortion 
of the proximal femur anatomy, and we were unable to adequately 
correct this deformity or achieve stable fixation with the Fassier 
technique. Bilateral deformity correction (staged in three children) 
was required in four children. Eight hips were diagnosed as CV with 
an NSA of less than 110° (Figure 1).1,2 Two hips had a decreased 
NSA (113° and 114°, respectively) that did not meet the diagnostic 
criteria of CV. The remaining two hips were diagnosed as ‘false 
coxa vara’ with an NSA measured as 124° and 130°, respectively.2 
False CV was diagnosed when a severe procurvatum deformity 
was apparent on the lateral femur X-ray that resulted in the 
appearance of CV on the AP X-ray (Figure 2). 

Fassier et al. previously described the surgical technique.2 Our 
indication for the procedure was any child with OI and proximal 
femoral deformity that required correction through a subtrochanteric 
osteotomy. The lateral approach was used to expose the proximal 
femur. Two K-wires were inserted along the femoral neck axis from 
the posterolateral proximal femur to anteromedial in the femoral 
head, and from the anterolateral proximal femur to posteromedial 
in the femoral head. We used these wires to control the proximal 
fragment after a transverse proximal femoral osteotomy was 
performed just below the level of the lesser trochanter. In 
severe true CV (Figure 1), the proximal entry was established 
in a retrograde direction from the lateral cortex. In false CV, the 
retrograde entry was made from within the intramedullary canal 
(Figure 2). The proximal tip of the male component of the Fassier–
Duval (FD) rod was passed in a retrograde direction through the 
proximal fragment exiting at the piriformis fossa and through a 
separate more proximal skin incision. The male component was 
then advanced, and the threaded distal end seated into the distal 
femur epiphysis. The female component of the FD rod was then 
inserted antegrade over the male component and the proximal 
threaded portion secured in the proximal femur. The K-wires were 
then cut and bent and secured to the proximal femoral shaft with 
two cerclage wires. All the children with OI received the intravenous 
bisphosphonate zoledronic acid (0.05 mg/kg zoledronic acid in 
50 ml normal saline over 30 minutes) at six-monthly intervals for 
metabolic control of the disorder.7 

Clinical data was extracted from our paediatric orthopaedic 
database and combined with the radiological data stored in our 
picture archiving and communication system (PACS). Data points 
included age at surgery, sex, body mass index percentile for age 
and sex (BMI percentile), mobility status, preoperative neck-shaft 
angle (NSA), immediate postoperative NSA, NSA at latest follow-
up, delta NSA (the change between the immediate postoperative 
NSA measurement and the NSA measured at latest follow-up), and 
complications.

Figure 1. a) AP pelvis radiograph a 5-year-old boy with healed proximal 
femur stress fractures and coxa vara with the neck-shaft angle (X) 
indicated on the right hip. b) Postoperative AP radiograph after bilateral 
Fassier technique deformity correction. c) Standing AP pelvis and femurs 
radiograph one year postoperatively with maintenance of deformity 
correction and expansion of the Fassier–Duval rods visible.

b

c

a



Page 36 Mwelase SM et al. SA Orthop J 2022;21(1)

The magnitude of NSA correction and the extent to which this 
correction was maintained during follow-up were the primary 
outcome variables. The incidence of complications was the 
secondary outcome variable. Possible complications were 
recurrent deformity, loss of epiphyseal fixation with failed rod 
expansion (FD rods), transcortical rod migration, periprosthetic 
fracture, rod breakage, infection, growth arrest and hip avascular 
necrosis.

Statistical analysis
Statistical analysis was performed using jamovi version 1.2.18.0 
open-source software.8 Continuous variables were reported as 
mean (standard deviation [SD], range) or median (interquartile 

range [IQR], range), and categorical variables as number and 
percentages. The Shapiro–Wilk test was used to analyse the 
distribution of data. Normally distributed data were compared using 
the unpaired Student’s t-test, whereas the Mann–Whitney test was 
used for non-parametric data. Categorical data were analysed 
using the chi-squared test unless the expected value in any cell 
was below 5 when Fisher’s exact test was used. Correlation 
between normally distributed continuous variables was tested 
with Pearson’s correlation coefficient. All tests were two-sided, 
and the level of significance was set at p < 0.05. Binomial logistic 
regression was used to determine the odds ratio (ORs) and 95% 
confidence interval (95% CI) of the primary outcome measure.

Figure 2. a) AP radiograph of the right femur of a 4-year-old boy with false coxa vara. b) A lateral X-ray shows the procurvatum deformity which results in 
the appearance of coxa vara. c) Postoperative radiograph demonstrates the multilevel osteotomies and Fassier technique of fixation. The proximal entry is 
retrograde but intramedullary because there is no true coxa vara. d) Standing AP radiograph three years postoperatively showing maintenance of deformity 
correction and expansion of the Fassier–Duval rod.

a b c d

Table I: Descriptive data of children with osteogenesis imperfecta treated with the Fassier technique for proximal femoral deformity

No
OI 

typea
Ageb Sex Side

NSAc

preop
NSAc 

postop
NSAc 
latest

Delta 
NSAd

F/Ue W/Cf BMIg Complications Rodh

1 III 8 M R 84 130 132 −2 1 0 no – RR

2 III 5 F R 97 138 137 1 45 0 yes – FD

F L 114 142 140 2 45 0 yes – FD

3 IV 3 M R 130 137 128 9 72 0 yes Loss of distal epiphyseal fixation FD

4 III 10 F R 113 152 153 −1 61 1 no – FD

1 F L 102 137 118 19 63 1 no Loss of distal epiphyseal fixation FD

5 III 5 F R 94 139 127 12 22 0 no Loss of distal epiphyseal fixation FD

F L 124 142 133 9 22 0 no – FD

6 III 6 M R 56 144 142 2 12 0 no – FD

M L 78 140 142 −2 12 0 no – FD

7 III 5 F L 73 128 107 21 49 1 no Proximal lateral transcortical migration RR

8 IV 2 M L n/a 137 140 −3 59 0 no Proximal rod migration RR
a) Sillence type of osteogenesis imperfecta; b) Age in years; c) Neck-shaft angle in degrees; d) The difference in NSA between the postoperative and latest measurement;  
e) Follow-up duration in months; f) Wheelchair use for all mobility pre- and postoperatively; g) BMI > 95th percentile; h) RR: Rush rod, FD: Fassier–Duval rod



Page 37Mwelase SM et al. SA Orthop J 2022;21(1)

Results
The descriptive data are summarised in Table I. The mean age 
of the patients at operation was 5.8 years (SD 2.4 years, range 
2–10). Of the eight children, two had Sillence type IV OI, and six 
had type III OI. Obesity (BMI > 95th percentile for sex and age) 
was present in two children (three hips). Intramedullary fixation 
was achieved with Rush rods (RR) in three, and FD expandable 
rods in nine hips. 

The mean NSA preoperatively was 97° (SD 23°, range 56–130) 
and mean NSA postoperatively was 137° (SD 5°, range 128–148). 
The mean follow-up was 39 months (SD 24 months, range 1–72). 
At the latest follow-up, the mean NSA was 133º (SD 12.4, range 
107–153). The mean delta NSA was −6° (SD 8°, range +3 to −21). 
The NSA remained corrected to > 120° in 83% (10/12) of hips at 
latest follow-up. 

There was no correlation between delta NSA and age at surgery 
(p = 0.791), BMI percentile (p = 0.722), Sillence type OI (p = 0.653) 
or ambulatory status (p = 0.193). There was also no correlation 
between a lower preoperative NSA or longer length of follow-up 
(p = 0.174) and a higher delta TFA at latest follow-up (p = 0.567). 

There was a 42% (5/12) complication rate in our series. There 
was a 30% (3/9) incidence of loss of distal epiphyseal fixation 
of the male FD rod with failed rod expansion during growth. In 
case number 7, lateral transcortical migration of the proximal RR 
occurred with recurrent CV. The NSA measured 107° at latest 
follow-up. This child was wheelchair-bound before and after sur-
gery due to severe recurrent kyphoscoliosis and opposite lower 
limb deformity, and surgical revision was not advised. The final 
complication occurred when the RR in case number 8 migrated 
proximally into the gluteal region, causing pain and hip abduction 
limitation. The RR was exchanged to an FD rod that was inserted 
percutaneously. This was the only case that underwent revision 
surgery. 

Comparative analysis of data showed that age at surgery (p = 
0.342), preoperative NSA (p = 0.765), OI type (p = 0.067), type of 
rod used (FD vs RR) (p = 0.310) and BMI percentile (p = 0.735) 
were not associated with a higher complication rate.

Discussion
The role of orthopaedic surgery in OI is primarily to prevent and 
manage fractures or deformities. Long bone deformity correction 
and intramedullary stabilisation improve function and decrease the 
incidence of fractures.9 Our study aimed to evaluate the use of the 
Fassier technique for the correction of proximal femur deformities 
in OI.2 The technique resulted in a correction of the NSA to within 
the normal range in all cases, and this correction was maintained 
in 83% of cases at a mean three-year follow-up. Complications 
related to the rods used occurred in five cases, with one patient 
that required reoperation. 

The incidence of CV in OI was reported as 10% by Aarabi et al. 
with an average NSA of 99 degrees.1 Ambulatory children with CV 
will limp due to the shortened lever arm of the femoral neck with 
resultant abductor weakness muscles and a Trendelenburg gait. 
Finidori described a technique to correct CV using telescopic rods 
inserted retrograde on the lateral cortex of proximal femur and 
exiting at the piriformis fossa.10 Wagner described using multiple 
K-wires to achieve and maintain the deformity correction of CV in 
young children.11 

The specific surgical technique to correct CV in OI that we 
used combined the techniques of Finidori and Wagner and was 
first described by Fassier in 2003.4 Fassier et al. published their 
experience with this technique in 18 hips of children with OI in 
2008.2 In South Africa, Robertson and George described a similar 
surgical technique for CV in OI type III, using K-wires and a 

Williams rod in five hips.5 The advantages of this technique are that 
the K-wires allow for proximal control during deformity correction, 
the K-wire cerclage combination provides fixation of the proximal 
fragment, and intramedullary fixation of the femur is still achieved 
with the intramedullary rod. 

We achieved correction of the NSA from 96.8° preoperatively to 
137° postoperatively in 13 hips. This result compares favourably 
with those of Fassier et al. (18 hips, NSA 84.6° to 119.5°) and 
Robertson and George (five hips, NSA 60° to 130°), who both used 
a similar technique.2,5 Compared to these two studies, our cohort 
had a less severe deformity, but a higher postoperative NSA. We 
demonstrated maintenance of this correction with a mean NSA of 
133° at 39 months (3.25 years) follow-up. In the short term, this 
compares well with the results reported by Fassier et al. (NSA of 
114.4 at 4.3 years).

All patients in this study received intravenous bisphosphonate 
treatment. While el-Sobky et al., in a comparative study, concluded 
that surgery plus bisphosphonate treatment improves the ambu-
latory status of patients with OI, we were not able to confirm an 
improvement in ambulatory status as we only had data related to 
wheelchair use.12 Preoperatively, two of the eight patients were 
wheelchair-bound, and they remained so postoperatively.

None of the patients had intraoperative complications. Implant-
related complications were observed in 41% (5/12) of hips. While the 
complication rate is relatively high, the most common complication 
is a 30% (3/9) incidence of distal loss of epiphyseal fixation of 
the male component of the FD rod and subsequent failure of rod 
expansion. This rate compares favourably to the 45% failure of rod 
expansion reported by Landrum et al.13 In a recent paper, Holmes 
et al. found that eccentric epiphysial placement may predispose 
the rod to fail to expand, and we now pay particular attention to 
achieving this outcome.14 One RR that migrated proximally required 
revision, and this was revised to an FD rod. The last complication 
was a recurrent deformity due to lateral transcortical migration 
of the proximal RR and loss of fixation in a child with severe OI  
type III. All patients achieved radiological union, and there were no 
cases of postoperative infection or avascular necrosis of the hip.

We could not demonstrate an association between the loss 
of correction of the NSA and age at surgery, BMI, Sillence type 
OI, ambulatory status, or length of follow-up. Due to our small 
sample size and relatively short follow-up, our results were 
prone to a type 2 error. Further studies with larger numbers and 
longer follow-up are required to determine whether the deformity 
correction will be lasting, and which factors are associated with 
loss of correction. Despite the small sample size, there are very 
few studies that report on the results of treatment of the proximal 
femoral deformity in OI, and its findings are therefore important.  
A further limitation of this study is that we were unable to measure 
the Hilgenreiner’s epiphyseal angle (HEA) accurately due to pelvic 
distortion and variable positioning of the lower limbs during AP 
pelvis X-rays during follow-up. Despite this shortcoming, we were 
able to measure the NSA reliably. This was a single-centre study, 
and external validity needs to be confirmed with further studies. We 
included cases of ‘false CV’ and cases with a decreased NSA that 
was not lower than 110°. We included these because the proximal 
deformity in OI is varied and often multiplanar, and the advantages 
of the Fassier technique make it applicable in all these situations. 

Despite these shortcomings, we were able to report effective and 
safe deformity correction with the Fassier technique in this series 
of children with CV secondary to OI in the short term.

Conclusion
The Fassier technique effectively corrected CV in children with 
moderate and progressively deforming OI. The deformity cor-
rection was maintained in the short term. The complication rate 



Page 38 Mwelase SM et al. SA Orthop J 2022;21(1)

was high, but mainly related to the failed expansion of the FD rods. 
Further studies are required to determine the long-term outcome 
of this technique. 

Ethics statement
The authors declare that this submission is in accordance with the principles laid down 
by the Responsible Research Publication Position Statements as developed at the 
2nd World Conference on Research Integrity in Singapore, 2010.
Prior to commencement of the study, ethics approval was obtained from the University 
of KwaZulu-Natal Biomedical Research Ethics Committee BREC/00001850/2020. 
All procedures were in accordance with the ethical standards of the responsible 
committee on human experimentation (institutional and national) and with the Helsinki 
Declaration of 1975, as revised in 2008.

Declaration
The authors declare authorship of this article and that they have followed sound 
scientific research practice. This research is original and does not transgress 
plagiarism policies.

Author contributions 
SMM: data capture, data analysis, first draft preparation, manuscript preparation
PHM: study conceptualisation, study design, data capture, data analysis, manuscript 
revision
DMT: study conceptualisation, data capture, manuscript revision
LCM: study design, manuscript revision

ORCID
Mwelase SM  https://orcid.org/0000-0001-9952-0986
Maré PH  https://orcid.org/0000-0003-1599-7651
Thompson DM  https://orcid.org/0000-0003-2607-3999
Marais LC  https://orcid.org/0000-0002-1120-8419

References
1. Aarabi M, Rauch F, Hamdy R, Fassier F. High prevalence of coxa vara in patients with 

severe osteogenesis imperfecta. J Pediatr Orthop. 2006;26(1):24-28. https://doi.
org/10.1097/01.bpo.0000189007.55174.7c. 

2. Fassier F, Sardar Z, Aarabi M, et al. Results and complications of a surgical technique for 
correction of coxa vara in children with osteopenic bones. J Pediatr Orthop. 2008;28(8):799-
805. https://doi.org/10.1097/bpo.0b013e31818e19b7. 

3. Noonan K, Enright W. Bone plating in patients with type III osteogenesis imperfecta: results 
and complications. Iowa Orthop J. 2006;26:37-40. 

4.  Fassier F, Glorieux FH. Osteogenesis imperfecta. In: Surgical Techniques in Orthopaedics 
and Traumatology. Paris: Elsevier SAS; 55-050-D-30,2003, 8.

5.  Robertson A, George JA. A surgical technique for coxa vara in osteogenesis imperfecta. SA 
Orthop J. 2005;4(1):16-19. 

6.  Georgescu I, Gavriliu S, Nepaliuc I, et al. Burnei’s technique of femoral neck variation 
and valgisation by using the intramedullary rod in osteogenesis imperfecta. J Med Life. 
2014;7(4):493-98. 

7.  Palomo T, Fassier F, Ouellet J, et al. Intravenous bisphosphonate therapy of young children 
with osteogenesis imperfecta: skeletal findings during follow up throughout the growing 
years. J Bone Miner Res. 2015;30(12):2150-57. https://doi.org/10.1002/jbmr.2567.

8.  The jamovi project (2020). jamovi (Version 1.2)[Computer Software]. Downloaded from: 
https://www.jamovi.org on 30 August 2020.

9.  Esposito P, Plotkin H. Surgical treatment of osteogenesis imperfecta: current concepts. Curr 
Opin Pediatr. 2008;20(1):52-57. https://doi.org/10.1097/mop.0b013e3282f35f03. 

10.  Finidori, G. Treatment of osteogenesis imperfecta in children. Ann N Y Acad Sci. 
1988;543:167-69. https://doi.org/10.1111/j.1749-6632.1988.tb55329.x.

11.  Widmann RF, Hresko MT, Kasser JR, Millis MB. Wagner multiple K-wire osteosynthesis to 
correct coxa vara in the young child: experience with a versatile ‘tailor-made’ high angle 
blade plate equivalent. J Pediatr Orthop B. 2001;10(1):43-50.

12.  el-Sobky MA, Zaky Hanna AA, Basha NE, et al. Surgery versus surgery plus pamidronate in 
the management of osteogenesis imperfecta patients: a comparative study. J Pediatr Orthop 
B. 2006;15(3):222-28. https://doi.org/10.1097/01.bpb.0000192058.98484.5b.

13.  Landrum M, Birch C, Richards BS. Challenges encountered using Fassier-Duval rods in 
osteogenesis imperfecta. Curr Orthop Pract. 2019;30(4):318-22.

14.  Holmes K, Gralla J, Brazell C, et al. Fassier-Duval rod failure: is it related to positioning 
in the distal epiphysis? J Pediatr Orthop. 2020;40(8):448-52. https://doi.org/10.1097/
bpo.0000000000001513.

https://orcid.org/0000-0001-9952-0986
https://orcid.org/0000-0003-1599-7651
https://orcid.org/0000-0003-2607-3999
https://orcid.org/0000-0002-1120-8419
https://doi.org/10.1097/01.bpo.0000189007.55174.7c
https://doi.org/10.1097/01.bpo.0000189007.55174.7c
https://doi.org/10.1097/bpo.0b013e31818e19b7
https://doi.org/10.1002/jbmr.2567
https://www.jamovi.org
https://doi.org/10.1097/mop.0b013e3282f35f03
https://doi.org/10.1111/j.1749-6632.1988.tb55329.x
https://doi.org/10.1097/01.bpb.0000192058.98484.5b
https://doi.org/10.1097/bpo.0000000000001513
https://doi.org/10.1097/bpo.0000000000001513