Top

Surgical and Radiologic Anatomy

Published in:

01-10-2020 | Original Article

The fibular notch: an anatomical study

Authors: Petr Fojtík, Karel Kostlivý, Jan Bartoníček, Ondřej Naňka

Published in: Surgical and Radiologic Anatomy | Issue 10/2020

Abstract

Introduction

Reduction of the distal fibula into the fibular notch (FN) poses a problem that has not been fully resolved, yet. A number of methods have been developed for the assessment of the position of the fibula in the FN, but none of them is ideal. A majority of authors assess the FN 1 cm above the tibiotalar joint space, without specifying the reason for the choice of this distance. None of the previous studies has addressed at what level the FN is the deepest. Our findings show that it is 4–5 mm above the ankle joint space and verification of this hypothesis has been the aim of this study.

Materials and methods

Dry adult tibial bone specimens from the Pachner’s collection of the Institute of Anatomy of 1st Faculty of Medicine, Charles University, Prague were used in the study. Height of the FN at its widest point, 3 mm and 10 mm above the articular surface of the distal tibia were measured in each specimen, as well as the depth of the FN at the deepest point, 3 mm and 10 mm above the articular surface of the distal tibia and the distance between the highest point of this surface and the deepest point of the notch.

Results

The mean length of the tibia was 350 mm; the mean height of the FN was 42.5 mm; the mean width of the FN at its widest point was 23.6 mm, at 3 mm above the tibiotalar joint space 22 mm, 10 mm above this articular surface of distal tibia (tibial plafond) 18.9 mm. The mean depth of the notch at 3 mm above the tibial plafond was 3.8 mm, at 10 mm above this surface 4.1 mm. The maximum mean depth of the notch was 4.5 mm, the distance from this point to the highest point of the tibial plafond was 5.3 mm.

Conclusion

The deepest point of the FN lies 5 mm above the articular surface of the tibial plafond, with the mean value of the depth being 4.5 mm. This region is, therefore, ideal for assessment of the position of the distal fibula in the FN.

Bartoníček J (2003) Anatomy of the tibiofibular syndesmosis and its clinical relevance. Surg Radiol Anat 25:379–386CrossRef

Bartoníček J, Rammelt S, Kostlivý K, Vaněček V, Klika D, Trešl I (2015) Anatomy and classification of the posterior tibial fragment in ankle fractures. Arch Orthop Trauma Surg 135:506–516CrossRef

Bartoníček J, Rammelt S, Kašper Š, Malík J, Tuček M (2019) Pathoanatomy of Maisonneuve fracture based on radiologic and CT examination. Arch Orthop Trauma Surg 139:497–506CrossRef

Boszczyk A, Kwapisz A, Krümmel M, Graas R, Rammelt S (2017) Anatomy of the tibial incisura as a risk factor for syndesmotic injury. Foot Ankle Surg 25:51–58CrossRef

Boszczyk A, Kwapisz S, Krümmel M, Graas R, Rammelt S (2018) Correlation of incisura anatomy with syndesmotic malreduction. Foot Ankle Int 39:369–375CrossRef

Brzobohatá H, Krajíček V, Velemínský P, Velemínská J (2019) Three-dimensional geometry of human tibial anterior curvature in chronologically distinct population samples of Central Europeans (2900 BC—21st century AD). Sci Rep 9:4234CrossRef

Chen Y, Qiang M, Zhang K, Li H, Dai H (2015) A reliable radiographic measurement for evaluation of normal distal tibiofibular syndesmosis: a multi-detector computed tomography study in adults. J Foot Ankle Res 8:32CrossRef

Cherney SM, Spraggs-Hughes AG, McAndrew CM, Ricci WM, Gardner MJ (2016) Incisura morphology as a risk factor for syndesmotic malreduction. Foot Ankle Int 37:748–754CrossRef

Dalmau-Pastor M, Vega J (2017) Letter regarding: cadaveric analysis of the distal tibiofibular syndesmosis. Foot Ankle Int 38:343–345CrossRef

10.

Elgafy H, Semaan HB, Blessinger B, Wassef A, Ebraheim NA (2010) Computed tomography of normal distal tibiofibular syndesmosis. Skelet Radiol 39:559–564CrossRef

11.

Gupta C, Nayak N, Palimar V (2018) A morphometric study of incisura fibularis in south Indian population with its clinical implications. Int J Anat Appl Physiol 4:84–86

12.

Hermans JJ, Beumer A, De Jong TA, Kleinrensink GJ (2010) Anatomy of the distal tibiofibular syndesmosis in adults: a pictorial essay with a multimodality approach. J Anat 217:633–645CrossRef

13.

Hu WK, Chen DW, Li B, Yang YF, Yu GR (2019) Motion of the distal tibiofibular syndesmosis under different loading patterns: a biomechanical study. J Orthop Surg (Hong Kong) 27:1–6

14.

Kulkarni RR, Prakash ChR, Nidhi S (2012) Importance of fibular incisura measurements in ankle reconstructive surgeries. Int J AJ Inst Med Sci 1:80–85

15.

Liu GT, Ryan E, Gustafson E, VanPelt MD, Raspovic KM, Lalli T, Wukich DK, Xi Y, Chhabra A (2018) Three-dimensional computed tomographic characterization of normal anatomic morphology and variations of the distal tibiofibular syndesmosis. J Foot Ankle Surg 57:1130–1136CrossRef

16.

Musa M, Pamela M, Moses O, Beda O, Gichambira G (2014) Morphometric characteristics of the fibular incisura in adult Kenyans. Anat J Afr 3:243–249

17.

O´Sullivan E, Bowyer G, Webb AL (2013) The synovial fold of the distal tibiofibular joint: a morphometric study. Clin Anat 26:630–637CrossRef

18.

Park CH, Kim GB (2019) Tibiofibular relationships of the normal syndesmosis differ by age on axial computed tomography—anterior fibular translation with age. Injury 50:1256–1260CrossRef

19.

Prakash A (2017) Is incisura fibularis a reliable landmark for assessing syndesmotic stability? A systematic review of morphometric studies. Foot Ankle Spec 10:246–251CrossRef

20.

Sharif B, Welck M, Saifuddin A (2020) MRI of the distal tibiofibular joint. Skeletal Radiol 49:1–17CrossRef

21.

Sora MC, Strobl B, Stavkov D, Förster-Streffleur S (2004) Evaluation of the ankle syndesmosis: a plastination slices study. Clin Anat 17:513–517CrossRef

22.

Taser F, Toker S, Kilincoglu V (2009) Evaluation of morphometric characteristics of the fibular incisura on dry bones. Joint Dis Rel Surg 20:52–58

23.

Tonogai I, Hamada D, Sairyo K (2017) Morphology of the incisura fibularis at the distal tibiofibular syndesmosis in the Japanese population. J Foot Ankle Surg 56:1147–1150CrossRef

24.

Yildirim H, Mavi A, Büyükbebeci O, Gümüsburun E (2003) Evaluation of the fibular incisura of the tibia with magnetic resonance imaging. Foot Ankle Int 24:387CrossRef

25.

Yu M, Zhang Y, Su Y, Wang F, Zhao D (2018) An anthropometric study of distal tibiofibular syndesmosis (DTS) in a Chinese population. J Orthop Surg Res 13:95–102CrossRef

Title: The fibular notch: an anatomical study
Authors: Petr Fojtík
Karel Kostlivý
Jan Bartoníček
Ondřej Naňka
Publication date: 01-10-2020
Publisher: Springer Paris
Published in: Surgical and Radiologic Anatomy / Issue 10/2020
Print ISSN: 0930-1038
Electronic ISSN: 1279-8517
DOI: https://doi.org/10.1007/s00276-020-02476-w

Keynote webinar | Spotlight on medication adherence

Springer Medicine

The fibular notch: an anatomical study

Abstract

Introduction

Materials and methods

Results

Conclusion

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Abstract

Introduction

Materials and methods

Results

Conclusion

Please log in to get access to this content

Other articles of this Issue 10/2020

The morphometry, localization, and shape types of the fovea capitis femoris, and their relationship with the femoral head parameters

Three-dimensional morphological analysis and clinical application of ankle joint in Chinese population based on CT reconstruction

Morphological characteristics of the lateral ankle ligament complex

Retro-psoas muscle vermiform appendix: an unusual location

Anatomical variations in the insertion of the peroneus longus tendon

Successful reconstruction of the posterior cruciate ligament: assessment of posterior cruciate ligament footprints using an objective coordinate system