Anatomic study of septocutaneous system of the human fetuses’ lower leg: posterior tibial artery

  • Goran Stevanovic Clinical Center Niš, Clinic for Plastic, Reconstructive and Aesthetic Surgery, Nis, Serbia
  • Marija Z. Daković-Bjelaković University of Niš, Faculty of Medicine, Department of Anatomy, Niš, Serbia
  • Boban Djordjević Military Medical Academy, Clinic for Plastic Surgery and Burns, Belgrade, Serbia; University of Defence, Faculty of Medicine of the Military Medical Academy, Belgrade, Serbia
  • Jadranka M. Paravina Clinical Center Niš, Clinic for Plastic, Reconstructive and Aesthetic Surgery; Niš, Serbia
  • Ivan Z. Golubović Clinical Center Niš, Department of Orthopedics and Traumatology,Niš, Serbia
  • Irena D. Janković Clinical Center Niš, Clinic for Plastic, Reconstructive and Aesthetic Surgery; Niš, Serbia
  • Milan D. Radojković Clinical Center Niš, Clinic for General Surgery, Niš, Serbia
  • Milica D. Nestorović Clinical Center Niš, Clinic for General Surgery, Niš, Serbia
  • Nebojša S. Ignjatović Clinical Center Niš, Clinic for General Surgery, Niš, Serbia
  • Miljan S. Krstić Clinical Center Niš, Department of Pathology, Niš, Serbia
Keywords: anatomy, fetus, leg, surgical flaps, tibial arteries

Abstract


Abstract

 

Background/Aim. Lower-leg septocutaneous system of perforating blood vessels represents the vascular basis of fasciocutaneous flaps. Additionally, it is of a particular im­portance when designing distally based fasciocutaneous flaps which represent the “workhorse” in the reconstruction of the distal third of the lower leg and foot. The aim of this study was to analyse the vascular anatomy of posterior tibial artery and its septocutaneous (fasciocutaneous) perforating arterial vessels. Methods. The dissection was conducted on 20 fetuses of both sexes and of gestational age from 20 to 28 weeks. Cluster analysis was applied to the data on vascu­lar anatomy of posterior tibial artery and its septocutaneous performating arterial vessels. Results. A total of 212 perfo­rating arterial vessels was identified. The average number of perforating arterial vessels was 5.32 (ranging from 4 to 7). It was identified that septocutaneous perforating blood vessels are more likely to be found at certain levels (“safe levels of finding perforators”). These are: second, third, fifth and sixth tenth (measured as a distance from intermalleolar line to popliteal crease). Conclusion. The presence of septo­cutaneous system of perforating blood vessels and reliability of their localization even in the fetal period allows applica­tion of these findings in the lower leg reconstructions in children of early age. It also contributes to the greater level of understanding of anatomy of the lower-leg vascular sys­tem. Finally, it provides a basis for understanding the devel­opment of this system as it is now possible to compare re­sults obtained on fetuses with those obtained on adults.

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Published
2021/02/24
Section
Original Paper