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Abstract

Objective:

To elucidate the mechanics of scalp rotation flaps through 3D imaging and computational modeling. Excessive tension near a wound or sutured region can delay wound healing or trigger complications. Measuring tension in the operating room is challenging, instead, noninvasive methods to improve surgical planning are needed.

Design:

Multi-view stereo allows creation of 3D patient-specific geometries based on a set of photographs. The patient-specific 3D geometry is imported into a finite element (FE) platform to perform a virtual procedure. The simulation is compared with the clinical outcome. Additional simulations quantify the effect of individual flap parameters on the resulting tension distribution.

Participants:

Rotation flaps for reconstruction of scalp defects following melanoma resection in 2 cases are presented. Rotation flaps were designed without preoperative FE preparation.

Main Outcome Measure:

Tension distribution over the operated region.

Results:

The tension from FE shows peaks at the base and distal ends of the scalp rotation flap. The predicted geometry from the simulation aligns with postoperative photographs. Simulations exploring the flap design parameters show variation in the tension. Lower tensions were achieved when rotation was oriented with respect to skin tension lines (horizontal tissue fibers) and smaller rotation angles.

Conclusions:

Tension distribution following rotation of scalp flaps can be predicted through personalized FE simulations. Flaps can be designed to reduce tension using FE, which may greatly improve the reliability of scalp reconstruction in craniofacial surgery, critical in complex cases when scalp reconstruction is essential for coverage of hardware, implants, and/or bone graft.

Keywords

finite element analysis multi-view stereo tissue mechanics craniofacial reconstruction skin anisotropy

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References

Aarabi

Longaker

Gurtner

. Hypertrophic scar formation following burns and trauma: new approaches to treatment. PLoS Med. 2007;4(9):1464–1470.

Abe

Kuroda

Furutani

Tanaka

Data-based prediction of soft tissue changes after orthognathic surgery: clinical assessment of new simulation software. Int J Oral Maxillofac Surg. 2015;44(1):90–96.

Camison

Bykowski

Lee

Carslson

Roosenboom

Goldstein

Losee

Weingberg

. Validation of the Vectra H1 portable three-dimensional photogrammetry system for facial imaging. Int J Oral Maxillofac Surg. 2018;47(3):403–410.

Cox

. The cleavage lines of the skin. Br J Surg. 1941;29(114):234–240.

Gurtner

Dauskardt

Wong

Bhatt

Vial

Padois

Korman

Longaker

. Improving cutaneous scar formation by controlling the mechanical environment: large animal and phase I studies. Ann Surg. 2011;254(2):217–225.

Hiep

Keriven

Labatut

Pons

. Towards high-resolution large-scale multi-view stereo. In: 2009 IEEE Conference on Computer Vision and Pattern Recognition. June 22-25, 2009; Miami, FL.

Holzapfel

Gasser

Ogden

. A new constitutive framework for arterial wall mechanics and a comparative study of material models. J Elast. 2000;61:1–48.

Jor

JWY

Parker

Taberner

Nash

Nielsen

PMF.

Computational and experimental characterization of skin mechanics: identifying current challenges and future directions. Wiley Interdiscip Rev Syst Biol Med. 2013;5(5):539–556.

Lanir

Fung

. Two-dimensional mechanical properties of rabbit skin-II. Experimental results. J Biomech. 1974;7(2):171–182.

10.

Lee

Turin

Gosain

Tepole

. Multi-view stereo in the operating room allows prediction of healing complications in a patient-specific model of reconstructive surgery. J Biomech. 2018;74:202–206.

11.

Lee

Vaca

Ledwon

Bae

Topczewska

Turin

Kuhl

Gosain

Tepole

. Improving tissue expansion protocols through computational modeling. J Mech Behav Biomed Mater. 2018;82:224–234.

12.

Limbert

. Mathematical and computational modelling of skin biophysics: a review. Proc R Soc A Math Phys Eng Sci. 2017;473(2203):20170257.

13.

Weng

Lin

. Three-dimensional region-based study on the relationship between soft and hard tissue changes after orthognathic surgery in patients with prognathism. PLoS One. 2018;130(8):e0200589.

14.

Luebberding

Krueger

Kerscher

Mechanical properties of human skin in vivo: a comparative evaluation in 300 men and women. Ski Res Technol. 2014;20(2):127–135.

15.

Müller

Elrod

Pensalfini

Hopf

Distler

Schiestl

Mazza

. A novel ultra-light suction device for mechanical characterization of skin. PLoS One. 2018;13(8):e0201440.

16.

Ní Annaidh

Bruyère

Destrade

Gilchrist

Otténio

. Characterization of the anisotropic mechanical properties of excised human skin. J Mech Behav Biomed Mater. 2012;5(1):139–148.

17.

Paterno

Vial

Wong

Rustad

Sorkin

Shi

Bhatt

Thangarajah

Gurtner

. Akt-mediated mechanotransduction in murine fibroblasts during hypertrophic scar formation. Wound Repair Regen. 2010;19(1):49–58.

18.

Paul

Matulich

Charlton

. A new skin tensiometer device: computational analyses to understand biodynamic excisional skin tension lines. Sci Rep. 2016;6(1):30117.

19.

Raposio

Nordström

Santi

. Undermining of the scalp: quantitative effects. Plast Reconstr Surg. 1998;101(5):1218–1222.

20.

Seitz

SM.

Curless

Diebel

Scharstein

Szeliski

. A comparison and evaluation of multi-view stereo reconstruction algorithms. Proceedings of IEEE Conference on Computer Vision and Pattern Recognition (CVPR). 2006;1:519–528.

21.

Sen

Gordillo

Roy

Kirsner

Lambert

Hunt

Gottrup

Gurtner

Longaker

. Human skin wounds: a major and snowballing threat to public health and the economy. Wound Repair Regen. 2009;17(6):763–771.

22.

Sifakis

Hellrung

Teran

Oliker

Cutting

Local flaps: a real-time finite element based solution to the plastic surgery defect puzzle. Stud Health Technol Informatics. 2009;142:313318.

23.

Sree

Rausch

Tepole

. Linking microvascular collapse to tissue hypoxia in a multiscale model of pressure ulcer initiation. Biomech Model Mechanobiol. 2019;18(6):1947–1964.

24.

Strecha

von Hansen

Van Gool

Fua

Thoennessen

. On benchmarking camera calibration and multi-view stereo for high resolution imagery. In 2008 IEEE Conference on Computer Vision and Pattern Recognition. June 23-28, 2008; Anchorage, Alaska:1–8.

25.

Tepole

Gart

Gosain

Kuhl

. Characterization of living skin using multi-view stereo and isogeometric analysis. Acta Biomater. 2014;10(11):4822–4831.

26.

Tepole

Gart

Purnell

Gosain

Kuhl

. Multi-view stereo analysis reveals anisotropy of prestrain, deformation, and growth in living skin. Biomech Model Mechanobiol. 2015;14(5):1007–1019.

27.

Tepole

Gart

Purnell

Gosain

Kuhl

. The incompatibility of living systems: characterizing growth-induced incompatibilities in expanded skin. Ann Biomed Eng. 2016;44(5):1734–1752.

28.

Tepole

Gosain

Kuhl

Computational modeling of skin: using stress profiles as predictor for tissue necrosis in reconstructive surgery. Comput Struct. 2014;143:32–39.

29.

Tong

Fung

. The stress-strain relationship for the skin. J Biomech. 1976;9(10):649–657.

30.

Tonge

Voo

Nguyen

. Full-field bulge test for planar anisotropic tissues: part II-a thin shell method for determining material parameters and comparison of two distributed fiber modeling approaches. Acta Biomater. 2013,9(4):5926–5942.

31.

Tonge

Atlan

Voo

Nguyen

. Full-field bulge test for planar anisotropic tissues: part I-experimental methods applied to human skin tissue. Acta Biomater. 2013;9(4):5913–5925.

32.

Weickenmeier

Jabareen

Mazza

. Suction based mechanical characterization of superficial facial soft tissues. J Biomech. 2015;48(16):4279–4286.

33.

Wong

Levi

Akaishi

Schultz

Dauskardt

. Scar zones: region-specific differences in skin tension may determine incisional scar formation. Plast Reconstr Surg. 2012:129(6):1272.

34.

Wong

Longaker

Gurtner

. Soft tissue mechanotransduction in wound healing and fibrosis. Semin Cell Dev Biol. 2012;23(9):981–986.

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Personalized Computational Models of Tissue-Rearrangement in the Scalp Predict the Mechanical Stress Signature of Rotation Flaps

Abstract

Objective:

Design:

Participants:

Main Outcome Measure:

Results:

Conclusions:

Keywords

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References

Supplementary Material