Subscribe to RSS
Download PDF
DOI: 10.1055/a-2655-0004
In Silico Analysis of Stress Distribution in Proximal Interphalangeal Joint Arthrodesis in Horses Using a Locking Compression Plate
Funding This study was supported by the São Paulo Research Foundation, grant number 2021/07105-9.
Abstract
Objective
This study aimed to compare the stress distribution in proximal interphalangeal joint arthrodesis with locking compression plate in horses based on the type and method of screw implantation in the proximal hole and partial or total removal of implants after fusion.
Study Design
Finite element analysis.
Methods
Proximal interphalangeal joint arthrodesis was simulated using a 3-hole, 4.5-mm narrow locking compression plate combined with two 5.5-mm transarticular screws. Models were created according to the type (cortex or locking) and method of implantation (uni- or bicortical) of the screw in the proximal hole of the locking compression plate. Four conditions were simulated: Immediate postoperative, ankylosis, ankylosis with partial removal (transarticular screws remaining) and ankylosis with no implants. An axial load of 8,700 N was applied, and the major principal stresses in the bones and von Mises stress in the implants were evaluated.
Results
Cortical screws in the proximal hole better distributed the stresses, reducing their concentration along the diaphysis of the proximal phalanx in the postoperative condition. Stress distribution did not differ between partial and total implant removal. High stresses were observed in the implants, especially when locking screws were used, with a reduction observed after ankylosis simulation.
Conclusion
A cortex screw in the proximal hole reduces stress concentration in the proximal phalanx. Retaining the transarticular screws after ankylosis did not alter the stress pattern in the bone.
Keywords
equine - proximal interphalangeal joint - ankylosis - finite element analysis - locking compression plateNote
The limited abstract of this study was presented as a poster at the XXIV Conferência Anual ABRAVEQ on July 4–6, 2024, at Campinas, São Paulo, Brazil.
Authors' Contribution
A.F.de S. contributed to the conception of the study and study design, collected data; drafted, revised and approved the submitted manuscript. C.A.M.P. contributed to the conception of the study, obtained strain gage data to validate finite element models results and approved the submitted manuscript. I.O.G. contributed to the conception of the study and study design, collected data; and revised and approved the submitted manuscript. J.B.C.M., R.Y.B., and A.L.de V. de Z. contributed to the conception of the study and study design, collected data; drafted, revised and approved the submitted manuscript. All authors provided a critical review of the manuscript and endorse the final version.
Publication History
Received: 02 December 2024
Accepted: 14 July 2025
Article published online:
24 July 2025
© 2025. Thieme. All rights reserved.
Georg Thieme Verlag KG
Oswald-Hesse-Straße 50, 70469 Stuttgart, Germany
-
References
- 1 Lischer CJ, Auer JA. Arthrodesis techniques. In: Auer JA, Stick JA, Kümmerle JM, Prange T. eds. Equine Surgery. 5th ed.. Elsevier; 2019: 1374-1398
- 2 Souza AF, Zoppa ALV. Proximal interphalangeal joint arthrodesis in horses: concepts, indications, and techniques. Braz J Vet Res Anim Sci 2021; 58: e178586
- 3 Watkins JP. Arthrodesis of the proximal interphalangeal joint. In: Equine Fracture Repair. 2nd ed.. Wiley Blackwell; 2019: 277-294
- 4 Clayton HM, Singleton WH, Lanovaz JL, Prades M. Sagittal plane kinematics and kinetics of the pastern joint during the stance phase of the trot. Vet Comp Orthop Traumatol 2002; 15 (01) 15-17
- 5 Clayton HM, Sha DH, Stick JA, Robinson P. 3D kinematics of the interphalangeal joints in the forelimb of walking and trotting horses. Vet Comp Orthop Traumatol 2007; 20 (01) 1-7
- 6 Martin GS, McIlwraith CW, Turner AS, Nixon AJ, Stashak TS. Long-term results and complications of proximal interphalangeal arthrodesis in horses. J Am Vet Med Assoc 1984; 184 (09) 1136-1140
- 7 Caston S, McClure S, Beug J, Kersh K, Reinertson E, Wang C. Retrospective evaluation of facilitated pastern ankylosis using intra-articular ethanol injections: 34 cases (2006-2012). Equine Vet J 2013; 45 (04) 442-447
- 8 Caron JP, Fretz PB, Bailey JV, Barber SM. Proximal interphalangeal arthrodesis in the horse. A retrospective study and a modified screw technique. Vet Surg 1990; 19 (03) 196-202
- 9 Steenhaut M, Verschooten F, De Moor A. Arthrodesis of the pastern joint in the horse. Equine Vet J 1985; 17 (01) 35-40
- 10 Hicks RB, Glass KG, Watkins JP. Proximal interphalangeal locking compression plate for pastern arthrodesis in horses. Equine Vet J 2021; 54 (04) 740-749
- 11 Sakai RR, Goodrich LR, Katzman SA. et al. Use of a locking compression plate for equine proximal interphalangeal joint arthrodesis: 29 cases (2008-2014). J Am Vet Med Assoc 2018; 253 (11) 1460-1466
- 12 Souza AF, Marcondes Gde M, Paretsis NF, Corrêa RR, Spagnolo JD, Zoppa ALV. Proximal interphalangeal arthrodesis in seven horses: A retrospective study in Brazil (2011–2019). Cienc Rural 2021; 51: e20200741
- 13 de Souza AF, Pereira CAM, Fürst A, Kümmerle JM, De Zoppa ALDV. Does the proximal screw type affect stress and strain in pastern arthrodesis with locking plate in horses?. Res Vet Sci 2024; 178: 105378
- 14 de Souza AF, Pereira CAM, Costa C, Fürst A, Kümmerle JM, De Zoppa ALV. Mechanical properties and failure mode of proximal screw fixation technique using locking compression plate for proximal interphalangeal arthrodesis in horses: An ex vivo study. Vet Comp Orthop Traumatol 2024; 37 (06) 263-272
- 15 Arthurs G. Advances in internal fixation locking plates. In Pract 2015; 37 (01) 13-20
- 16 de Souza AF, Paretsis NF, De Zoppa ALDV. Proximal interphalangeal arthrodesis in horses: A meta-analysis of retrospective studies. J Equine Vet Sci 2023; 122: 104226
- 17 Donati B, Fürst AE, Del Chicca F, Jackson MA. Plate removal after internal fixation of limb fractures: A retrospective study of indications and complications in 48 horses. Vet Comp Orthop Traumatol 2021; 34 (01) 59-67
- 18 Ruggles AJ. Implant removal. In: Equine Fracture Repair. 2nd ed.. Wiley Blackwell; 2019: 823-830
- 19 Andrade MC, De Rus Aznar I, Brunnberg M, Slunsky P. Indications for the removal of implants after fracture healing: A comparison between human and veterinary medicine. Vet Med (Praha) 2023; 68 (07) 259-270
- 20 Onche II, Osagie OE, INuhu S. Removal of orthopaedic implants: Indications, outcome and economic implications. J West Afr Coll Surg 2011; 1 (01) 101-112
- 21 Hirashima T, Matsuura Y, Suzuki T, Akasaka T, Kanazuka A, Ohtori S. Long-term evaluation using finite element analysis of bone atrophy changes after locking plate fixation of forearm diaphyseal fracture. J Hand Surg Glob Online 2021; 3 (05) 240-244
- 22 Sumner DR. Long-term implant fixation and stress-shielding in total hip replacement. J Biomech 2015; 48 (05) 797-800
- 23 Sumner DR, Galante JO. Determinants of stress shielding: Design versus materials versus interface. Clin Orthop Relat Res 1992; (274) 202-212
- 24 Haase K, Rouhi G. Prediction of stress shielding around an orthopedic screw: using stress and strain energy density as mechanical stimuli. Comput Biol Med 2013; 43 (11) 1748-1757
- 25 Rouhi G, Tahani M, Haghighi B, Herzog W. Prediction of stress shielding around orthopedic screws: Time-dependent bone remodeling analysis using finite element approach. J Med Biol Eng 2015; 35 (04) 545-554
- 26 Pfeiffer FM. The use of finite element analysis to enhance research and clinical practice in orthopedics. J Knee Surg 2016; 29 (02) 149-158
- 27 O'Hare LMS, Cox PG, Jeffery N, Singer ER. Finite element analysis of stress in the equine proximal phalanx. Equine Vet J 2013; 45 (03) 273-277
- 28 Brama PA, Karssenberg D, Barneveld A, van Weeren PR. Contact areas and pressure distribution on the proximal articular surface of the proximal phalanx under sagittal plane loading. Equine Vet J 2001; 33 (01) 26-32
- 29 Bel JC. Pitfalls and limits of locking plates. Orthop Traumatol Surg Res 2019; 105 (1S): S103-S109
- 30 Gasiorowski JC. Principles of locking plate applications in large animals. In: Locking Plates in Veterinary Orthopedics. John Wiley & Sons, Ltd; 2018: 51-67
- 31 von Mises R. Mechanik der festen Körper im plastisch-deformablen Zustand. Nachr Ges Wiss Gottingen Math-Phys Kl 1913; 1: 582-592
- 32 Frazer LL, Santschi EM, Fischer KJ. Impact of a void in the equine medial femoral condyle on bone stresses and peak contact pressures in a finite element model. Vet Surg 2019; 48 (02) 237-246
- 33 Frazer LL, Santschi EM, Fischer KJ. The impact of subchondral bone cysts on local bone stresses in the medial femoral condyle of the equine stifle joint. Med Eng Phys 2017; 48: 158-167
- 34 Lang JJ, Li X, Micheler CM. et al. Numerical evaluation of internal femur osteosynthesis based on a biomechanical model of the loading in the proximal equine hindlimb. BMC Vet Res 2024; 20 (01) 188
- 35 Boschin LC, Alencar PGC. Stress shielding: avaliação radiográfica após seguimento a longo prazo. Rev Bras Ortop 2007; 42: 290-296
- 36 Field JR. Bone plate fixation: Its relationship with implant induced osteoporosis. Vet Comp Orthop Traumatol 1997; 10 (02) 88-94
- 37 Gilbert JA. Stress protection osteopenia due to rigid plating. Clin Biomech (Bristol, Avon) 1988; 3 (03) 179-186
- 38 Ahmad M, Nanda R, Bajwa AS, Candal-Couto J, Green S, Hui AC. Biomechanical testing of the locking compression plate: When does the distance between bone and implant significantly reduce construct stability?. Injury 2007; 38 (03) 358-364
- 39 Karpiński R, Jaworski Ł, Zubrzycki J. Structural analysis of articular cartilage of the hip joint using finite element method. Adv Sci Technol Res J 2016; 10 (31) 240-246
- 40 Livermore C, Voldman J. Material Properties Database. Accessed April 10, 2024; available at: http://www.mit.edu/~6.777/matprops/matprops.htm
- 41 Goodno BJ, Gere JM. Mechanics of Materials. 9th ed.. Cengage Learning; 2018
- 42 AZO Materials. A Background to Silicon and its Applications. Accessed April 10, 2024; available at: https://www.azom.com/properties.aspx?ArticleID=920