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J Reconstr Microsurg
DOI: 10.1055/a-2737-5529
DOI: 10.1055/a-2737-5529
Original Article
The Impact of Needle Geometry on Tissue Damage and Anastomotic Leakage: A Combined Analysis of Human Skin and Porcine Cardiovascular Models
Authors
Abstract
Background
Surgical needles have evolved to optimize tissue approximation while minimizing tissue damage. Needle point geometry is a critical operative factor that impacts surgical dexterity. This study aims to compare the effects of taper point (TP) and reverse cutting (RC) needles on tissue damage and anastomotic bleeding risk across different tissue types and needle diameters.
Methods
Two experimental models were employed. The Tissue Damage Model pierced 10 abdominal and 10 cheek skin samples using TP and RC needles. Histologic impact on skin layers was analyzed. The Anastomosis Leakage Model measured fluid leakage after 30 porcine aortas were punctured by TP and RC needles of varying diameters in an ex vivo pulsatile flow system. Both experiments ensured controlled variables and consistent methodologies.
Results
In the Tissue Damage Model, RC needles caused twice as much dermal disruption in both abdominal and cheek skin as TP needles (p < 0.01). Abdominal skin exhibited twice the histological damage compared to facial skin, irrespective of needle geometry (p < 0.05).
In the Anastomosis Leakage Model, RC needles caused 5.6-, 4.0-, and 8.7-fold more leakage than TP needles at small, medium, and large needle diameters, respectively (p < 0.002). Leakage from RC needles increased with needle diameter (p < 0.001). TP needles did not exhibit this effect.
Conclusion
RC needles caused significantly more dermal disruption compared to TP needles. Greater tissue damage was observed in abdominal skin than in facial skin. Additionally, RC needles led to progressively higher fluid leakage as needle diameter increased, while TP needles did not.
Publication History
Received: 23 July 2025
Accepted: 03 November 2025
Article published online:
28 November 2025
© 2025. Thieme. All rights reserved.
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References
- 1 Champaneria MC, Workman AD, Gupta SC. Sushruta: Father of plastic surgery. Ann Plast Surg 2014; 73 (01) 2-7
- 2 Bennett RG. Selection of wound closure materials. J Am Acad Dermatol 1988; 18 (4 Pt 1): 619-637
- 3 Lourie GM, Seaber AV, Urbaniak JR. Microanastomotic response to needle and suture size. J Reconstr Microsurg 1984; 1 (02) 135-138
- 4 Oldfield MJ, Leibinger A, Seah TE, Rodriguez Y Baena F. Method to reduce target motion through needle-tissue interactions. Ann Biomed Eng 2015; 43 (11) 2794-2803
- 5 van Gerwen DJ, Dankelman J, van den Dobbelsteen JJ. Needle-tissue interaction forces–a survey of experimental data. Med Eng Phys 2012; 34 (06) 665-680
- 6 Ethicon Incorporated. . Wound Closure Manual. 2005. Accessed March 17, 2025. Available at: https://anwresidency.com/simulation/guide/resources/Ethicon_Wound_Closure_manual.pdf
- 7 Byrne M, Aly A. The surgical needle. Aesthet Surg J 2019; 39 (Suppl. 02) S73-S77
- 8 Sergeant P, Kocharian R, Patel B, Pfefferkorn M, Matonick J. Needle-to-suture ratio, as well as suture material, impacts needle-hole bleeding in vascular anastomoses. Interact Cardiovasc Thorac Surg 2016; 22 (06) 813-816
- 9 Mitsou K, Papazoglou LG, Savvas I, Tzimtzimis E. Investigation of leakage holes created by four needle types used for closure of canine enterotomies. Open Vet J 2018; 8 (04) 411-414
- 10 Podder T, Clark D, Sherman J. et al. Vivo motion and force measurement of surgical needle intervention during prostate brachytherapy. Med Phys 2006; 33 (08) 2915-2922
- 11 Podder T, Sherman J, Fuller D. et al. In-vivo Measurement of Surgical Needle Intervention Parameters: A Pilot Study. Paper presented at: Annual International Conference of the IEEE Engineering in Medicine and Biology Society IEEE Engineering in Medicine and Biology Society Conference. 2006: 3652-3655 . Accessed March 17, 2025. Available at: https://ieeexplore.ieee.org/document/4462589
- 12 Okuno D, Togawa T, Saito H, Tsuchiya K. Development of an automatic blood sampling system: Control of the puncturing needle by measuring forces. 1998 ;4: 1811-1812 . Accessed March 17, 2025. Available at: https://ieeexplore.ieee.org/document/746941
- 13 Jackson RC, Cavuşoğlu MC. Modeling of needle-tissue interaction forces during surgical suturing. IEEE Int Conf Robot Autom 2012; 2012: 4675-4680
- 14 Min SH, Cho YS, Park K. et al. Multi-DOF (degree of freedom) articulating laparoscopic instrument is an effective device in performing challenging sutures. J Minim Invasive Surg 2019; 22 (04) 157-163
- 15 Ishikawa N, Watanabe G, Hirano Y, Inaki N, Kawachi K, Oda M. Robotic dexterity: evaluation of three-dimensional monitoring system and non-dominant hand maneuverability in robotic surgery. J Robot Surg 2007; 1 (03) 231-233
- 16 Ishikawa N, Watanabe G, Inaki N, Moriyama H, Shimada M, Kawaguchi M. The da Vinci surgical system versus the radius surgical system. Surg Sci 2012; 3: 358-361
- 17 Man J, Hrabe J. Anastomotic technique-How to optimize success and minimize leak rates. Clin Colon Rectal Surg 2021; 34 (06) 371-378
- 18 Kouba DJ, Tierney E, Mahmoud BH, Woo D. Optimizing closure materials for upper lid blepharoplasty: A randomized, controlled trial. Dermatol Surg 2011; 37 (01) 19-30
- 19 Zolotov A, Isokov S, Isokova A. The optimal surgical needle for tendon suture: Cutting edge or reverse cutting edge?. Traumatol Orthoped Russia 2021; 27: 75-80
- 20 Maloney ME, Potter CT, Chun BD, Montilla RD, Schanbacher CF. Comparative analysis of taper point and reverse cutting needles on skin puncture force. Dermatol Surg 2025; 51 (02) 144-147
- 21 Bernstein G. Needle basics. J Dermatol Surg Oncol 1985; 11 (12) 1177-1178
- 22 Thacker JG, Rodeheaver GT, Towler MA, Edlich RF. Surgical needle sharpness. Am J Surg 1989; 157 (03) 334-339
- 23 Towler MA, McGregor W, Rodeheaver GT. et al. Influence of cutting edge configuration on surgical needle penetration forces. J Emerg Med 1988; 6 (06) 475-481
- 24 Potter CT, Maloney ME, Riopelle AM, Fudem GM, Schanbacher CF. Impact of needle design and suture gauge on tissue tearing during skin suturing: A comparative analysis. Dermatol Surg 2025; 51 (02) 148-151
- 25 Casanova F, Carney PR, Sarntinoranont M. Effect of needle insertion speed on tissue injury, stress, and backflow distribution for convection-enhanced delivery in the rat brain. PLoS ONE 2014; 9 (04) e94919
- 26 Jiang S, Li P, Yu Y, Liu J, Yang Z. Experimental study of needle-tissue interaction forces: effect of needle geometries, insertion methods and tissue characteristics. J Biomech 2014; 47 (13) 3344-3353
- 27 Xiong MY, Bennett RG. Correlation of suture diameter with its ability to cut through an artificial skin model. Dermatol Surg 2021; 47 (04) 480-482
- 28 Usansky I, Jaworska P, Asti L. et al. A developmental basis for the anatomical diversity of dermis in homeostasis and wound repair. J Pathol 2021; 253 (03) 315-325
- 29 Kudur MH, Pai SB, Sripathi H, Prabhu S. Sutures and suturing techniques in skin closure. Indian J Dermatol Venereol Leprol 2009; 75 (04) 425-434
- 30 Firestone DE, Lauder AJ. Chemistry and mechanics of commonly used sutures and needles. J Hand Surg Am 2010; 35 (03) 486-488 , quiz 488
- 31 Pedram SA, Ferguson P, Ma J, Dutson E, Rosen J. Autonomous suturing via surgical robot: An algorithm for optimal selection of needle diameter, shape, and path. Paper presented at: 2017 IEEE International Conference on robotics and Automation (ICRA); 2017: 2391-2398 . Accessed March 18, 2025. Available at: https://ieeexplore.ieee.org/document/7989278
- 32 Chu CC, von Fraunhofer JA, Greisler HP. Wound Closure Biomaterials and Devices. Taylor & Francis; 1997. . Accessed March 18, 2025. Available at: https://api.pageplace.de/preview/DT0400.9781351404006_A37925208/preview-9781351404006_A37925208.pdf
- 33 Halabian M, Beigzadeh B, Karimi A, Shirazi HA, Shaali MH. A combination of experimental and finite element analyses of needle-tissue interaction to compute the stresses and deformations during injection at different angles. J Clin Monit Comput 2016; 30 (06) 965-975
- 34 Patel K, Hutapea P. Study of tissue damage induced by insertion of composite-coated needle. Med Eng Phys 2024; 123: 104094
- 35 Rodrigues SP, Horeman T, Dankelman J, van den Dobbelsteen JJ, Jansen FW. Suturing intraabdominal organs: When do we cause tissue damage?. Surg Endosc 2012; 26 (04) 1005-1009
- 36 Gambichler T, Matip R, Moussa G, Altmeyer P, Hoffmann K. In vivo data of epidermal thickness evaluated by optical coherence tomography: Effects of age, gender, skin type, and anatomic site. J Dermatol Sci 2006; 44 (03) 145-152
- 37 Huang J, Heng S, Zhang W. et al. Dermal extracellular matrix molecules in skin development, homeostasis, wound regeneration and diseases. Semin Cell Dev Biol 2022; 128: 137-144
- 38 Agarwal P, Zwolanek D, Keene DR. et al. Collagen XII and XIV, new partners of cartilage oligomeric matrix protein in the skin extracellular matrix suprastructure. J Biol Chem 2012; 287 (27) 22549-22559
- 39 Kleiser S, Nyström A. Interplay between cell-surface receptors and extracellular matrix in skin. Biomolecules 2020; 10 (08) 1170
- 40 Derraik JG, Rademaker M, Cutfield WS. et al. Effects of age, gender, BMI, and anatomical site on skin thickness in children and adults with diabetes. PLoS ONE 2014; 9 (01) e86637
- 41 Chopra K, Calva D, Sosin M. et al. A comprehensive examination of topographic thickness of skin in the human face. Aesthet Surg J 2015; 35 (08) 1007-1013
- 42 Riopelle AM, Jeong D, Boyd AY, Schanbacher CF. Reconstruction of high-tension scalp defects by the Twizzler technique: A retrospective case series. Dermatol Surg 2023; 49 (09) 832-837
- 43 Liu H, Hu M, Rao M, Li F, Zhang Q, Tang X. Effectiveness of stepwise progressive ultra-tension-reducing suture method in treatment of high-tension wounds on chest, back, and limbs. Zhongguo Xiu Fu Chong Jian Wai Ke Za Zhi 2024; 38 (12) 1505-1509
- 44 Potter CT, Camargo AM, Cecere RA, Wang A, Schanbacher CF. The Twizzler: a modified primary closure for distal lower extremity wound reconstruction utilizing a dynamic winch stitch. Dermatol Online J 2021; 27 (12) 19-24
- 45 Frick TB, Marucci DD, Cartmill JA, Martin CJ, Walsh WR. Resistance forces acting on suture needles. J Biomech 2001; 34 (10) 1335-1340
- 46 Hoard MA, Bellian KT, Powell DM, Edlich RF. Biomechanical performance of tapercut needles for oral surgery. J Oral Maxillofac Surg 1991; 49 (11) 1198-1203
- 47 Gantwerker EA, Hom DB. Principles to minimize scars. Facial Plast Surg 2012; 28 (05) 473-486