Subscribe to RSS
DOI: 10.1055/s-0040-1709453
Large and Uneven Bites in End-to-End Anastomosis of the Rat Femoral Artery
Funding This project was funded in part by a Surgical Specialties Corporation grant to the Microsurgery Training and Research Laboratory at the Columbia University Irving Medical Center.Publication History
23 September 2019
23 February 2020
Publication Date:
17 April 2020 (online)
Abstract
Background Successful microvascular anastomosis depends on sutures that adequately oppose both cut vessel edges. Trainees tend to take oversized or uneven bite. To improve early microsurgical skill acquisition using the rat, this study tests the belief that such bites compromise early patency by applying exaggerated bites to end-to-end arterial anastomoses.
Methods Twelve Sprague–Dawley rats were randomly assigned to one of the four bite techniques to be applied to both femoral arteries (mean diameter, 0.8 mm). Large (L) and standard (S) bites measured 1.0 and 0.2 mm from the edge, respectively. Eight simple interrupted anastomoses were performed per bite technique, each labeled according to every proximal end bite size, followed by every distal end bite size: LL, LS, SL, and SS. Anastomosis time and blood flow rates were recorded and analyzed statistically. After sacrifice 5 days postoperation, anastomosis sections of each technique were examined histologically.
Results All 24 anastomoses (100%) maintained patency for 5 days. There was no statistical difference between all postoperative blood flow measurements at any given time. Anastomosis times using LL, LS, SL, and SS bite techniques were 41.6, 33.2, 34.8, and 25.5 minutes, respectively. Anastomosis time for the traditional bite technique (SS) was significantly shorter than all other bite techniques (p < 0.05). Histological examination of the harvested segments from each group revealed similar pathophysiological features.
Conclusion Oversized bites (1 mm), placed symmetrically and asymmetrically across the anastomosis, do not affect early patency in the rat femoral artery. A reduced reliance on conventional guidelines for suture bites appears acceptable during microarterial anastomoses if the goal is vessel patency. However, we believe clinical competence involves the ability to place small, even bites consistently and uniformly. During microsurgical training, the occasional large bite need not be replaced; however, the trainee should be encouraged to take standard bites.
-
References
- 1 Griffin JR, Thornton JF. Microsurgery: free tissue transfer and replantation. Select Read Plast Surg 2005; 10 (05) 1-41
- 2 Ozkan O, Ozgentaş HE. Open guide suture technique for safe microvascular anastomosis. Ann Plast Surg 2005; 55 (03) 289-291
- 3 McKinnon VE, Kalun P, McRae MH, Sonnadara RR, Fahim C. A shift on the horizon: asystematic review of assessment tools for plastic surgery trainees. Plast Reconstr Surg 2018; 142 (02) 217e-231e
- 4 El Tecle NE, El Ahmadieh TY, Daou MR, Abecassis IJ, Rahme RJ, Bendok BR. Enhancing microsurgical skills through deliberate practice. World Neurosurg 2013; 80 (3-4): 229-230
- 5 Wain RA, Hammond D, McPhillips M, Whitty JP, Ahmed W. Microarterial anastomoses: aparameterised computational study examining the effect of suture position on intravascular blood flow. Microvasc Res 2016; 105: 141-148
- 6 Isogai N, Kamiishi H, Chichibu S. Re-endothelialization stages at the microvascular anastomosis. Microsurgery 1988; 9 (02) 87-94
- 7 Stone JP, Doherty CC, Schrag CH. Incidence and type of errors in microsurgical technique in surgical trainees. J Reconstr Microsurg 2016; 32 (07) 528-532
- 8 Schaverien MV, Liu J, Butler CE, Selber JC. Factors correlating with microsurgical performance: aclinical and experimental study. J Surg Educ 2018; 75 (04) 1045-1051
- 9 Selber JC, Chang EI, Liu J. , et al. Tracking the learning curve in microsurgical skill acquisition. Plast Reconstr Surg 2012; 130 (04) 550e-557e
- 10 Osgood CP, Dujovny M, Faille R, Barrionuevo PJ, Longa EZ, Matta R. Early scanning electron microscopic evaluation of microvascular maneuvers. Angiology 1976; 27 (02) 96-105
- 11 Cooley BC. A Laboratory Manual for Microvascular and Microtubal Surgery. 2nd ed. Reading, PA: Surgical Specialties Corporation; 2009
- 12 Guity A, Young PH, Fischer VW. In search of the “perfect” anastomosis. Microsurgery 1990; 11 (01) 5-11
- 13 Dudley HA. Layered and mass closure of the abdominal wall. A theoretical and experimental analysis. Br J Surg 1970; 57 (09) 664-667
- 14 Nickell WB, Bartley TD, Hartley CS. Arteries and anastomoses--some basic controversies settled. Ann Thorac Surg 1969; 7 (03) 221-230
- 15 Gruber DD, Massengill JC, Lamb SV. , et al. Magnification effects on distance estimation during robotic suturing. J Robot Surg 2014; 8 (03) 233-238
- 16 Naides A, Noland R, Lu JG, Akelina Y, Marboe C, Strauch RJ. Histological changes in the rat femoral artery following the use of the empty-and-refill test. J Reconstr Microsurg 2018; 34 (04) 270-276
- 17 Shaughness G, Blackburn C, Ballestín A, Akelina Y, Ascherman JA. Predicting thrombosis formation in 1-mm-diameter arterial anastomoses with transit-time ultrasound technology. Plast Reconstr Surg 2017; 139 (06) 1400-1405
- 18 Nasir S, Aydin MA, Ozgüner M. Thrombotic effect of purposeful back-wall stitch for different suture locations and vessels in rats. Ann Plast Surg 2005; 55 (05) 508-511
- 19 Miyamoto S, Sakuraba M, Asano T. , et al. Optimal technique for microvascular anastomosis of very small vessels: comparative study of three techniques in a rat superficial inferior epigastric arterial flap model. J Plast Reconstr Aesthet Surg 2010; 63 (07) 1196-1201
- 20 Seki S. Accuracy of suture placement. Br J Surg 1987; 74 (03) 195-197
- 21 Sabapathy SR. Microsurgery techniques: vessels. In: Wei FC, Mardini S. , eds. Flaps and Reconstructive Surgery. 2nd ed. Edinburgh: Elsevier Inc; 2017: 310-322
- 22 Lidman D, Daniel RK. Evaluation of clinical microvascular anastomoses--reasons for failure. Ann Plast Surg 1981; 6 (03) 215-223
- 23 Furka I, Brath E, Nemeth N, Miko I. Learning microsurgical suturing and knotting techniques: comparative data. Microsurgery 2006; 26 (01) 4-7
- 24 Hayhurst JW, O'Brien BM. An experimental study of microvascular technique, patency rates and related factors. Br J Plast Surg 1975; 28 (02) 128-132
- 25 Mattox DE. Microvascular anastomosis: a scanning electron microscopic study. Otolaryngol Head Neck Surg (1979) 1980; 88 (03) 252-256
- 26 Decherd ME, Calhoun KH. The effect of tension on patency of rat femoral artery anastomoses. Arch Facial Plast Surg 2003; 5 (01) 83-85
- 27 Chow SP, Huang CD, Chan CW. Microvascular anastomosis of arteries under tension. Br J Plast Surg 1982; 35 (01) 82-87
- 28 Topalan M, Bilgin SS, Ip WY, Chow SP. Effect of torsion on microarterial anastomosis patency. Microsurgery 2003; 23 (01) 56-59
- 29 Harb A, Levi M, Kozato A, Akelina Y, Strauch RJ. Torsion does not affect early vein graft patency in the rat femoral artery model. J Reconstr Microsurg 2019; 35 (04) 299-305