Top

Knee Surgery, Sports Traumatology, Arthroscopy

Published in:

01-08-2008 | Experimental Study

Optimal configuration of arthroscopic sliding knots backed up with multiple half-hitches

Published in: Knee Surgery, Sports Traumatology, Arthroscopy | Issue 8/2008

Abstract

The purpose of this biomechanical study was to determine optimized configuration of additional half-hitches placed after various arthroscopic sliding knots. Four commonly used arthroscopic sliding knots, namely, the Duncan loop, the SMC, Weston, and SP knot, were included in this study. All knots were tied with a single-hole knot pusher using a knot-tying simulator. After tying a sliding knot, it was backed up with zero to four additional reverse half-hitches on alternating posts (RHAPs). The first half-hitch was either placed on the same post (conventional RHAP; c-RHAP) or on the loop limb of the sliding knot (switched RHAP; s-RHAP). Ten knots were tied in each configuration using No. 2 Ethibond or No. 1 PDSII sutures. Loop security (loop circumference at 5 N) and knot security (highest load to failure at a cross-head displacement of 3 mm) were measured. Knot configurations, number of RHAPs, or mode of placement of the first half-hitch did not make clinically significant effects on loop security for either suture type. Using No. 2 Ethibond sutures, SMC, SP, and Weston knots required at least three additional half-hitches before knot security plateaued. However, when the first half-hitch was switched to the loop limb of the sliding knot, only two additional half-hitches (2 s-RHAPs) were required to reach maximum knot security. Using No. 1 PDSII sutures, SMC knots needed one additional half-hitch to reach maximum knot security, whereas SP and Weston knots required two half-hitches. However, SMC, SP and Weston knots with switched first half-hitch only required one additional half-hitch (1 s-RHAP) to achieve maximum knot security. This study demonstrated that switching the post just after the sliding knot could save one half-hitch without compromising knot security. That means that sliding knots with 2 s-RHAPs for No. 2 Ethibond and 1 s-RHAPs for No. 1 PDSII achieved knot security comparable to that of sliding knots with 3 c-RHAPs and with 2 c-RHAPs, respectively. The results suggested that the optimized configuration for arthroscopic sliding knots required a secure sliding knot, such as, the SMC, SP, or Weston knots and 2 s-RHAPs when No. 2 Ethibond or No. 1 PDSII suture materials were used considering the unraveling tendency of No. 1 PDSII. Results of the current study may be helpful for establishing arthroscopic sliding knot-tying routines for best results in clinical practice.

Weston PV (1991) A new clinch knot. Obstet Gynecol 78:144–147PubMed

Delimar D (1996) A secure arthroscopic knot. Arthroscopy 12:345–347PubMedCrossRef

De Beer JF, van Rooyen K, Boezaart AP (1998) Nicky’s knot—a new slip knot for arthroscopic surgery. Arthroscopy 14:109–110PubMed

Fleega BA, Sokkar SH (1999) The Giant knot: a new one-way self-locking secured arthroscopic slip knot. Arthroscopy 15(4):451–452PubMed

Kim SH, Ha KI (2000) The SMC knot—a new slip knot with locking mechanism. Arthroscopy 16:563–565PubMedCrossRef

Field MH, Edwards B, Savoie FH (2001) Technical note: a new arthroscopic sliding knot. Orthop Clin Notrth Am 32:525–526CrossRef

Rolla PR, Surace MF (2002) The double-twist knot: a new arthroscopic sliding knot. Arthroscopy 18:815–820PubMed

Pallia CS (2003) The PC knot: a secure, satisfying arthroscopic slip knot. Arthroscopy 19:558–560PubMed

Wiley WB, Goradia VK (2004) The Tuckahoe knot: a secure locking slip knot. Arthroscopy 20:556–559PubMedCrossRef

10.

Jo CH, Yoon KS, Lee JH, Kang SB, Lee JH, Lee MC (2007) The slippage-proof knot: a new non-stacking arthroscopic sliding locking knot with a lag bight. Orthopedics 30:349PubMed

11.

Soper NJ, Hunter JG (1992) Suturing and knot tying in laparoscopy. Surg Clin North Am 72:1139–1152PubMed

12.

Loutzenheiser TD, Harryman DT II, Yung SW, France MP, Slidles JA (1995) Optimizing arthroscopic knots. Arthroscopy 11:199–206PubMedCrossRef

13.

Kim SH, Ha KI, Kim SH, Kim JS (2001) Significance of the internal locking mechanism for loop security enhancement in the arthroscopic knot. Arthroscopy 17:850–855PubMedCrossRef

14.

Chan KC, Burkhart SS, Thiagarajan P, Goh JCH (2001) Optimization of stacked half-hitch knots for arthroscopic surgery. Arthroscopy 17:752–759PubMedCrossRef

15.

Lo IKY, Burkhart SS, Chan KC, Athanasiou K (2004) Arthroscopic knots: determining the optimal balance of loop security and knot security. Arthroscopy 20:489–502PubMedCrossRef

16.

Hassinger SM, Montri DW, Hechanova JW (2006) Biomechanical characteristics of 10 arthroscopic knots. Arthroscopy 22:827–832PubMedCrossRef

17.

Loutzenheiser TD, Harryman DT II, Ziegler DW, Yung SW (1998) Optimizing arthroscopic knots using braded or monofilament suture. Arthroscopy 14:57–65PubMedCrossRef

18.

Burkhart SS, Wirth MA, Simonick M, Salem D, Lanctot D, Athanasiou K (1998) Loop security as a determinant of tissue fixation security. Arthroscopy 14:773–776PubMedCrossRef

19.

Lieurance RK, Pflaster DS, Abbott D, Nottage WM (2003) Failure characteristics of various arthroscopically tied knots. Clin Orthop Relat Res 408:311–318PubMedCrossRef

20.

Ilahi OA, Youna SA, Alexander JA et al (2004) Cyclic testing of arthroscopic knot security. Arthroscopy 20:62–68PubMedCrossRef

21.

Kim SH, Yoo JC, Wang JH, Choi KW, Bae TS, Lee CY (2005) Arthroscopic sliding knot: how many additional half-hitches are really needed? Arthroscopy 21:405–411PubMedCrossRef

22.

Trimbos JB (1984) Security of various knots commonly used in surgical practice. Obstet Gynecol 64:274–280PubMed

23.

Trimbos JB, Van Rijssel EJC, Klopper PJ (1986) Performance of sliding knots in monofilament and multifilament suture material. Obstet Gynecol 68:425–430PubMed

24.

Elkousy HA, Sekiya JK, Stabile KJ, McMahon PJ (2005) A biomechanical comparison of arthroscopic sliding and sliding-locking knots. Arthroscopy 21:204–210PubMedCrossRef

25.

Abbi G, Espinoza L, Odell T, Mahar A, Pedowitz R (2006) Evaluation of 5 knots and 2 suture materials for arthroscopic rotator cuff repair: very strong sutures can still slip. Arthroscopy 22:38–43PubMedCrossRef

26.

Snyder SJ (1994) Technical manual for the Revo screw and knot. Linvatec Corp., Largo, FL

27.

Hermann JB (1971) Tensile strength and knot security of surgical suture materials. Am Surgeon 37:209–217

28.

Babetty Z, Sumer A, Altintas S, Ergueny S, Goksel S (1998) Changes in knot-holding capacity of sliding knots in vivo and tissue reaction. Arch Surg 133:727–734PubMedCrossRef

Title: Optimal configuration of arthroscopic sliding knots backed up with multiple half-hitches
Publication date: 01-08-2008
Published in: Knee Surgery, Sports Traumatology, Arthroscopy / Issue 8/2008
Print ISSN: 0942-2056
Electronic ISSN: 1433-7347
DOI: https://doi.org/10.1007/s00167-008-0497-y

At a glance: The ONWARDS insulin icodec trials

Springer Medicine

Optimal configuration of arthroscopic sliding knots backed up with multiple half-hitches

Abstract

At a glance: The ONWARDS insulin icodec trials

Springer Medicine

Abstract

Please log in to get access to this content

Other articles of this Issue 8/2008

Neovascularisation in de Quervain’s disease of the wrist: novel combined therapy using sclerosing therapy with polidocanol and eccentric training of the forearms and wrists—a pilot report

Determining knee joint alignment using digital photographs

Active non-operative treatment of acute isolated posterior cruciate ligament injury with cylinder cast immobilization

Limited ankle dorsiflexion: a predisposing factor to Morbus Osgood Schlatter?

Simultaneous anterior and posterior cruciate ligament reconstruction in chronic knee instabilities: surgical concepts and clinical outcome

Lipoma arborescens of the glenohumeral joint: a possible cause of osteoarthritis