Meniscal sutures: biomechanical study of “mulberry” and horizontal loop techniques
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This in vitro biomechanical study tested the pullout strength of meniscal repair in human menisci using two different biodegradable suture techniques: the “mulberry” and the horizontal loop.
Materials and methods
Fifty-five human menisci were used, to which a longitudinal tear of 1.5 cm was applied. If the thread broke or the knot was pulled inside the suture, as happened with the mulberry technique, the repair was considered a failure. Furthermore, we evaluated possible lesions of the meniscus due to changes the structural properties caused by the suture, leading to the loss of elastic return.
The results showed there was a statistically significant difference between the two suture techniques used and the unsutured menisci. Furthermore, five menisci with vertical sutures were analyzed for which the breakup loads were superior to the breakup loads of the mulberry suture and the horizontal loop suture. Nevertheless, the load strengths with respect to elastic return were similar to those of the mulberry and the horizontal loop techniques. Finally, in five menisci, we analyzed the suture–healthy meniscus interface, and found breakup values similar to those of the unsutured meniscus.
Our results show the need to perform meniscal sutures and the futility of sutures that are intended to withstand elevated loads such as traction strengths of >30 N, as these produce irreparable secondary lesions that alter the histological structure of the meniscus and prevent healing.
KeywordsArthroscopy Meniscus Sutures Loop Mulberry
Normal menisci protect the joint cartilage by distributing loads over a broad and congruent area in order to guarantee stability and correct movements of the joint surfaces, lubricating and nourishing them [1, 2, 3, 4]; moreover they provide propioceptive information .
The decision to repair a meniscus is preferable, but it is necessary to carefully evaluate several aspects, such as the type of injury, the site, the quality of the tissue, the patient’s age, and the blood supply. Analysis of these factors allows us to foresee the recovery potential of the injury and to exclude recurrences.
Arnoczky and Warren’s  studies have given us an insight into the meniscal microvascular distribution. Meniscal repair is directly correlated with the degree of vascularization and the ability to generate an inflammatory-type healing response, which is a physiopathological mechanism that depends strongly on the patient’s age. Radial injuries that extend as far as the vascularized synovial need at least ten weeks to heal, while the scar needs several months to become fibrocartilage [2, 7]. This situation has led to a debate over whether it is advisable to use reabsorbable devices, especially in cases where an accelerated postoperative rehabilitation protocol has been chosen .
Various techniques are available for meniscal repair: “in–out,” “out–in,” and “all inside.”
Some reports in the literature indicate tensile breakage strengths of 115 N for vertical loop sutures, 75 N for horizontal loop sutures, and only 38 N for biodegradable arrows [9, 10, 11]. Other authors  report different data: 63.7 N for the single vertical loop stitch and 29.3 N for the horizontal loop suture. Considering the lack of accord among the available data and the greater reliability of sutures compared to arrows, the aim of this study was to compare the breakage tensile strengths of two simple and effective arthroscopic suture techniques: the “mulberry” method, as first described by Cooper, Arnoczky and Warren in 1990 , and the horizontal loop technique, as described by Johnson in 1995  (both can be performed with either the in–out or the out–in technique). Furthermore, the study took into consideration possible methods of making this type of suture more reliable.
Materials and methods
Fifty-five human menisci with intact capsules and no evidence of previous injury or degenerative changes were examined.
A broken thread was considered a failed suture; moreover, when the knot doubled up in the meniscus in the mulberry suture, this was also considered a failure. We used an unsutured meniscus as a control, and we analyzed the tensile behavior of the zone interposed between the first suture and healthy meniscus (the healthy meniscus–suture interface, for both mulberry and for horizontal loop sutures) by determining the force needed to produced a significant lesion or meniscal rupture. The results of such tests are important for evaluating the best zone in which to place a suture.
The aim of the study was to establish which suture was the most resistant to traction. Furthermore, we measured the maximum load that can be applied while preserving the structural properties of the meniscus without the suture causing secondary lesions (an event defined as “elastic return”).
Finally, we evaluated the best suture position and defined the concept of a “healthy meniscus–suture interface.”
Rupture load and elastic return values (expressed in newtons) for the menisci sutured using the mulberry technique, the horizontal loop technique, or the vertical loop technique, as well as the injured and unsutured menisci and the healthy meniscus–suture interface (H–M Int)
Mean traction load
26.22 ± 2.03
25.83 ± 2.04
18.99 ± 0.16
25.9 ± 2.08
19.45 ± 0.22
94.09 ± 6.77
105.33 ± 5.71
38.85 ± 0.93
123.8 ± 3.08
40.86 ± 2.11
Comparison of behavior
Mulberry versus horizontal loop: rupture
Mulberry versus horizontal loop: elastic return
Mulberry versus no suture: rupture
Horizontal loop versus no suture: rupture
Horizontal loop versus no suture: elastic return
Mulberry versus no suture: elastic return
No suture versus H–M interface: elastic return
No suture versus H–M interface: rupture
Mulberry versus vertical loop: elastic return
Vertical loop versus horizontal loop: elastic return
Mulberry versus vertical loop: rupture
Horizontal loop versus vertical loop: rupture
When the elastic return is considered, the traction loads applied to the mulberry suture and the unsutured meniscus were found to be statistically significantly different (26.22 ± 2.03 vs. 18.99 ± 0.16, p < 0.005), as were the traction loads applied to the horizontal loop suture and the unsutured meniscus (25.83 ± 2.04 vs. 18.99 ± 0.16, p < 0.005). Five menisci with vertical sutures were also analyzed, and their break loads were found to be 123.8 ± 3.08 N, similar to data reported in literature [10, 11, 12, 13, 14], and greater than the break loads of the menisci sutured using the mulberry (statistically significant difference: p < 0.05) and the horizontal loop (no statistically significant difference: p = 0.08) techniques. However, the load strength for elastic return of the menisci sutured using the vertical loop method was 25.9 ± 2.08 N, similar to those of the mulberry and the horizontal loop techniques (no statistically significant difference: p > 0.05). Finally, the healthy meniscus–suture interface was evaluated in five menisci, which presented a breakage value of 40.86 ± 2.11 N and an elastic return of 19.45 ± 0.22 N, neither of which were significantly different from the corresponding values for the unsutured meniscus (p > 0.05 for both assessments).
Much has changed in the last few years with regards to meniscal repair, due to our enhanced knowledge of the role of menisci as well as improvements in surgical techniques.
In the literature, there is much debate over whether to use the horizontal or vertical loop suture techniques. Some authors  have observed no differences in tension between vertical and horizontal sutures, whereas others believe that horizontal sutures are less effective (less than 25% of the rupture strength of vertical sutures) . Numerous studies have reported that vertical sutures for meniscal repair provide superior load to failure compared to horizontal sutures [10, 15, 18, 19, 20]. This could be because the vertical loop captures a greater proportion of the semicircularly oriented meniscal collagen fibers.
Song et al.  obtained a superior load to failure with vertical sutures (113.9 ± 14.6 N) compared to horizontal sutures (75.1 ± 18.4 N) using a 0-PDS suture in a porcine model.
Post et al.  used a young porcine medial and a lateral meniscus model and reported that the load to failure using vertical sutures (146.3 ± 17.1 N) and (115.9 ± 28.5 N), respectively, was superior to that obtained with horizontal sutures (73.81 ± 31.3 N) and (66.1 ± 28.7 N) when 1-PDS and 0-PDS were used, respectively. Additionally, they reported comparable load to failure results for repairs using horizontal sutures regardless of whether 2–0 Ethibond (59.7 ± 20.4 N), 0-PDS (66.1 ± 28.7 N), or 1-PDS (73.81 ± 31.3 N) were used as suture materials. The selected suture material made a greater contribution to the fixation when vertical sutures were used, with 1-PDS sutures (146.3 ± 17.1 N) showing superior load to failure compared to 0-PDS sutures (115.9 ± 28.5 N).
Kocabey  reported that the mean loads to failure of oblique (171.9 ± 25.9 N) and vertical loop (145.9 ± 32.3 N) sutures were not statistically different. The 18% difference in favor of the oblique suture is probably due to the fact that a greater meniscal area is sutured, together with a greater percentage of horizontal fibers.
Another debatable point concerns the use of absorbable or nonabsorbable thread; the first is more elastic and risks being absorbed before the injury has healed, while the second is more rigid and offers greater stability, allowing early and rapid rehabilitation , although it remains as a permanent foreign body in the suture site, and may therefore cause secondary lesions later on.
Noting Post’s studies  and the implications of using nonabsorbable thread, we chose to use MAXON 2-0, (monofilament polyglyconate synthetic absorbable suture) for all techniques. Size is an important factor in mini-invasiveness, as the use of a finer thread allowed us to use 21G needles, which are less traumatic than the needles used previously (18G), leading to high values of resistance to traction. These considerations mainly apply to the mulberry technique, where the 18G needle made a passage big enough for a knot to pass through, ultimately resulting in the failure of the suture. The 21G needle allowed us to reduce the size of the knot (one double and two single knots) in order to avoid creating a foreign body within the joint, which could be traumatic for the cartilage.
Finally, in five menisci, the area between the suture and the extremity of the lesion, which we defined as the healthy meniscus–suture interface, was evaluated and presented a rupture value of 40.86 ± 2.11 N and an elastic return of 19.45 ± 0.22 N, which were not statistically significantly different from the values for unsutured menisci (p > 0.05 for both measurements). These further assessments led us to consider the healthy meniscus–suture interface to be similar to an unsutured lesion—a weak point that can be corrected by drawing the suture as close as possible to the healthy meniscus. We believe that it is necessary to not only perform a meniscal repair but also pay much attention to where the suture is applied, thereby identifying the weakness area in between the first suture and non-damaged meniscus.
Respecting anatomical and biomechanical principles, our experiments have highlighted the fundamental features and requisites needed to achieve a meniscal suture that allows the injured tissue to heal and the lost structural integrity to recover.
We can now claim that the first factor to consider is the anatomical position at which to perform the suture. In fact, it is necessary to try and draw the suture as close as possible to the healthy meniscus, reducing the space defined as the healthy meniscus–suture interface, as it is an out-and-out weak point when applying the load force. Considering the loss of structural and elastic properties of the meniscus in the presence of traction loads lower than those needed for breakage, and the risk of secondary lesions due to certain load levels, it is understandable why it is necessary and advantageous to draw together only the edges of the meniscal lesion, respecting the physiopathological processes at the root of the healing process. The biomechanical principle according to us is not that of a “quantitative” suture which can withstand high traction loads, but rather a “qualitative” one which is placed correctly and has a certain level of manageability that can grant the necessary healing time. According to these concepts, we do not believe in accelerated rehabilitation, as this could invalidate, complicate, and slow down the healing mechanisms that the meniscus implements, accelerating degenerative processes and possibly causing secondary lesions due to the suture.
As far as the technique is concerned, it would be advisable to choose a slowly absorbable suture capable of offering meniscal stability and withstanding hydrolysis to a sufficient degree, so that it does not yield before the slow healing and recovery process has occurred. It is preferable to use 21G needles of a reduced size, bearing in mind both the mini-invasive approach and the effort that should be expended to reduce the knots, which are potentially harmful to the intra-articular knee structures.
To date, our studies and the literature have not unambiguously identified a particular suture that will withstand both the vertical and the circumferential traction forces which normally occur within the knee, but we feel that the characteristics we have suggested and tested scientifically could provide the foundation for a successful technique.
A simple and mini-invasive technique aimed at drawing together the borders of the tear in an anatomic fashion, reducing the healthy suture–meniscus interface, and respecting the time needed for healing to set in, as well as the use of biodegradable thread and the performance of a biomechanical analysis of the forces within the knee that are unloaded to the meniscus are the basic concepts of meniscal suture. In conclusion, the mulberry-type suture fits well with the abovementioned criteria, which is why we prefer it to the other techniques.
In future studies, we will assess the follow-up in patients with mulberry sutures, evaluate the traction loads both perpendicular and circumferential to the tear in different types of sutures, including biodegradable arrows, and perform a microscopic analysis in order to better understand the three-dimensional histologic structure that can be altered by the suture itself.
Conflict of interest
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