Repair & Augmentation

The healing potential of the meniscus has been well recognised since experiments by King in 1936 and it is well known that meniscal preservation reduces risk of osteoarthritis. Suturing techniques are the gold standard for meniscal repair with success rates reported between 80-95%. All inside purely arthroscopic suturing techniques have comparable repair strength and success rates to inside-out techniques.

Meniscus repair should be undertaken if a clinical case for meniscal preservation exists, even if the appearances are not those classically recommended and supplemented with augmentation techniques

Meniscal Repair

Classical indications for Repair

All-inside plus Outside-In repair
Meniscal repair is classically performed for a longitudinal traumatic tear within the peripheral 10-30% of a healthy meniscus. The tear should be >1cm and repair is not indicated for incomplete tears. The knee should be stable or a concomitant ligament reconstruction should be performed.

Surgical decision making

Quite often the tears are not classical. Hence often one would have to repair the meniscus if there is a clinical case for saving the meniscus.

When to extend the indications?

  1. Young patients
  2. Acute longitudinal tear in the white-white area but still in the peripheral third that would otherwise result in resection of a large volume of meniscus
  3. Chronic tear in the periphery (combine with augmentation techniques)
  4. Large radial tear extending to peripheral rim

Techniques

Open Repair

Occasionally indicated in the anterior capsular tear in association with Tibial Plateau Fractures or whilst doing an Acute Open Ligament repair. (See picture of Acute Posterolateral corner injury with capsular meniscal tear).

Arthroscopic Repair

Inside Out

Traditionally Gold Standard but unnecessary and difficult technique with only marginal improvement in load to failure and shear strength compared to all inside suturing. Henning popularised this technique in the 1980s. It is performed using zone specific cannulas and nonabsorbable sutures with a flexible long needle on either end. Make a small incision besides the exit point of the suture and dissect down with small curved scissors and hook the suture material into the wound to retrieve the sutures. Avoid making an incision directly on the exit point of the suture to avoid dividing the suture material. For more posterior repairs it may be safer to make a single larger incisions for safe dissection down to capsule to protect the nerves. If one is making a single large incision, it is placed posterior to the collateral ligament. A combination of superior and inferiorly placed sutures may be necessary to avoid meniscal eversion.

The structures commonly at risk are the saphenous nerve medially and the common peroneal nerve laterally. The popliteal vessels and tibial nerve can also be at risk. The knot should be tied directly on the capsule to avoid entrapping the nerve.

Outside in

No longer recommended. A suture is passed outside-in via a spinal needle across the tear. The suture is then pulled through an arthroscopy portal, a knot placed and then the knot is then pulled back against the meniscus and a further knot placed on the outside.

All inside

The newer all-inside sutures have comparable load to failure strength, shear strength and gapping to conventional vertical mattress sutures. Gapping is low with arrows but they fail early due to pull out from the rim.

First Generation:

  • Meniscal Arrow (Bionx implants)
  • Sharp shooter (Linvatec)- PLLA
  • Clearfix (Mitek)- PLLA
  • Arthrotek Meniscal screw(Biomet)

Second Generation:

  • FasT-Fix- Smith & Nephew
  • Ultra FasT-Fix- UltraBraid suture 2-0
  • Rapidloc- Mitek- Ethibond or Panacryl suture 2-0
  • Viper system- Arthrex- Fibrewire 2-0

 

Device Author

Load To

Failure (N)

Shear (N) Gapping (mm) Failure
Arthrotek Barber 28.9 Pull Out
Arrow

Kocabey

McDermott

Rankin

39.755

34.2

95.9

27.67 2.18

Rim

Pull Out

T Fix

Kocabey

McDermott

Rankin

45.892

49.1

99.4

57.47 3.47
RapidLok Barber 43.28

Backstop

or Suture

FasT-Fix

Barber

Chang

70.9

145.9

3.9 Knot
Viper Chang 111.2 3.9
Suture

Mcdermott

Rankin

Chang

107.65

72.7

202

133.4

64.15

3.29

2.3

 

Video of peripheral tear of meniscus suitable for repair:

This video shows a peripheral meniscal tear of menicus being repaired using Fast fix:

This video shows the healed repair:

Suture type and placement

    Sutures are best placed 3-5mm apart 3mm from tear edge. Vertical or oblique sutures are preferable but Horizontal sutures using FasT-Fix have still shown good healing rates though the biomechanical strength maybe inferior.

    Horizontal vs vertical mattress

      Gapping: Vertical fast-Fix 3.2mm Horizontal 4.4mm RapidLoc 4.6mm
      Load to Failure: Vertical FasT-Fix 125.3N Horizontal 89.7N Rapidloc 87.1N
      (Kocabey Arthroscopy 2006)

      Oblique and vertical sutures had similar strengths on load to failure testing. Vertical fast-Fix better than horizontal FasT-Fix or RapidLoc.
      Nyland J, Chang H, Kocabey Y, Nawab A, Brand J, Caborn DN. A cyclic testing comparison of FasT-Fix and RapidLoc devices in human cadaveric meniscus.
      Arch Orthop Trauma Surg. 2008 May;128(5):489-94.

      Postoperative rehabilitation

        There are no good large prospective randomised studies to compare various rehabilitation programmes. In general restriction of flexion beyond 90 degrees is preferred to avoid shear forces on the meniscus. Similar forces also occur in the last few degrees of extension. Weight bearing is controversial. Both Shelbourne(1996) and Barber(1994) have shown satisfactory results with meniscal repair combined with accelerated rehabilitation. Hence it is recommended that accelerated rehabilitation be continued for meniscal repairs with concomitant ACL reconstruction. Most surgeons would still be more conservative in isolated meniscal repairs.

        Outcomes

          There are numerous studies with clinical follow-up showing good success rates. It is well known that there is a significant incidence of incomplete healing following meniscal repair. MRI scans and MR arthrograms are unreliable in the presence of previous meniscal repair.

          The following table shows the studies where a second look arthroscopy has been used for follow-up.

          Study Number Fixation Follow-up ACL Success
          Cannon and Vittori 90 Inside-out 10 mths

          Stable-22

          Recon-68

          50%

          93%

          Miller et al 79 Inside-out 3.25 yrs

          Stable

          Recon

          84%

          93%

          Morgan et al 74 Inside-out 8.5 mths Injured 84%
          Buseck and Noyes 66 Inside-out 1 yr Recon

          80% Complete

          14% Partial

          Tenuta and Arciero 54 Inside-out 11 mths

          Stable 14

          Recon 40

          57%

          90%

          Ahn 39 FasT-Fix 19 mths Recon 97.4%
          Horibe 132 Inside-out

          73% complete

          17% incomplete

          Meniscal repair healing rates are higher when performed with a concomitant ACL reconstruction. More importantly meniscal repair rates are inferior if performed in an unstable knee.

          Complications

          The complications with meniscal repair are mainly failure (10%) and incomplete healing (15%). There is a risk of Nerve injury (Saphenous, Peroneal or Tibial) and vascular injury. Cohen showed that the distance between the tip of the needle and the popliteal artery is between 0-2mm if inserted to the hub of the needle.

          There is a risk of arthrofibrosis with concomitant ACL reconstruction (10%).

          References

            • Greis PE, Holmstrom MC, Bardana DD, Burks RT. Meniscal injury: II. Management.J Am Acad Orthop Surg. 2002 May-Jun;10(3):177-87. Review
            • Mesiha M, Zurakowski D, Soriano J, Nielson JH, Zarins B, Murray MM. Pathologic characteristics of the torn human meniscus. Am J Sports Med. 2007 Jan;35(1):103-12.
            • Boyd KT, Myers PT. Meniscus preservation; rationale, repair techniques and results. Knee. 2003 Mar;10(1):1-11. Review
            • Ahn JH, Wang JH, Yoo JC. Arthroscopic all-inside suture repair of medial meniscus lesion in anterior cruciate ligament–deficient knees: results of second-look arthroscopies in 39 cases. Arthroscopy. 2004 Nov;20(9):936-45
            • Haas AL, Schepsis AA, Hornstein J, Edgar CM. Meniscal repair using the FasT-Fix all-inside meniscal repair device. Arthroscopy. 2005 Feb;21(2):167-75.
            • Quinby JS, Golish SR, Hart JA, Diduch DR. All-inside meniscal repair using a new flexible, tensionable device. Am J Sports Med. 2006 Aug;34(8):1281-6.
            • Farng E, Sherman O. Meniscal repair devices: a clinical and biomechanical literature review. Arthroscopy. 2004 Mar;20(3):273-86. Review
            • Kimura M, Shirakura K, Hasegawa A, Kobuna Y, Niijima M. Second look arthroscopy after meniscal repair. Factors affecting the healing rate. Clin Orthop Relat Res. 1995 May;(314):185-91
            • Horibe S, Shino K, Nakata K, Maeda A, Nakamura N, Matsumoto N.Second-look arthroscopy after meniscal repair. Review of 132 menisci repaired by an arthroscopic inside-out technique. J Bone Joint Surg Br. 1995 Mar;77(2):245-9.
            • Uchio Y, Ochi M, Adachi N, Kawasaki K, Iwasa J.Results of rasping of meniscal tears with and without anterior cruciate ligament injury as evaluated by second-look arthroscopy. Arthroscopy. 2003 May-Jun;19(5):463-9
            • Noyes FR, Barber-Westin SD.Arthroscopic repair of meniscus tears extending into the avascular zone with or without anterior cruciate ligament reconstruction in patients 40 years of age and older. Arthroscopy. 2000 Nov;16(8):822-9
            • Rubman MH, Noyes FR, Barber-Westin SD. Arthroscopic repair of meniscal tears that extend into the avascular zone. A review of 198 single and complex tears. Am J Sports Med. 1998 Jan-Feb;26(1):87-95.
            • Cannon WD Jr, Vittori JM. The incidence of healing in arthroscopic meniscal repairs in anterior cruciate ligament-reconstructed knees versus stable knees. Am J Sports Med. 1992 Mar-Apr;20(2):176-81
              Rehabilitation
            • Shelbourne KD, Patel DV, Adsit WS, Porter DA. Rehabilitation after meniscal repair. Clin Sports Med. 1996 Jul;15(3):595-612. Review
            • Barber FA.Accelerated rehabilitation for meniscus repairs. Arthroscopy. 1994 Apr;10(2):206-10
            • Mariani PP, Santori N, Adriani E, Mastantuono M. Accelerated rehabilitation after arthroscopic meniscal repair: a clinical and magnetic resonance imaging evaluation. Arthroscopy. 1996 Dec;12(6):680-6.
              Complications
            • Small NC. Complications in arthroscopic surgery performed by experienced arthroscopists. Arthroscopy. 1988;4(3):215-21
            • Austin KS, Sherman OH. Complications of arthroscopic meniscal repair. Am J Sports Med. 1993 Nov-Dec;21(6):864-8
            • Cohen SB, Boyd L, Miller MD. Vascular risk associated with meniscal repair using Rapidloc versus FasT-Fix: comparison of two all-inside meniscal devices. J Knee Surg. 2007 Jul;20(3):235-40

            Augmentation

              Meniscal tears in the red-red zone have good vascularity and high healing potential with repair alone. Tears further away from the rim potentially benefit from repair along with augmentation techniques

              Augmentation techniques are useful during attempts to salvage meniscal tears in the avascular zone. They are also useful in the more chronic tears and whilst repairing tears in stable knees without concomitant ligament reconstruction.

              The techniques available to augment healing of meniscal tears are –

              1. Meniscal rasping
              2. Synovial abrasion
              3. Synovial graft
              4. Fibrin clot
              5. Meniscal trephining
              6. Microfracture
              7. Radiofrequency stimulation

              Meniscal Rasping

              Rasping the meniscal edges rather than the primeniscal synovium has also been shown to augment meniscal heling through the expression of cytokines.

              Uchio showed results of meniscal rasping without suturing in a retrospective study. Forty-eight meniscal tears treated arthroscopically with the meniscal rasping technique were evaluated by second-look arthroscopy. The interval between the injury and the time of surgery ranged from 3 weeks to 13 years. There were 35 lateral and 13 medial meniscal tears associated with 44 anterior cruciate ligament injuries; 28 of the menisci had a full-thickness longitudinal tear and the other 20 had a partial-thickness tear. The length of the tears ranged from 10 to 33 mm (mean, 14.4 mm). The distance from the capsule to the tear ranged from 1 to 9 mm (mean, 5.0 mm). There was 71% complete healing at second look arthroscopy. The distance of the tear site from the capsule, length and the stability of the tear affect healing potential.

              Ochi M, Uchio Y, Okuda K, Shu N, Yamaguchi H, Sakai Y. Expression of cytokines after meniscal rasping to promote meniscal healing. Arthroscopy. 2001 Sep;17(7):724-31

              Uchio Y, Ochi M, Adachi N, Kawasaki K, Iwasa J. Results of rasping of meniscal tears with and without anterior cruciate ligament injury as evaluated by second-look arthroscopy. Arthroscopy. 2003 May-Jun;19(5):463-9

              Okuda K, Ochi M, Shu N, Uchio Y. Meniscal rasping for repair of meniscal tear in the avascular zone. Arthroscopy. 1999 Apr;15(3):281-6.

              Synovial Abrasion

              This technique can be performed using a curved arthroscopic rasp or using a arthroscopic shaver (synovator). Access to the synovium in the posterior third can be achieved by displacing the meniscus fragment back towards the notch.

              Talley reported results from 44 partial stable meniscal tears that were treated with parameniscal synovial abrasion at the time of anterior cruciate ligament reconstruction. Meniscal repair was not performed. Four failures occurred in the medial meniscus (21% of total MM tears) and 1 failure occurred in the lateral meniscus (4% of total LM tears). The median time to failure was 12 months.

              Nachostine performed an animal study for avascular zone tears where the tears. They concluded that the distance from the periphery to the defect is too far for abrasion therapy to stimulate sufficient cellular ingrowth to facilitate repair of tears in the avascular region of the meniscus.

              Talley MC, Grana WA. Treatment of partial meniscal tears identified during anterior cruciate ligament reconstruction with limited synovial abrasion. Arthroscopy. 2000 Jan-Feb;16(1):6-10.

              McAndrews PT, Arnoczky SP. Meniscal repair enhancement techniques. Clin Sports Med. 1996 Jul;15(3):499-510.

              Nakhostine M, Gershuni DH, Anderson R, Danzig LA, Weiner GM. Effects of abrasion therapy on tears in the avascular region of sheep menisci. Arthroscopy. 1990;6(4):280-7.

              Synovial Graft

              Kimura performed a vascularized synovial pedicle flap to the suture site 7 tears in avascularized areas and all of them showed healing on second look arthroscopy. They performed repeat arthroscopy on 46 of 137 meniscal repairs. In patients with tears in avascularized areas, the conventional meniscal repairs showed a lower healing rate than did the repairs with a synovial pedicle transplantation or an anterior cruciate ligament reconstruction (p < 0.005).

              In an animal study, Jijsuiki performed meniscal repairs in the avascular zone on 34 rabbit knees. There were17 in the study group and 17 in the control group. In the study group, an interpositional free synovial autograft was sewn into the tear with a single horizontal suture. In the control group, the tear was repaired without synovium in the same manner. In the study group, the lesion completely healed by 4 weeks, except for one. The menisci in the control group never completely healed, particularly at the deeper levels of the lesion. Ochi showed similar beneficial effect of free synovial graft.

              Jitsuiki J, Ochi M, Ikuta Y. Meniscal repair enhanced by an interpositional free synovial autograft: an experimental study in rabbits. Arthroscopy. 1994 Dec;10(6):659-66.

              Kimura M, Shirakura K, Hasegawa A, Kobuna Y, Niijima M. Second look arthroscopy after meniscal repair. Factors affecting the healing rate. Clin Orthop Relat Res. 1995 May;(314):185-91.

              Ochi M, Mochizuki Y, Deie M, Ikuta Y. Augmented meniscal healing with free synovial autografts: an organ culture model. Arch Orthop Trauma Surg. 1996;115(3-4):123-6.

              Fibrin Clot

              Fibrin clot acts as a chemotactic and mitogenic stimulus for reparative cells and provides a scaffolding for the reparative process. The clot contains platelet-derived growth factor and fibronectin, which are chemotactic. They appear to stimulate local cell activity within the meniscus and to attract synovial cells.

              Arnoczky (1988) demonstrated that defects created in the avascular zone of menisci when filled with a fibrin clot healed through a proliferation of fibrous connective tissue that eventually modulated into fibrocartilaginous tissue. Control defects remained empty. The reparative tissue was morphologically similar to the reparative tissue that was observed in the vascular area of the meniscus.

              Technique of fibrin clot preparation

              Preparation of the clot in this setting is important; the clot should contain as little serum and red cells as possible. Generally, 50-60 ml of blood is spun in a glass container. The clot is removed from the glass stirring rod and inserted in a tube before placement in the tear after the ACL reconstruction. Tibial fixation of the graft is performed after placing the clot. If desired, the clot can be tied in place with a PDS suture.

              Sethi described a insitu technique of creating a fibrin clot. The synovium directly above the tear site is abraded with a shaver, rasp, or small intra-articular banana blade. Next, the water inflow cannula is closed, and the outflow cannula is opened to vacuum suctioning, allowing collapse of the distended joint. Under these circumstances, negative intra-articular pressure is produced in the knee joint. This condition is maintained for a period of 1 to 2 minutes and induces bleeding from the abraded synovial site. The knee in a dependent position causes the blood to run down the synovial wall and into the meniscal cleft, pooling there and forming a clot adherent to the edges of the separated meniscal tear. This procedure has been found to be a simple and minimally invasive mechanism for clot placement. The exposed collagen of the meniscal tear provides an ideal surface for a relatively tenacious clot attachment. It provides the healing factors reported to induce successful meniscal healing.

              Arnoczky SP, Warren RF, Spivak JM Meniscal repair using an exogenous fibrin clot. An experimental study in dogs. J Bone Joint Surg Am.1988 Sep;70(8):1209-17.

              Sethi PM, Cooper A, Jokl P. Technical tips in orthopaedics: meniscal repair with use of an in situ fibrin clot. Arthroscopy. 2003 May-Jun;19(5):E44.

              Port J, Simon TM, Jackson DW. Preparation of an exogenous fibrin clot. Arthroscopy. 1995 Jun;11(3):332-7.

              O’Meara PM. Surgical techniques for arthroscopic meniscal repair. Orthop Rev. 1993 Jul;22(7):781-90. Review.

              van Trommel MF, Simonian PT, Potter HG, Wickiewicz TL. Arthroscopic meniscal repair with fibrin clot of complete radial tears of the lateral meniscus in the avascular zone. Arthroscopy. 1998 May-Jun;14(4):360-5.

              McAndrews PT, Arnoczky SP. Meniscal repair enhancement techniques. Clin Sports Med. 1996 Jul;15(3):499-510.
              Trephination

              Trephination is a technique to create vascular access channels by removal of a core of tissue from the periphery of the meniscus to the tear, thus connecting a lesion in the avascular portion of the meniscus to the peripheral blood supply. The technique is performed through the arthroscopic prtals using a spinal needle. The channels are equally spaced with controlled depth of insertion, going through the rim portion of the meniscus.

              Zang showed in an animal study the proliferation of fibrochondrocyte in meniscal tears after trephining. In a further clinical study, thirty-six patients with meniscal tears underwent arthroscopic trephination plus suturing (group TS) and 28 patients had suturing alone (group S). The follow-up was 25 to 78 months. Two symptomatic retears have occurred in group TS and 7 symptomatic retears in group S. The symptomatic retear rate of group TS was significantly smaller than group S (P < .01). Trephination appeared to reduce clinical failure rate.

              Shelbourne reported good results in 332 lateral meniscus tears treated with abrasion or trephining but not repaired at the time of ACL reconstruction. Fox showed similar results with trephination and conservative treatment of meniscal tears.

              Biedert examined the effect of four different methods for treating intrasubstance meniscal lesions. Forty patients with an isolated and symptomatic painful horizontal grade 2 meniscal lesion on the medial side (documented with MRI) were included. Created vascular access channels appeared to give good success rates.

              Cook and Fox used a bioabsorbable vascular conduit for avascular meniscal tears. Based on histologic assessment, the conduit was associated with complete (n = 4) or partial (n = 5) healing in all avascular defects at 12 and 24 weeks after surgery in their study. No healing was seen in defects treated by trephination and repair. The load to failure of the conduit treated menisci were also significantly better suggesting better repair tissue.

              Zhang Z, Arnold JA. Trephination and suturing of avascular meniscal tears: a clinical study of the trephination procedure. Arthroscopy. 1996 Dec;12(6):726-31.

              Fox JM, Rintz KG, Ferkel RD. Trephination of incomplete meniscal tears. Arthroscopy. 1993;9(4):451-5

              Zhang ZN, Tu KY, Xu YK, Zhang WM, Liu ZT, Ou SH. Treatment of longitudinal injuries in avascular area of meniscus in dogs by trephination. Arthroscopy. 1988;4(3):151-9

              Shelbourne KD, Heinrich J. The long-term evaluation of lateral meniscus tears left in situ at the time of anterior cruciate ligament reconstruction. Arthroscopy. 2004 Apr;20(4):346-51.

              Biedert RM. Treatment of intrasubstance meniscal lesions: a randomized prospective study of four different methods. Knee Surg Sports Traumatol Arthrosc. 2000;8(2):104-8.

              Cook JL, Fox DB. A novel bioabsorbable conduit augments healing of avascular meniscal tears in a dog model. Am J Sports Med. 2007 Nov;35(11):1877-87. Epub 2007 Aug 16.

              Microfracture

              Autologous Bone marrow stem cells can improve meniscal wound healing. Whether this improvement occurs through BMSC differentiation into cells operational in the repair process, the release of certain mediator or other unknown mechanisms mandates further investigations.

              Microfracture is a commonly performed procedure and can help bring in these stem cells in to the meniscal defect. This is performed in the lateral wall of the notch.

              Freedman KB, Nho SJ, Cole BJ. Marrow stimulating technique to augment meniscus repair. Arthroscopy. 2003 Sep;19(7):794-8.

              Radiofrequency

              Radiofrequency energy may induce fibroblast proliferation for meniscal repair. Monopolar RFE denatures and fuses collagen and also produces fibrochondrocyte death to a limited area. There is then fibroblast cell proliferation at 2 weeks. The acellular area is repopulated by 12 weeks(Hatayama).

              Themal welding has been experimentally tried for meniscal repairs. The internal structure of the nuclei of the cells are preserved at 63 degrees C, whereas cells were denatured inside the nuclei in the 69 degrees C. They exhibited necrosis, making cell regeneration difficult. It seems feasible that thermal welding at 63 degrees C can repair tears in the human meniscal white zone. Use of laser alone has been shown to be insufficient to repair unstable meniscus tears(Vangsness).

              Laser-assisted fibrin clot soldering may allow the opposing edges of a meniscal tear to be held together with a biologic scaffold, possibly inducing reparative cell migration and proliferation. After irradiation with argon ion laser energy, the tensile strength of the laser-assisted fibrin clot-bonded menisci increased 40-fold over that of nonirradiated fibrin clot-bonded menisci.

              Imakiire N, Kotani A, Ishii Y. Experimental study on thermal welding for the knee meniscal white zone. J Orthop Sci. 2003;8(5):683-92.

              Vangsness CT Jr, Akl Y, Marshall GJ, Subin W, Smith CF. The effects of the neodymium laser on meniscal repair in the avascular zone of the meniscus. Arthroscopy. 1994 Apr;10(2):201-5.

              Forman SK, Oz MC, Lontz JF, et al: Laser-assisted fibrin clot soldering of human menisci. Clin Orthop 310:37-41, 1995

              Hatayama K, Higuchi H, Kimura M et al. Histologic changes after meniscal repair using radiofrequency energy in rabbits. Arthroscopy. 2007 Mar;23(3):299-304.

              Lopez MJ, DeTemple LA, Lu Y, Markel MD. The effects of monopolar radiofrequency energy on intact and lacerated ovine menisci. Arthroscopy. 2001 Jul;17(6):613-9.