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Hand/Peripheral Nerve: Original Articles

New Developments Are Improving Flexor Tendon Repair

Tang, Jin Bo M.D.

Author Information
Plastic and Reconstructive Surgery: June 2018 - Volume 141 - Issue 6 - p 1427-1437
doi: 10.1097/PRS.0000000000004416

Outcomes of primary flexor tendon repair in zone 2 in the digits have long been unpredictable. However, an increasing number of surgeons have reported much-improved outcomes in this area in recent years. Over the past two decades, several surgical techniques have been established as essential or even critical to tendon repair in the fingers and thumb. The most important are strong core suture techniques, judicious venting of the annular pulleys, evolution of early active motion regimens, and recognition of key principles in surgery and rehabilitation,1–11 which have substantially changed the landscape of digital flexor tendon repair. Recently, improved outcomes have been demonstrated not only by well-established hand centers but also by surgeons with midlevel expertise in tendon repair.10–22 This article reviews developments in techniques of surgery and rehabilitation critical to improving outcomes.


One notable change in outcomes is the decrease in rupture rates after zone 2 flexor tendon repairs.10–20 A review of the reports in leading hand and plastic surgery journals over the past decade indicates only 0 to 5 percent rupture rates,10–22 and a few recent reports had zero ruptures in 50 to 100 repairs.12,14–16,19,21,22 With regard to functional recovery, reports in recent years reflect overall excellent and good rates greater than 80 percent.12–16,19 Notably, use of weak core sutures, rehabilitation with use of rubber-band traction, or failure to incorporate active digital flexion produce fewer outcomes considered excellent or good.23 I direct readers to recent reports in which the key technical points, such as strong repair techniques, venting the pulleys, and early active motion were incorporated into surgical repair and rehabilitation; these reports bring us closer to the long-expected goal of more predictable outcomes of zone 2 tendon repairs and satisfactory outcomes in a majority of patients.12,14–16,19,21,22 The authors of these reports do not consider that expected outcomes are harder to achieve in zone 2 than in other areas, although many more technical details than those in other zones should be attended to, and repair surgery should be as meticulous as possible and rehabilitation more carefully designed and executed.


Strong core suture methods emerging in the 1980s and 1990s are now used widely. Strong surgical repairs are currently achieved through various multistrand methods. Recently developed or clinically used multistrand repairs are exemplified in Figure 1. Such strong repairs are intended to minimize risk of rupture during early active digital motion. Because active digital motion without resistance generates 0 to 30 N of force over the flexor tendons,24 it is generally believed that a four-strand core suture (with 4-0 or 3-0 nonabsorbable suture) is a minimum requirement. However, a six-strand core suture would make the repair safer, and some surgeons even use eight or more strands. Currently, a four-strand repair is the most popular,6,7 but I use a six-strand repair.1,5,6 A four-strand repair meets basic requirements regarding repair strength. However, because less-experienced surgeons frequently perform these repairs, certain safety measures should be observed; an easy approach is to increase the number of suture strands from four to six. I observed that after completion of a four-strand repair, the repair site usually has remarkable pliability, and gaps on stretching; however, after placing two additional strands, the repair site shows much greater firmness and resistance to gapping when pulled. I always perform a six-strand repair in zone 2. Eight or more strands is reasonable but is used by fewer surgeons or in special cases requiring a more robust repair.25

Fig. 1.
Fig. 1.:
A few recently developed or commonly used four- or six-strand repair methods. (Left) Summary of a few repair configurations and designs. (Above, right) Details of methods of making a six-strand M-Tang repair using looped monofilament nylon. Note that two looped sutures are used. (Below, right) Asymmetric triple Kessler repair is shown. Three groups of Kessler repairs can be used to make a six-strand repair. If only four groups of Kessler repairs are used, the repair method is called a four-strand Kessler repair, a popular four-strand repair used by many surgeons. The U-Tang method is a four-strand repair (shown below M-Tang on the left), which omits two strands of the M-Tang repair.

In making a core suture, it is critical to keep its purchase of at least 7 to 10 mm in each tendon stump (Fig. 2).26–28 The lock size should be 2 mm in diameter if a locking suture is used. A 4-0 or 3-0 nonabsorbable nonbraided suture, regular monofilament nylon, or a looped nylon such as Supramid Extra (S. Jackson, Inc., Alexandria, Va.), depending on repair methods, is used in tendons in the digit area of my patients. (See Video, Supplemental Digital Content 1, which demonstrates how to make a six-strand M-Tang repair using two looped nylon sutures, available in the “Related Videos” section of the full-text article on or, for Ovid users, at I do not favor Ethibond (Ethicon, Inc., Somerville, N.J.) suture in zone 2 repair, because it is hard to keep under tension and easily becomes loose. FiberWire (Arthrex, Naples, Fla.) is too rigid for making a smooth tendon repair in zone 2, but Ethibond or FiberWire can be used in the forearm. I prefer a needle of a larger size, but have no particular preference regarding needle types. Leaving suture knots outside the tendon or burying them between the tendon ends is not a major consideration. In my repairs with an M-Tang method, knots are exposed on the tendon surface, most on the lateral aspects of the tendon.

Fig. 2.
Fig. 2.:
It is critically important to keep sufficient core suture purchase in the stump. Note the bite on the stump should be 0.7 to 1 cm away from the cut site as shown in the photograph.
Video 1.
Video 1.:
Supplemental Digital Content 1, which demonstrates how to make a six-strand M-Tang repair using two looped nylon sutures, is available in the “Related Videos” section of the full-text article on or, for Ovid users, at


Most hand surgeons now agree that critical annular pulleys can and should be vented during primary repair to allow freer tendon gliding.21,22,29–33 Although it was not acceptable 20 years ago, this practice is now considered critical to ensure functional recovery and is unlikely to cause clinical problems when executed cautiously.21,22,29,31 Narrow and rigid annular pulleys restrict tendon gliding and block motion of the edematous tendon repair site. Therefore, release of these pulleys (or their most narrow parts) is key to improving tendon motion, decreasing risk of rupture during early active digital motion.29,32–34 Nevertheless, such releases should be executed cautiously to avoid creating a lengthy sheath-pulley defect and damaging the series of annular pulleys. The flexor pulley system is intricate yet robust to some loss of integrity; losing a portion of the sheath-pulley does not affect digital function. The pulley release does not need to be lengthy, because in the proximal part of a finger of an average adult, the flexor tendons glide only 1.5 to 2 cm with full digital extension and flexion.21,22 Therefore, release of the sheath and pulley shorter than 2 cm is sufficient to allow the tendon to glide for the entire range of finger flexion. A sheath-pulley release less than 2 cm long causes no clinical tendon bowstringing, provided that other sheath and pulleys are preserved.

Correctly incising a segment of sheath and pulleys while avoiding damage to tendon function demands a profound mastery of anatomy.1,6,7 Two essential rules are as follows: (1) a segment of the A2 pulley should always be retained (the venting can be distal or proximal to the retained A2 portion, which may include the entire A1 pulley or cruciate pulleys distal to the A2 pulley); and (2) the A4 pulley can be entirely vented, including extension to the A3 pulley, but should not extend over or much proximal to the A3 pulley. Occasionally, the A2 pulley will have to be entirely vented, but this is not customary. Retaining at least a part—up to one-half or two-thirds—of the A2 pulley is a safe recommendation for venting.1,6,7,21

Again, proper venting of pulleys is based on mastery of their locations and identification of the pulleys intraoperatively. Surgeons should familiarize themselves with the anatomy involved before surgery. Understanding the intricate anatomy of the pulleys may be easier said than done, but this is key to performing a correct venting procedure.


If I were asked to name three keys to an ideal repair, I would respond, “strong core suture repair, venting of pulleys, and tension over the repair site.” Clinically, tension-free tendon repair is harmful. Maintaining tension across the suture strands increases the ability of the repair to resist gapping during active finger flexion.35 Tension across the repair site is also vital to preventing repair rupture. If a surgeon performs a core suture repair with four or six strands, but without sufficient tension, the repair will easily gap and disrupt at the junction of the tendon ends. If the tendon is not loaded during surgery, gapping may not be noticed by surgeons. However, once loaded, if gapping occurs, the repair tends to disrupt (Fig. 3). Therefore, we need to ensure sufficient tension in the suture strands and allow some tendon bulkiness.21,35

Fig. 3.
Fig. 3.:
Bulkiness versus tension across the repair site. (Above) A loose repair or a repair with gapping should always be avoided. (Center) Tension-free repair is not an ideal repair. (Below) With tension in the repair site, certain bulkiness is always not avoidable. With proper pulley venting, an increase in the repair site diameter by one-fifth to one-fourth is tolerable. This degree of tension is necessary to ensure no gapping at the repair site in early active digital flexion. Ensuring tension should not be traded for decreasing the bulkiness.

Adding tension across the repair increases tendon bulkiness but, in current practice, appears not to be a major issue, because the constrictive or narrow pulleys are vented and tendon repair-site bulkiness lessens when the tendon is loaded proximally.34,35 The allowable repair-site bulkiness in terms of tendon diameter is 120 to 130 percent of the uninjured tendon in my practice, which usually causes 10 to 20 percent shortening of the tendon segment encompassed by the suture strands. Some surgeons allow an increase to over 150 percent of the tendon diameter after repair, but I usually avoid this degree of bulkiness.


In practice, if a surgeon fulfills the above-mentioned key points, there should be no need to perform a digital extension-flexion test after repair. However, this test can serve as a quality control, and I suggest it be performed after all digital flexor tendon repairs. For junior and senior hand surgeons alike, this test objectively validates a reliable, strong repair; sufficient venting; and proper tension. The test consists of three parts (Fig. 4).36 Parts of this test have long been practiced by some surgeons8; more recently, the test was proposed in response to the call for a uniform standard test after a tendon repair.

Fig. 4.
Fig. 4.:
This test is performed immediately after completion of the tendon repair to check the quality of the repair. The test consists of three parts: part I, passive full extension of the digit to ensure the tendon repair site shows no gapping (above); part II, passive flexion of the digit to confirm that gliding is smooth (center); and part III, pushing the digit to almost full flexion to check whether the tendon repair site (usually a bit bulky) impinges against the edge of the sheath or a pulley (below).

If the repair fails the test, it should be revised. For example, if gapping is noted with the digit fully extended, the repair should be strengthened with additional core or peripheral sutures; if a pulley is found to block gliding of the repair site, the pulley needs further release. Any repair that gaps, fails, or gets stuck during finger motion during surgery risks rupture in early active digital motion, which plainly is the reason for performing such a test.

Tendon repair under wide-awake settings, as advocated by Higgins et al.8 and Lalonde,9 allows active digital extension-flexion (Fig. 5), which is an even more powerful validation of quality of repair and a major advantage of the wide-awake setting.29,30 (See Video, Supplemental Digital Content 2, which demonstrates intraoperative active digital extension and flexion to verify quality of repair and sufficiency of pulley-venting with the patient under local anesthesia and no tourniquet, available in the “Related Videos” section of the full-text article on or, for Ovid users, at

Fig. 5.
Fig. 5.:
Testing quality of tendon repair in the wide-awake setting: active extension (above) and active flexion (below) to ensure no gapping at the repair site and smooth active tendon gliding after repair of the middle finger.
Video 2.
Video 2.:
Supplemental Digital Content 2, which demonstrates intraoperative active digital extension and flexion to verify quality of repair and sufficiency of pulley-venting with the patient under local anesthesia and no tourniquet, is available in the “Related Videos” section of the full-text article on or, for Ovid users, at


Increasingly, much shorter splints are used for protection of the wrist and hand after flexor tendon repair.10,11,21 A short splint extends from either the distal forearm or the wrist to the fingertips; I use a splint from the distal forearm to the fingertips. In addition, exact wrist positions are no longer considered important. The wrist can be in neutral, mild flexion, or mild extension, provided that the patient is comfortable. The splint should be slightly flexed at the metacarpophalangeal joint and be straight beyond the metacarpophalangeal joint, and should extend past the finger or thumb tip. The wrist position for splinting should avoid marked flexion (which will be uncomfortable) or marked extension (which will add unnecessary tension to the repaired tendon).

There is no need to start motion or therapy in the first 3 or 4 days after surgery, which also avoids pain and discomfort.1 From day 4 or 5, at least a few sessions of digital motion exercises are necessary; the exact number of sessions should be decided by the surgeons and therapists according to preferences and the patient’s condition. In each session, to lessen resistance of joint stiffness, full passive finger motion—usually 20 to 40 repetitions—should be performed before active digital flexion. Then, active digital flexion should proceed gradually. In the first 3 to 4 weeks, only one-third to two-thirds of the active motion range should be the goal. Extreme digital active flexion should be avoided, because the tendon has greatly increased resistance to gliding and the repair is more prone to disrupt when the tendon is bent and being pulled (Fig. 6).1,28 In reality, some patients have marked swelling at this time, making full range of active motion difficult. For them, it is not possible to immediately pursue forceful, full active flexion, but full passive finger flexion and extension should always be performed. From the end of week 3 or 4, full range of active flexion is the goal. Patients having difficulty with full active flexion at week 4 or 5 may gradually achieve full flexion in later weeks, but exercise to reduce joint stiffness and prevent extension lag is very important for eventual recovery of active finger flexion.

Fig. 6.
Fig. 6.:
Changes in resistance during active range of digital flexion from full extension. The tendon is easiest to disrupt at maximal flexion of the finger (right) when the tendon is bent. The safe range of active motion is from full extension to slight or moderate active flexion (left and center). MP, metacarpophalangeal; PIP, proximal interphalangeal; DIP, distal interphalangeal.


Out-of-splint active motion is encouraged as the most efficient exercise for decreasing resistance to active motion. A robust tendon repair is strong enough to permit the digit to move out of splint. A number of surgeons obtained excellent outcomes after performing out-of-splint active digital motion after finger flexor tendon repair or flexor pollicis longus tendon repair (Fig. 7).14,16,21 The splint can be discarded entirely at week 6 to 7 depending on the severity of injury. Rehabilitation should continue for at least 8 to 10 weeks (or longer), with the goal of decreasing residual extension lag or achieving full flexion. After flexor pollicis longus repairs, active thumb flexion exercise is similar to that of the fingers, although some details vary.14,16

Fig. 7.
Fig. 7.:
Active out-of-splint motion of the interphalangeal joint with the patient’s other hand holding the proximal part of the injured thumb after flexor pollicis longus repair. (Left) Flexion exercise. (Right) Extension exercise (arrow indicates the flexor pollicis longus cut level).


Venting the pulleys changes the dynamics of gliding of a repaired flexor tendon, and strong repair methods increase repair safety. Because of these measures, practices are evolving: (1) peripheral sutures can be rather sparse or even absent14,21,22; (2) a slightly bulky repair site is fine; (3) sheath closure is no longer considered essential or necessary; and (4) wrist positioning can be flexible, and the wrist may not even need protection. In addition, not repairing the flexor digitorum superficialis tendon (e.g., leaving the retracted flexor digitorum superficialis stump alone without resection or resection of the flexor digitorum superficialis tendon exposed in the surgical field locally) is not detrimental to finger motion.

The timing of surgery is not important if the repair is not delayed too long. Although primary repair is always preferable, delayed primary repair within 1 to 2 weeks after injury gives outcomes quite similar to those of a primary repair. Very delayed primary repair (>3 or 4 weeks after injury) can also be attempted,25 but conservative measures, such as using a very strong repair,25 should be taken; and surgeons should be very experienced, because the intraoperative decision as to whether to proceed with secondary tendon reconstruction requires expert judgment.


Repair Ruptures

Although rupture rates of primary repairs have decreased substantially, ruptures remain a persistent complication. They occur mainly in patients whose surgeons still use a weak core suture, or have not yet updated their knowledge about the keys to performing a repair and early active motion.

Adhesion Formations

Adhesions remain a major complication, and are more frequent than repair ruptures. Significant adhesions need surgical tenolysis 6 months after the repair or 3 months after failure to improve active range of motion. Severe soft-tissue and bone injuries or local tissue loss are factors contributing to the formation of adhesions. These complications cannot be avoided entirely with current repair techniques and rehabilitation. Although mild adhesions can be disrupted during passive or active digital motion exercises, severe injury to and edema of the hand cause formation of restrictive adhesions, often requiring tenolysis. There are no recent reports on rates of tenolysis, but they are estimated to be around 10 percent.

Joint Stiffness

Although only some patients need release of joint stiffness, the incidence of joint stiffness is very high. The stiffness improves, although patients often complain of lack of full extension or flexion in the first few months after primary repair. In my experience, unless such lags are severe, it is not necessary to proceed to surgical release. The stiffness usually resolves in 5 to 6 months through daily hand use. The improvement in hand function can be observed for more than 1 year, with major decreases in extension and flexion lags.


The following pitfalls and pearls are very helpful in performing primary flexor tendon repair and rehabilitation:

  1. Always create a window to find a retracted proximal tendon. The proximal tendon stump usually retracts to the proximal end of the fingers or palm. Surgeons should create a separate incision in the palm to deliver the tendon end through the preserved sheath and pulleys to approximate the distal end. With flexion of the distal joint(s) of the finger, the distal tendon end can glide out to the surgical field for repair. Avoid making a lengthy sheath-pulley opening to find the retracted proximal tendon.
  2. Asymmetric arrangement may be more beneficial compared with symmetric arrangement of the core sutures. This is a very recent pearl for making a core suture more resistant to gapping.37 This practice has attracted attention from surgeons and investigators.31
  3. Allow venting of more pulleys or aggressive motion. Pulley venting is key to decreasing tendon gliding resistance. Some surgeons perform a slightly wider pulley release and find that it makes the repair easier and tendon gliding better.32 In addition, more aggressive motion, such as discarding or part-time use of splint protection as early as at week 5 or 6, is currently attempted by surgeons, with no increases in repair rupture.


Based on recent reports and the experience of the author and his colleagues, multistrand repair, especially a six-strand core suture, ensures a strong tendon repair and almost completely prevents repair rupture. Rupture was noted only in rare patients who returned to unrestricted hand use too soon or who suffered accidents. It appears that venting the sheath-pulley a bit longer than previously recommended is not harmful and appears to cause no problems of tendon bowstringing. Although the length limit of the venting apparently varies among fingers and hands of different sizes, the A2 and A4 pulleys should certainly not both be vented. A report from Japan describes venting the entire A2 pulley in some cases.32 Other surgeons vent the A2 pulley according to intraoperative active motion; they do not emphasize keeping it intact.8,29,33 Considerable variations exist in clinical repair configuration; their strengths vary.38 The best practice for pulley venting in the thumb is poorly defined, remaining a topic of discussion.14,16,39

Out-of-splint motion from the very initial weeks is another step toward true active motion. A common impression among many surgeons who use strong repairs and vent the pulleys is that early active motion can be more aggressive than currently recommended. In fact, if a too-forceful grip is avoided, any active motion appears to be safe. I consider that expertise of surgeons should be described together with outcomes,36,40–42 and more aggressive pursuit of tendon motion is likely to become a future direction for research.


1. Tang JBIndications, methods, postoperative motion and outcome evaluation of primary flexor tendon repairs in zone 2. J Hand Surg Eur Vol. 2007;32:118129.
2. Kwai Ben I, Elliot D“Venting” or partial lateral release of the A2 and A4 pulleys after repair of zone 2 flexor tendon injuries. J Hand Surg Br. 1998;23:649654.
3. Elliot D, Giesen TPrimary flexor tendon surgery: The search for a perfect result. Hand Clin. 2013;29:191206.
4. Savage RThe search for the ideal tendon repair in zone 2: Strand number, anchor points and suture thickness. J Hand Surg Eur Vol. 2014;39:2029.
5. Tang JBRelease of the A4 pulley to facilitate zone II flexor tendon repair. J Hand Surg Am. 2014;39:23002307.
6. Tang JB, Chang J, Elliot D, Lalonde DH, Sandow M, Vögelin EIFSSH Flexor Tendon Committee report 2014: From the IFSSH Flexor Tendon Committee (Chairman: Jin Bo Tang). J Hand Surg Eur Vol. 2014;39:107115.
7. Tang JB, Amadio PC, Boyer MI, et al.Current practice of primary flexor tendon repair: A global view. Hand Clin. 2013;29:179189.
8. Higgins A, Lalonde DH, Bell M, McKee D, Lalonde JFAvoiding flexor tendon repair rupture with intraoperative total active movement examination. Plast Reconstr Surg. 2010;126:941945.
9. Lalonde DHWide-awake flexor tendon repair. Plast Reconstr Surg. 2009;123:623625.
10. Wong JK, Peck FImproving results of flexor tendon repair and rehabilitation. Plast Reconstr Surg. 2014;134:913e925e.
11. Khor WS, Langer MF, Wong R, Zhou R, Peck F, Wong JKImproving outcomes in tendon repair: A critical look at the evidence for flexor tendon repair and rehabilitation. Plast Reconstr Surg. 2016;138:1045e1058e.
12. Hoffmann GL, Büchler U, Vögelin EClinical results of flexor tendon repair in zone II using a six-strand double-loop technique compared with a two-strand technique. J Hand Surg Eur Vol. 2008;33:418423.
13. Moriya K, Yoshizu T, Maki Y, Tsubokawa N, Narisawa H, Endo NClinical outcomes of early active mobilization following flexor tendon repair using the six-strand technique: Short- and long-term evaluations. J Hand Surg Eur Vol. 2015;40:250258.
14. Giesen T, Sirotakova M, Copsey AJ, Elliot DFlexor pollicis longus primary repair: Further experience with the Tang technique and controlled active mobilization. J Hand Surg Eur Vol. 2009;34:758761.
15. Zhou X, Li XR, Qing J, Jia XF, Chen JOutcomes of the six-strand M-Tang repair for zone 2 primary flexor tendon repair in 54 fingers. J Hand Surg Eur Vol. 2017;42:462468.
16. Pan ZJ, Qin J, Zhou X, Chen JRobust thumb flexor tendon repairs with a six-strand M-Tang method, pulley venting, and early active motion. J Hand Surg Eur Vol. 2017;42:909914.
17. Moriya K, Yoshizu T, Tsubokawa N, Narisawa H, Hara K, Maki YOutcomes of release of the entire A4 pulley after flexor tendon repairs in zone 2A followed by early active mobilization. J Hand Surg Eur Vol. 2016;41:400405.
18. Sandow MJ, McMahon MActive mobilisation following single cross grasp four-strand flexor tenorrhaphy (Adelaide repair). J Hand Surg Eur Vol. 2011;36:467475.
19. Al-Qattan MMIsolated flexor digitorum profundus tendon injuries in zones IIA and IIB repaired with figure of eight sutures. J Hand Surg Eur Vol. 2011;36:147153.
20. Frueh FS, Kunz VS, Gravestock IJ, et al.Primary flexor tendon repair in zones 1 and 2: Early passive mobilization versus controlled active motion. J Hand Surg Am. 2014;39:13441350.
21. Tang JB, Zhou X, Pan ZJ, Qing J, Gong KT, Chen JStrong digital flexor tendon repair, extension-flexion test, and early active flexion: Experience in 300 tendons. Hand Clin. 2017;33:455463.
22. Giesen T, Calcagni M, Elliot DPrimary flexor tendon repair with early active motion: Experience in Europe. Hand Clin. 2017;33:465472.
23. Rigo IZ, Røkkum MPredictors of outcome after primary flexor tendon repair in zone 1, 2 and 3. J Hand Surg Eur Vol. 2016;41:793801.
24. Edsfeldt S, Rempel D, Kursa K, Diao E, Lattanza LIn vivo flexor tendon forces generated during different rehabilitation exercises. J Hand Surg Eur Vol. 2015;40:705710.
25. Tang JBUncommon methods of flexor tendon and tendon-bone repairs and grafting. Hand Clin. 2013;29:215221.
26. Cao Y, Zhu B, Xie RG, Tang JBInfluence of core suture purchase length on strength of four-strand tendon repairs. J Hand Surg Am. 2006;31:107112.
27. Tang JB, Zhang Y, Cao Y, Xie RGCore suture purchase affects strength of tendon repairs. J Hand Surg Am. 2005;30:12621266.
28. Wu YF, Tang JBRecent developments in flexor tendon repair techniques and factors influencing strength of the tendon repair. J Hand Surg Eur Vol. 2014;39:619.
29. Lalonde DH, Martin ALWide-awake flexor tendon repair and early tendon mobilization in zones 1 and 2. Hand Clin. 2013;29:207213.
30. Tang JBWide-awake primary flexor tendon repair, tenolysis, and tendon transfer. Clin Orthop Surg. 2015;7:275281.
31. Kozono N, Okada T, Takeuchi N, Hanada M, Shimoto T, Iwamoto YAsymmetric six-strand core sutures enhance tendon fatigue strength and the optimal asymmetry. J Hand Surg Eur Vol. 2016;41:802808.
32. Moriya K, Yoshizu T, Tsubokawa N, Narisawa H, Hara K, Maki YClinical results of releasing the entire A2 pulley after flexor tendon repair in zone 2C. J Hand Surg Eur Vol. 2016;41:822828.
33. Elliot D, Lalonde DH, Tang JBCommentaries on clinical results of releasing the entire A2 pulley after flexor tendon repair in zone 2C. K. Moriya, T. Yoshizu, N. Tsubokawa, H. Narisawa, K. Hara and Y. Maki. J Hand Surg Eur. 2016, 41: 822-28. J Hand Surg Eur Vol. 2016;41:829830.
34. Wu YF, Tang JBTendon healing, edema, and resistance to flexor tendon gliding: Clinical implications. Hand Clin. 2013;29:167178.
35. Wu YF, Tang JBEffects of tension across the tendon repair site on tendon gap and ultimate strength. J Hand Surg Am. 2012;37:906912.
36. Tang JBOutcomes and evaluation of flexor tendon repair. Hand Clin. 2013;29:251259.
37. Wu YF, Tang JBThe effect of asymmetric core suture purchase on gap resistance of tendon repair in linear cyclic loading. J Hand Surg Am. 2014;39:910918.
38. Leppänen OV, Linnanmäki L, Havulinna J, Göransson HSuture configurations and biomechanical properties of flexor tendon repairs by 16 hand surgeons in Finland. J Hand Surg Eur Vol. 2016;41:831837.
39. Sirotakova M, Elliot DEarly active mobilization of primary repairs of the flexor pollicis longus tendon with two Kessler two-strand core sutures and a strengthened circumferential suture. J Hand Surg Br. 2004;29:531535.
40. Tang JBRe: Levels of experience of surgeons in clinical studies. J Hand Surg Eur Vol. 2009;34:137138.
41. Tang JB, Giddins GWhy and how to report surgeons’ levels of expertise. J Hand Surg Eur Vol. 2016;41:365366.
42. Moriya K, Yoshizu T, Tsubokawa N, Narisawa H, Matsuzawa S, Maki YOutcomes of flexor tendon repairs in zone 2 subzones with early active mobilization. J Hand Surg Eur Vol. 2017;42:896902.


Coding perspective provided by Dr. Raymond Janevicius is intended to provide coding guidance.

The following CPT codes are reported for flexor tendon repairs in the hand.

  • 26350 Repair or advancement, flexor tendon, not in zone 2 digital flexor tendon sheath (e.g., no man’s land); primary or secondary without free graft, each
  • 26352 Repair or advancement, flexor tendon, not in zone 2 digital flexor tendon sheath (e.g., no man’s land); secondary with free graft (includes obtaining graft), each tendon
  • 26356 Repair or advancement, flexor tendon, in zone 2 digital flexor tendon sheath (e.g., no mans land); primary, without free graft, each tendon
  • 26357 Repair or advancement, flexor tendon, in zone 2 digital flexor tendon sheath (e.g., no man’s land); secondary, without free graft, each tendon
  • 26358 Repair or advancement, flexor tendon, in zone 2 digital flexor tendon sheath (e.g., no man’'s land); secondary, with free graft (includes obtaining graft), each tendon
  • 26370 Repair or advancement of profundus tendon, with intact superficialis tendon; primary, each tendon
  • 26372 Repair or advancement of profundus tendon, with intact superficialis tendon; secondary with free graft (includes obtaining graft), each tendon
  • 26373 Repair or advancement of profundus tendon, with intact superficialis tendon; secondary without free graft, each tendon

The flexor tenorrhaphy codes are global and include the following:

  • Extension of wound.
  • Exploration of wound.
  • Débridement.
  • Retrieval of tendon ends.
  • Tenorrhaphy, including core and epitenon sutures.
  • Straightforward wound closure.
  • Application of splint.
  • 90 days of postoperative care.

CODING PRINCIPLE: Accurate documentation in the operative report is crucial for precise CPT and International Classification of Diseases, 10th Revision, coding. The operative report must include the following:

  • Which tendon (flexor, extensor, intrinsic).
  • Location of injury (forearm, wrist, hand, finger, zone 2).
  • Which digit, even for forearm repairs (e.g., flexor digitorum sublimis of right ring finger).
  • Laterality (right or left).
  • Procedure performed (primary, secondary, use of tendon graft).

Although the body of the operative report may include this information, it should always be summarized in the “Findings” section of the operative report heading.

Disclosure: Dr. Janevicius is the president of JCC ([email protected]), a firm specializing in coding consulting services for surgeons, government agencies, attorneys, and other entities.

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