Arthroscopic Management of Intra-articular Ligament Lesions on Distal Radius Fractures

• Abstract
• Introduction
• Principles of Biomechanics
• Clinical Relevance
• Methods
• Postoperative Period
• Results
• Discussion
• The Advantages of Using Wrist Arthroscopy are:
• The Disadvantages are:
• Author Recommendations
• Conclusion
• References

Abstract

Articular distal radius fractures (DRFs) have increased in incidence in recent years, especially among the economically active population. Most of the treatment approaches are based on plain X- rays, and do not give us any information on how to treat these fractures. In the search for solutions with greater precision in diagnosis, in reducing the joint surface of the fracture, and envolving minimally-invasive techniques, we found arthroscopy as the main tool for these patients. Therefore, an enhanced understanding of the biomechanics of the different types of fracture associated with ligamentous lesions should facilitate the right decision regarding the treatment. The present paper aims at providing a management-oriented concept to diagnose and treat ligamentous lesions associated with intra-articular DRFs based on a arthroscopy-assisted procedure, and showing the objective and patient-reported outcomes and a new classification. The objective and patient-reported outcomes were: the mean range of motion (ROM) was of 94.80% on the non-affected side; the mean score on the abbreviated version of the Disabilities of the Arm, Shoulder and Hand questionnaire (QuickDASH) was of 3.6 (range: 1 to 12). The score on the Visual Analog Scale (VAS) was of 1.66 (range: 1 to 3). Complications were observed in 2 (13.33%) patients: extensor tendon synovitis in 1 patient, and a limitation (stiffness) in ROM in 1 patient, both treated with wrist arthroscopy release. The mean time until the return to work was of 6.4 weeks. In patients with unstable intra-articular DRFs associated with ligamentous lesions, the fixation of specific osseous-ligamentous fragments and ligamentous repair/reconstruction by wrist arthroscopy prove to be a safe and reliable treatment. The clinical and functional results predict that the patients can return to work more quickly.

Introduction

The incidence of articular distal radius fractures (DRFs) has increased recently, especially among the economically-active population. The frequency of surgery for patients with DRF has also increased. Arthroscopy is considered the primary tool available for these patients, as it utilizes minimally-invasive techniques, reduces the joint surface of the fracture, and enables a higher precision in diagnosis. Arthroscopic techniques enable surgeons to perform surgery for DRFs via a direct and anatomical reduction of the joint surface, with sufficient stability for early mobility of the joint, preserving the proprioception and the vascularization of the tissues, often resulting in the patients resuming their regular personal or professional activities. Arthroscopy of the wrist requires specific characteristics and tools that generally follow these basic principles: creation of work or vision portals, identification of the lesion, and a specific treatment procedure; the standard of conduct for the postoperative care of these patients is very similar to that of procedures in other joints. Imaging scans of upper-limb joint fractures have been used for the initial diagnosis for many years. In recent years, plain radiography is often the first test to be ordered; however, the computed tomography (CT) scan has gained momentum, and is particularly useful to measure deviations and to check bone consolidation.[1] [2] Furthermore, magnetic resonance imaging (MRI) is useful to diagnose occult fractures[3] and associated ligament injuries; however, it is not superior to arthroscopy, so it is not widely used. Articular fractures appear differently, depending on the pattern and the associated trauma mechanism. Thus, torsional and indirect traumas present avulsion fracture patterns, and traumas in which the upper limb is used for protection (to support the body load, for example) are considered direct fractures by compression.[4] Arthroscopically-assisted techniques have broadened the technique spectrum, particularly when reducing intra-articular fractures and in the diagnosis of ligamentar lesions. Therefore, understanding the enhanced biomechanics of the different fracture types associated with ligament lesions should help facilitate an accurate treatment protocol.[5] Conservative treatment is an acceptable option for ligament injuries, fractures without deviation, and stable fractures, as it poses fewer risks and enables earlier mobilization by keeping the radiocarpal joint congruent. Another important factor is the time elapsed between the injury and the start of treatment. As with all injuries, prompt treatment generally results in a better prognosis.[6] The present study sought to provide a management-oriented concept for the diagnosis and treatment of ligament lesions associated with the stabilization of intra-articular DRFs based on a arthroscopy-assisted procedure through the presentation of objective and patient-reported outcomes (range of motion [ROM], Quick Disabilities of the Arm, Shoulder and Hand [QuickDASH] questionnaire, Visual Analog Scale [VAS], grip strength. and time until return to work) for classification.

Principles of Biomechanics

The biomechanics of the wrist involves both kinetic (performing the movement) and cinematic (bearing load) motion. The basic prerequisites for regular motion of the carpus are ([Fig. 1]):

• (1) Intact bone stock of the radius and ulna.

• (2) Intact intrinsic ligaments conjoin the proximal carpal row to a variable geometrical condyle versus the invariable proximal and distal counterparts.

• (3) Intact extrinsic ligaments coordinate the proximal row with the radius and ulna against the distal carpal row, which acts as a monolith.[7]

• (4) The role of proprioception and neuromuscular control in carpal stability.

The rather strong palmar ligaments support the proximal row like a cummerbund and act against forces of the dorsal side like a tension band ([Fig. 2]).[8]

The basic factors that cause DRF include the acting forces, the position of the wrist, and the resistance of the ligaments. Specific fracture types arise from the interaction among these parameters. These ligaments appear to reinforce the bone at their origin. Fracture patterns in two-part fractures generally occur in the area between the ligamentous zones. Intra-articular fractures show six different patterns, and at least one corner remains intact with the shaft. From a biomechanical standpoint, these bone-ligament fragments form a unit and tend to dislocate in different directions depending on their ligamentous attachment sites.[9] [10] [11] ([Fig. 3]). Recent laboratory research has revealed that carpal ligaments exhibited different kinetic behaviors depending on the direction and point of application of the forces to the wrist. The helical antipronation ligaments were usually active when the wrist was axially loaded; whereas the helical antisupination ligaments constrained the supination torques to the distal row. This novel way of interpreting the function of the carpal ligaments might assist in developing improved strategies for the treatment of carpal instabilities ([Fig. 4]).[12]

In the past decade, a fourth factor in carpal stability has been proposed, which involves the neuromuscular and proprioceptive control of the joints ([Fig. 5]). The proprioception of the wrist originates from afferent signals, and is elicited by sensory end organs (mechanoreceptors) in the ligaments and joint capsules. It elicits spinal reflexes for immediate joint stability, and a higher order of neuromuscular influx to the cerebellum and sensorimotor cortices for planning and executing joint control.[11] [12]

Clinical Relevance

However, many of these injuries have a mixed or complex trauma mechanism, as well as other ligament injuries not observed on the X-ray exam. The clinical relevance of the present article lies in the identification of occult lesions (perilunate injuries, not displaced, PLINDs)[13] associated with distal radius fractures, in which the fixation of the bone-ligament fragments is not sufficient to maintain the stabilization of the wrist joint, and in the proposal of a new classification and appropriate and specific treatment for these injuries.

Methods

In total, 150 patients with articular DRFs were selected as subjects in the present study, which was conducted at Centro Hospitalar Municipal de Santo André (CHMSA), in the city of Santo André, Brazil. The patients were diagnosed, treated, and subjected to clinical follow-up ([Figs. 6] and [7]). The surgical procedures used included[1] temporary fixation of the joint fragments with Kirschner wires, or procedures associated with a volar or dorsal plate under fluoroscopic control;[2] arthroscopic fine adjustment of the reduction (we mainly use radiocarpal portals 3–4 and 6-R);[3] rigid fixation of the joint fragments with screws, under arthroscopic guidance;[4] and exploration of the radiocarpal, scapholunate, lunotriquetral ligament complex, and of the triangular fibrocartilage complex (radio carpal portals 3–4, 6-R, and central volar).[14] Following the arthroscopic identification of the lesions, we started with the stabilization of the radius fracture:

• 1) rigid fixation with the volar locking plates (extra-articular fragments);[15] 2) arthroscopic control of the joint reduction.

In avulsion-fractures (bone ligament fragments), cannulated headless compression screws (HCSs) and Kirschner wires, or specific fragment-type hook plates, were used ([Fig. 8]). Compression-type fractures ([Figs. 9],[10],[11]) cannulated HCSs, Kirschner wires, blocked intramedullary nail (Micronail, Wright Medical Memphis, TN, US), or a graft (autologous or synthetic) were used to fill the bone gap that appeared following fracture reduction.

The ideal approach and type of implant: regarding the large number of implants available on the market, it is important to consider which type would be the most suitable to stabilize a specific fracture type, with regard to economic considerations, and not every fracture type necessarily requires the most expensive treatment.[5]

The first step was to determine the correct approach and use it to assess the subsequent measures necessary to prevent secondary dislocation of the carpus (to check ligament lesions associated the bone-ligament fragments). This seems to be more important than a perfect reduction. Specific fragments of the plates did not compromise the flexor tendons; however, they offered only limited possibilities to grasp and stabilize the very distal fracture elements. For the treatment of single fragments, cannulated self-tapping screws are becoming increasingly popular, and the minimally-invasive arthroscopy-assisted methods, in our opinion, were state-of-art, with the plate or nail or screw as the best solution.

• 3) Approach to associated ligament injuries

  • a) Reparable:

    • - thermal shrinkage[16] or thermal shortening (by radiofrequency) of the ligament fibers;

    • - direct suture[17] (with or without anchors; InternalBrace, Arthrex, Inc., Naples, FL, US) ([Figs. 12],[13], and [14]);

    • - indirect suture[18] (with or without anchors; InternalBrace)( [Fig. 15] and [Video 1]);

    • - reinsertion[19] (with or without anchors / InternalBrace) [Fig. 16]);

    • - dorsal or palmar capsulodesis[20] [21] (with or without anchors; InternalBrace) ([Figs. 17],[18], and [Video 1]).

  • b) Irreparable:

    • - arthroscopic debridement of the joint extension (removing scar or pulvinar fibrosis)[22] ([Video 2]);

    • - reconstruction: graft, bone tunnels, augmentation[23] [24] [25] [26] ([Fig. 10] and [Videos 3],[4]);

    • - transarticular stabilization if necessary.

Postoperative Period

The rehabilitation protocol included the use of static orthosis in the first two weeks, with exercises of proprioception and the “dart throw movie” for the wrist, elbow flexion, and fingers since the first day after surgery.[27] Active kinesiotherapy exercises and dynamic orthoses, assisted by physiotherapy or occupational therapy professionals, were used from the third week onwards. The retrn to work or sports activities was faster than with the conventional surgical approach. This assessment must be individualized, associated with trauma, applied as a surgical technique, and dependent on the profession or sports-related function of each patient. The study participants were encouraged to perform activities that avoided overload or changes in function.

Results

The idea of improving the diagnosis with the inclusion of arthroscopy in the treatment of these injuries also establishes a greater precision in the choice of the treatment method, and that is how we obtained the results herein described.

The objective and patient-reported outcomes are shown in [Table 1]. The mean ROM was of 94.80% on the non-affected side. The mean score on the QuickDASH was of 3.6 (range: 1 to 12). The mean score on the VAS was of 1.66 (range: (1 to 3). There were complications in 2 (13.33%) of the patients, including extensor tendon synovitis in 1 patient, and a limitation in ROM (stiffness) in the other patient; both were treated with wrist arthroscopy release. The mean time until the return to work was of 6.4 weeks. The present study describes the intraoperative arthroscopic findings, a new classification ([Fig. 6]), the treatment algorithm used ([Fig. 7], [Tables 2],[3]), and the clinical and functional results of the patients ([Table 1]).

Discussion

Scientific studies[10] claim that the lack of anatomical restoration and on-going osteoarthritis might be associated with the clinical outcome after DRFs. Contrary to this belief, the reduction assisted by arthroscopy in DRFs could be conducted simply and with minimal consumption of resources in the operating room. The proposed technique combines the benefits of rigid fixation with volar locking plates (for the extra-articular component), arthroscopic reduction control, and associated ligament injuries (for the articular component). It is important that the operation is performed using the dry arthroscopic technique.[15] Perilunate injuries, not displaced,[13] were recently described, and we proposed a new arthroscopic classification for articular DRFs associated with PLINDs.

In the last three years, a new treatment (repair) for ligament injuries, using InternalBrace as an augmentation, has been developed ([Fig. 12]). This treatment enabled a new focus on the restoration of the normal anatomy and function of the traumatized joint. It supports the early mobilization of the repaired ligament and enables the natural tissues to be strengthened and recover progressively with minimal surgical morbidity. Reconstruction only should be indicated if the tissues did not heal properly after augmentation and ligament repair.[24]

These injuries were also treated with ligament reconstruction with a tendon graft (non-vascularized tissue) and bone tunnels, and this graft, which was termed ligamentization ([Fig. 13]), enabled the clinical and functional recovery of the joint.[25] [26] The rehabilitation protocol included the use of static orthosis in the first two weeks, with proprioception and “dart-throwing motion” exercises since the first day after surgery.[27] Around the third week, active kinesiotherapy exercises were started, and dynamic orthoses were also used.

The Advantages of Using Wrist Arthroscopy are:

• - Preservation of the mechanisms of proprioception on the wrist (dorsal capsule);[28]

• - accurate diagnosis of associated injuries;

• - it favors more anatomical ligament repairs and reconstruction;[29] and

• - it enables direct visualization of the reduction of the articular surface.

The Disadvantages are:

• - Higher cost;

• - long learning curve; and

• - greater difficulty in the integration of fluoroscopy and arthroscopy.

Sufficient stability, joint congruence, and anatomical reduction of the fractures remain the main goals of the treatment. The best result appeared when early joint mobility was allowed, and the patients were allowed to return to their personal and professional activities. Minimally-invasive techniques, guided by arthroscopy, were the most advantageous way to assist these patients.

The proper treatment of DRFs often involved bone-ligament fragments (avulsion), ligament injuries in other sites, and, radiocarpal or intercarpal instability (PLIND) in the patients. Here, the role of arthroscopy was essential for the diagnosis and treatment of these injuries. The present study suggested techniques for anatomical and biological ligament reconstruction and repair. We were able to observe in these patients stable and congruent wrist joints, absence of osteolysis in the bone tunnels, and signs of posttraumatic osteoarthritis. The clinical results and rate of complications in the present study showed the most favorable results compared with the other techniques.[10] The mean ROM was of 94.80% on the non-affected side. The mean score on the QuickDASH was of 3.6 (range: 1 to 12). The mean score on the VAS was of 1.66 (1 to 3). Complications were observed in 2 (13.33%) patients: extensor tendon synovitis in 1 patient, and a limitation in ROM (Stiffness) in another patient; both were treated with wrist arthroscopy release. The mean time until the return to work was of 6.4 weeks.

Author Recommendations

Many authors have used arthroscopy for the treatment of joint fractures; therefore, the tips and ideas have increased in the existing literature.[6] [14] [15] Furthermore, new classifications have appeared, and the procedure becomes increasingly reproducible. The authors would like to stress the importance of university courses with a cadaver laboratory, on going publications, and exchanges of information with colleagues from Europe (Spain, France, Italy), the United States, and Latin America (Brazil, Argentina, Chile, Mexico, and Colombia). Information regarding new treatments for acute articular fractures of the upper limb are lacking, and new studies are required in the future. Most of the available articles were heterogeneous, such as case reports.[18] [19] [21] [23] [24] All of the articles either found or emphasized the role of arthroscopy as the exam/tool that leads to the most favorable diagnoses of fractures and associated injuries. In the treatment of these fractures, reduction guided by arthroscopy was associated with percutaneous fixation, and had sufficient stability to enable immediate mobility. This procedure imparted advantages to the conventional methods of open reduction, primarily by what was involved in the concept of biomechanics and proprioception, as well as the accuracy of joint reduction and respect for the minimal aggression to adjacent tissues.

This surgery required substantial arthroscopic education for the most complicated cases; however, it was easily performed in simple cases. The paradox was that the cases that benefited the most from arthroscopy were the most complex.[16]

Conclusion

Basic understanding of the essential biomechanic characteristics in DRFs appeared crucial to maintaining the wrist proprioception and achieve sufficient stabilization of the bone ligament fragments and the associated ligament lesions, thereby avoiding secondary dislocation. The present paper provided a management-oriented concept for the diagnosis and treatment of the ligament lesions associated with the stabilization of intra-articular DRFs based on an arthroscopy-assisted procedure through a new classification shown here.

In the treatment of patients with unstable intra-articular DRFs associated with ligament lesions, the ligaments were either repaired or reconstructed, and the fixation of specific bone-ligament fragments was performed through wrist arthroscopy, which proved to be a safe and reliable treatment. Ultimately, the clinical and functional results predicted whether the patients could return to work.

Conflict of Interests

The authors have no conflict of interests to declare.

• References

• 1 De Zwart AD, Beeres FJ, Ring D. et al. MRI as a reference standard for suspected scaphoid fractures. Br J Radiol 2012; 85 (1016): 1098-1101
  CrossrefPubMedGoogle Scholar
• 2 Gilley E, Puri SK, Hearns KA, Weiland AJ, Carlson MG. Importance of computed to-mography in determining displacement in scaphoid fractures. J Wrist Surg 2018; 7 (01) 38-42
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 3 Larribe M, Gay A, Freire V, Bouvier C, Chagnaud C, Souteyrand P. Usefulness of dynamic contrast-enhanced MRI in the evaluation of the viability of acute scaphoid fracture. Skeletal Radiol 2014; 43 (12) 1697-1703
  CrossrefPubMedGoogle Scholar
• 4 Goffin JS, Liao Q, Robertson GAJ. Return to sport following scaphoid fractures: A systematic review and meta-analysis. World J Orthop 2019; 10 (02) 101-114
  CrossrefPubMedGoogle Scholar
• 5 Muller ME. et al. Manual of Internal Fixation, AO-ASIF, 1980. ISBN 3–540–52523–8. 3rd ed.. 1995
  Google Scholar
• 6 Hintringer W, Rosenauer R, Pezzei C. et al. Biomechanical considerations on a CT-based treatment-oriented classification in radius fractures. Arch Orthop Trauma Surg 2020; 140 (05) 595-609
  CrossrefPubMedGoogle Scholar
• 7 Wong K, von Schroeder HP. Delays and poor management of scaphoid fractures: factors contributing to nonunion. J Hand Surg Am 2011; 36 (09) 1471-1474
  CrossrefPubMedGoogle Scholar
• 8 Bain GI, MacLean SBM, McNaughton T, Williams R. Microstructure of the distal radius and its relevance to distal radius fractures. J Wrist Surg 2017; 6 (04) 307-315
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 9 Short WH, Palmer AK, Werner FW, Murphy DJ. A biomechanical study of distal radial fractures. J Hand Surg Am 1987; 12 (04) 529-534
  CrossrefPubMedGoogle Scholar
• 10 Gabl M, Arora R, Schmidle G. Biomechanik distaler Radiusfrakturen : Grundlagenverständnis und GPS-Behandlungsstrategie bei winkelstabiler Plattenosteosynthese. Unfallchirurg 2016; 119 (09) 715-722
  CrossrefPubMedGoogle Scholar
• 11 Goldfarb CA, Rudzki JR, Catalano LW, Hughes M, Borrelli Jr J. Fifteen-year outcome of displaced intra-articular fractures of the distal radius. J Hand Surg Am 2006; 31 (04) 633-639
  CrossrefPubMedGoogle Scholar
• 12 Garcia-Elias M, Puig de la Bellacasa I, Schouten C. Carpal ligaments: a functional classification. Hand Clin 2017; 33 (03) 511-520
  CrossrefPubMedGoogle Scholar
• 13 Hagert E, Lluch A, Rein S. The role of proprioception and neuromuscular stability in carpal instabilities. J Hand Surg Eur Vol 2016; 41 (01) 94-101
  CrossrefPubMedGoogle Scholar
• 14 Herzberg G. Perilunate injuries, not dislocated (PLIND). J Wrist Surg 2013; 2 (04) 337-345
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 15 Corella F, Ocampos M, Cerro MD, Larrainzar-Garijo R, Vázquez T. Volar central por-tal in wrist arthroscopy. J Wrist Surg 2016; 5 (01) 80-90
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 16 Del Piñal F. Technical tips for (dry) arthroscopic reduction and internal fixation of distal radius fractures. J Hand Surg Am 2011; 36 (10) 1694-1705
  CrossrefPubMedGoogle Scholar
• 17 Burn MB, Sarkissian EJ, Yao J. Long-term outcomes for arthroscopy thermal treatment for Scapholunate ligament injuries. J Wrist Surg 2020; 9 (01) 22-28
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 18 Carratalá V, Lucas FJ, Miranda I, Sánchez Alepuz E, González Jofré C. Arthroscopic scapholunate capsule ligamentous repair: suture with dorsal capsular reinforcement for scapholunate ligament lesion. Arthrosc Tech 2017; 6 (01) e113-e120
  CrossrefPubMedGoogle Scholar
• 19 Yao J, Zlotolow DA, Lee SK. ScaphoLunate Axis Method. J Wrist Surg 2016; 5 (01) 59-66
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 20 Johnson JC, Pfeiffer FM, Jouret JE, Brogan DM. Biomechanical analysis of capsular re-pair versus arthrex TFCC ulnar tunnel repair for triangular fibrocartilage complex tears. Hand (N Y) 2019; 14 (04) 547-553
  CrossrefPubMedGoogle Scholar
• 21 Mathoulin CL, Dauphin N, Wahegaonkar AL. Arthroscopic dorsal capsuloligamentous repair in chronic scapholunate ligament tears. Hand Clin 2011; 27 (04) 563-572 , xi
  CrossrefPubMedGoogle Scholar
• 22 del Piñal F, Studer A, Thams C, Glasberg A. An all-inside technique for arthroscopic suturing of the volar scapholunate ligament. J Hand Surg Am 2011; 36 (12) 2044-2046
  CrossrefPubMedGoogle Scholar
• 23 Carvalho VB, Ferreira CHV, Hoshino AR, Bernardo VA, Ruggiero GM, Aita MA. Dorsal capsulodesis associated with arthoscopy-assisted scapholunate ligament reconstruction using a palmaris longus tendon graft. Rev Bras Ortop 2017; 52 (06) 676-684
  PubMedGoogle Scholar
• 24 Aita MA, Alves RS, Ibanez DS, Consoni DAP, de Oliveira RK, Ruggiero GM. Reconstruction of radioscaphocapitate ligament in treatment of ulnar translation. J Wrist Surg 2019; 8 (02) 147-151
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 25 Mackay GM, Blyth MJ, Anthony I, Hopper GP, Ribbans WJ. A review of ligament augmentation with the InternalBrace™: the surgical principle is described for the lateral ankle ligament and ACL repair in particular, and a comprehensive review of other surgical applications and techniques is presented. Surg Technol Int 2015; 26: 239-255
  PubMedGoogle Scholar
• 26 Sonnery-Cottet B, Freychet B, Murphy CG, Pupim BHB, Thaunat M. Anterior cruciate ligament recon-struction an preservation: the single Anteromedial Bundle Biological Augmentation (SAMBBA) technique. Arthrosc Tech 2014; 3 (06) e689-e693
  CrossrefPubMedGoogle Scholar
• 27 Dimitris C, Werner FW, Joyce DA, Harley BJ. Force in the scapholunate interosseous lig-ament during active wrist motion. J Hand Surg Am 2015; 40 (08) 1525-1533
  CrossrefPubMedGoogle Scholar
• 28 Hagert E, Garcia-Elias M, Forsgren S, Ljung BO. Immunohistochemical analysis of wrist ligament innervation in relation to their structural composition. J Hand Surg Am 2007; 32 (01) 30-36
  CrossrefPubMedGoogle Scholar
• 29 Aita MA, Mallozi RC, Ozaki W, Ikeuti DH, Consoni DAP, Ruggiero GM. Ligamentous reconstruction of the interosseous membrane of the forearm in the treatment of instability of the distal radioulnar joint. Rev Bras Ortop 2018; 53 (02) 184-191
  Google Scholar

Address for correspondence

Publikationsverlauf

Eingereicht: 19. August 2020

Angenommen: 04. Februar 2021

Artikel online veröffentlicht:
02. Juli 2021

© 2021. SECMA Foundation. This is an open access article published by Thieme under the terms of the Creative Commons Attribution-NonDerivative-NonCommercial License, permitting copying and reproduction so long as the original work is given appropriate credit. Contents may not be used for commecial purposes, or adapted, remixed, transformed or built upon. (https://creativecommons.org/licenses/by-nc-nd/4.0/)

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• References

• 1 De Zwart AD, Beeres FJ, Ring D. et al. MRI as a reference standard for suspected scaphoid fractures. Br J Radiol 2012; 85 (1016): 1098-1101
  CrossrefPubMedGoogle Scholar
• 2 Gilley E, Puri SK, Hearns KA, Weiland AJ, Carlson MG. Importance of computed to-mography in determining displacement in scaphoid fractures. J Wrist Surg 2018; 7 (01) 38-42
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 3 Larribe M, Gay A, Freire V, Bouvier C, Chagnaud C, Souteyrand P. Usefulness of dynamic contrast-enhanced MRI in the evaluation of the viability of acute scaphoid fracture. Skeletal Radiol 2014; 43 (12) 1697-1703
  CrossrefPubMedGoogle Scholar
• 4 Goffin JS, Liao Q, Robertson GAJ. Return to sport following scaphoid fractures: A systematic review and meta-analysis. World J Orthop 2019; 10 (02) 101-114
  CrossrefPubMedGoogle Scholar
• 5 Muller ME. et al. Manual of Internal Fixation, AO-ASIF, 1980. ISBN 3–540–52523–8. 3rd ed.. 1995
  Google Scholar
• 6 Hintringer W, Rosenauer R, Pezzei C. et al. Biomechanical considerations on a CT-based treatment-oriented classification in radius fractures. Arch Orthop Trauma Surg 2020; 140 (05) 595-609
  CrossrefPubMedGoogle Scholar
• 7 Wong K, von Schroeder HP. Delays and poor management of scaphoid fractures: factors contributing to nonunion. J Hand Surg Am 2011; 36 (09) 1471-1474
  CrossrefPubMedGoogle Scholar
• 8 Bain GI, MacLean SBM, McNaughton T, Williams R. Microstructure of the distal radius and its relevance to distal radius fractures. J Wrist Surg 2017; 6 (04) 307-315
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 9 Short WH, Palmer AK, Werner FW, Murphy DJ. A biomechanical study of distal radial fractures. J Hand Surg Am 1987; 12 (04) 529-534
  CrossrefPubMedGoogle Scholar
• 10 Gabl M, Arora R, Schmidle G. Biomechanik distaler Radiusfrakturen : Grundlagenverständnis und GPS-Behandlungsstrategie bei winkelstabiler Plattenosteosynthese. Unfallchirurg 2016; 119 (09) 715-722
  CrossrefPubMedGoogle Scholar
• 11 Goldfarb CA, Rudzki JR, Catalano LW, Hughes M, Borrelli Jr J. Fifteen-year outcome of displaced intra-articular fractures of the distal radius. J Hand Surg Am 2006; 31 (04) 633-639
  CrossrefPubMedGoogle Scholar
• 12 Garcia-Elias M, Puig de la Bellacasa I, Schouten C. Carpal ligaments: a functional classification. Hand Clin 2017; 33 (03) 511-520
  CrossrefPubMedGoogle Scholar
• 13 Hagert E, Lluch A, Rein S. The role of proprioception and neuromuscular stability in carpal instabilities. J Hand Surg Eur Vol 2016; 41 (01) 94-101
  CrossrefPubMedGoogle Scholar
• 14 Herzberg G. Perilunate injuries, not dislocated (PLIND). J Wrist Surg 2013; 2 (04) 337-345
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 15 Corella F, Ocampos M, Cerro MD, Larrainzar-Garijo R, Vázquez T. Volar central por-tal in wrist arthroscopy. J Wrist Surg 2016; 5 (01) 80-90
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 16 Del Piñal F. Technical tips for (dry) arthroscopic reduction and internal fixation of distal radius fractures. J Hand Surg Am 2011; 36 (10) 1694-1705
  CrossrefPubMedGoogle Scholar
• 17 Burn MB, Sarkissian EJ, Yao J. Long-term outcomes for arthroscopy thermal treatment for Scapholunate ligament injuries. J Wrist Surg 2020; 9 (01) 22-28
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 18 Carratalá V, Lucas FJ, Miranda I, Sánchez Alepuz E, González Jofré C. Arthroscopic scapholunate capsule ligamentous repair: suture with dorsal capsular reinforcement for scapholunate ligament lesion. Arthrosc Tech 2017; 6 (01) e113-e120
  CrossrefPubMedGoogle Scholar
• 19 Yao J, Zlotolow DA, Lee SK. ScaphoLunate Axis Method. J Wrist Surg 2016; 5 (01) 59-66
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 20 Johnson JC, Pfeiffer FM, Jouret JE, Brogan DM. Biomechanical analysis of capsular re-pair versus arthrex TFCC ulnar tunnel repair for triangular fibrocartilage complex tears. Hand (N Y) 2019; 14 (04) 547-553
  CrossrefPubMedGoogle Scholar
• 21 Mathoulin CL, Dauphin N, Wahegaonkar AL. Arthroscopic dorsal capsuloligamentous repair in chronic scapholunate ligament tears. Hand Clin 2011; 27 (04) 563-572 , xi
  CrossrefPubMedGoogle Scholar
• 22 del Piñal F, Studer A, Thams C, Glasberg A. An all-inside technique for arthroscopic suturing of the volar scapholunate ligament. J Hand Surg Am 2011; 36 (12) 2044-2046
  CrossrefPubMedGoogle Scholar
• 23 Carvalho VB, Ferreira CHV, Hoshino AR, Bernardo VA, Ruggiero GM, Aita MA. Dorsal capsulodesis associated with arthoscopy-assisted scapholunate ligament reconstruction using a palmaris longus tendon graft. Rev Bras Ortop 2017; 52 (06) 676-684
  PubMedGoogle Scholar
• 24 Aita MA, Alves RS, Ibanez DS, Consoni DAP, de Oliveira RK, Ruggiero GM. Reconstruction of radioscaphocapitate ligament in treatment of ulnar translation. J Wrist Surg 2019; 8 (02) 147-151
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 25 Mackay GM, Blyth MJ, Anthony I, Hopper GP, Ribbans WJ. A review of ligament augmentation with the InternalBrace™: the surgical principle is described for the lateral ankle ligament and ACL repair in particular, and a comprehensive review of other surgical applications and techniques is presented. Surg Technol Int 2015; 26: 239-255
  PubMedGoogle Scholar
• 26 Sonnery-Cottet B, Freychet B, Murphy CG, Pupim BHB, Thaunat M. Anterior cruciate ligament recon-struction an preservation: the single Anteromedial Bundle Biological Augmentation (SAMBBA) technique. Arthrosc Tech 2014; 3 (06) e689-e693
  CrossrefPubMedGoogle Scholar
• 27 Dimitris C, Werner FW, Joyce DA, Harley BJ. Force in the scapholunate interosseous lig-ament during active wrist motion. J Hand Surg Am 2015; 40 (08) 1525-1533
  CrossrefPubMedGoogle Scholar
• 28 Hagert E, Garcia-Elias M, Forsgren S, Ljung BO. Immunohistochemical analysis of wrist ligament innervation in relation to their structural composition. J Hand Surg Am 2007; 32 (01) 30-36
  CrossrefPubMedGoogle Scholar
• 29 Aita MA, Mallozi RC, Ozaki W, Ikeuti DH, Consoni DAP, Ruggiero GM. Ligamentous reconstruction of the interosseous membrane of the forearm in the treatment of instability of the distal radioulnar joint. Rev Bras Ortop 2018; 53 (02) 184-191
  Google Scholar