Skip to main content
Download PDF

Biomechanical analysis of plate versus K-wire fixation for metacarpal shaft fractures with wedge-shaped bone defects

BMC Musculoskeletal Disorders volume 25, Article number: 350 (2024) Cite this article

Abstract

Background

Metacarpal shaft fracture is a common type of hand fracture. Numerous studies have explored fixing transverse fractures in the midshaft of the metacarpal bone. However, this section of the metacarpal bone is often susceptible to high-energy injury, resulting in comminuted fracture or bone loss. In such cases, wedge-shaped bone defects can develop in the metacarpal shaft, increasing the difficulty of performing fracture fixation. Notably, the research on this type of fracture fixation is limited. This study compared the abilities of four fixation methods to fix metacarpal shaft fractures with wedge-shaped bone defects.

Methods

In total, 28 artificial metacarpal bones were used. To create wedge-shaped bone defects, an electric saw was used to create metacarpal shaft fractures at the midshaft of each bone. The artificial metacarpal bones were then divided into four groups for fixation. The bones in the first group were fixed with a dorsal locked plate (DP group), those in the second group were fixed with a volar locked plate (VP group), and those in the third group were fixed by combining dorsal and volar locked plates (DP + VP group), and those in the fourth group were fixed with two K-wires (2 K group). Cantilever bending tests were conducted using a material testing machine to measure yielding force and stiffness. The four groups’ fixation capabilities were then assessed through analysis of variance and Tukey’s test.

Results

The DP + VP group (164.1±44.0 N) achieved a significantly higher yielding force relative to the 2 K group (50.7 ± 8.9 N); the DP group (13.6 ± 3.0 N) and VP group (12.3 ± 1.0 N) did not differ significantly in terms of yielding force, with both achieving lower yielding forces relative to the DP + VP group and 2 K group. The DP + VP group (19.8±6.3 N/mm) achieved the highest level of stiffness, and the other three groups did not differ significantly in terms of stiffness (2 K group, 5.4 ± 1.1 N/mm; DP group, 4.0 ± 0.9 N/mm; VP group, 3.9 ± 1.9 N/mm).

Conclusions

The fixation method involving the combined use of dorsal and volar locked plates (DP + VP group) resulted in optimal outcomes with respect to fixing metacarpal shaft fractures with volar wedge bone defects.

Peer Review reports

Introduction

Metacarpal bones are a primary skeletal component of the palm, and the metacarpal shaft is crucial for hand prehension. Metacarpal fractures are common, accounting for approximately 40% of hand fractures [1], and such fractures can mostly be treated nonsurgically, with treatment methods such as splint immobilization often yielding satisfactory outcomes. However, surgical intervention may be required for metacarpal fractures that exhibit more complexity or unstable fracture patterns, especially oblique or spiral fractures or those causing metacarpal shortening [2,3,4,5]. Common clinical fixation methods include lag screw fixation, bone plate fixation, and K-wire fixation. However, no consensus has been reached regarding the appropriate fixation method for treating complex cases of metacarpal shaft fractures, such as comminuted fractures or those involving bone loss [3, 6]. K-wire fixation is a minimally invasive surgical technique that violates least blood circulation and soft tissue at the fracture site, thereby enhancing the bone union. However, for comminuted metacarpal shaft fractures or cases involving wedge-shaped bone defect, whether K-wire fixation can provide sufficient fixation strength at the fracture site remains unclear [7]. Generally, lag screw fixation is excluded as a treatment option for comminuted metacarpal shaft fractures or cases involving bone loss because this surgical procedure is challenging and that may cause fractured bone shortening. The disadvantages of bone plate fixation include the requirement for extensive soft tissue dissection, which may lead to poor preservation of blood circulation at the fracture site [8,9,10]. Although bone plate fixation provides greater fracture fixation strength relative to other methods, no consensus has been reached regarding the optimal position and number of plates for the procedure. Therefore, by conducting a biomechanical study, we identified the optimal fixation method for treating comminuted metacarpal shaft fractures or those involving bone loss.

When metacarpal shaft fractures occur because of falling or punching, the most common resulting fracture patterns are transverse, oblique, or spiral fractures. These types of fracture generally exhibit good cortical bone contact after fracture reduction, allowing for effective bone healing when the appropriate fixation strength is applied [5, 11]. However, in highly complex situations (e.g., fractures caused by crushing injuries, the recalcitrant nonunion of fractures, or the development of osteomyelitis), bone absorption is likely to occur at the site of a metacarpal shaft fracture. In such cases, good cortical bone contact after fracture reduction is unlikely to achieve because of partial bone loss. Consequently, the fracture healing process is prolonged, and greater fracture fixation strength is required to support bone union.

Plate fixation is commonly used to treat metacarpal shaft fractures, and most hand surgeons have agreed that this method provides a stronger fixation strength in comparison to other fixation methods. However, the optimal placement of bone plates on the metacarpal shaft remains unclear. Notably, how the strongest fixation strength can be achieved when bone loss occurs at the site of a metacarpal shaft fracture remains a subject of debate. Most metacarpal shaft fractures involving bone loss occur on the volar side because the intrinsic muscles of the hand generate a traction force on the fracture’s end, causing dorsal angulation deformity [12, 13]. Consequently, the volar side cortical bone of the fracture end experiences compression force [14]. If proper fracture fixation is not performed during the acute stage, the volar cortical bone may eventually experience bone absorption resulting in bone loss at the fracture site [15].

Numerous studies have explored methods for fixing horizontal or oblique fractures at the metacarpal shaft. However, no study has comprehensively discussed methods for fixing a fracture in the midshaft of a metacarpal bone with wedge-shaped bone defects. In the present study, we used artificial metacarpal bones that simulated the material properties of real cortical bone and cancellous bone to compare the abilities of four methods—fixation with a volar locked plate, fixation with a dorsal locked plate, fixation involving the combined use of dorsal and volar locked plates, and fixation with two K-wires—to fix a fracture in the midshaft of a metacarpal bone with wedge-shaped bone defects.

Materials and methods

Preparation of artificial metacarpal bone specimens

In this study, artificial third metacarpal bones (Sawbones, Vashon, WA, USA) were employed because of the considerable challenge of acquiring a sufficient number real human metacarpal bones with comparable bone quality and size. In total, 28 artificial metacarpal bone specimens were used in the present study. Due to the joint capsule and muscle attachments at both the metacarpal head and metacarpal base, fractures often occur at the more fragile metacarpal shaft, especially under injury mechanisms that create a torsion force, resulting in a comminuted metacarpal shaft fracture. This often causes a wedge-shaped bone defect on the volar side. We created a uniform wedge-shaped bone defect fracture model in the middle of the metacarpal shaft to investigate which fixation method would achieve the best mechanical strength. This facilitates a more reference-worthy biomechanical study on fracture fixation methods [16,17,18].

Fixation methods

All specimens were assigned to undergo one of four fixation techniques performed by a single senior hand surgeon (Yung-Cheng Chiu). An electric saw created a wedge-shaped bone defect on the volar side of all the artificial bones. The wedge-shaped bone defect had a base-side measuring 0.6 cm and a perpendicular height of 1.0 cm.

  • Group 1: Seven specimens were assigned to the dorsal locked plate (DP) group and stabilized using a 5-hole straight locked plate that was secured with four locked screws with a 2.3-mm diameter (Stryker, Freiburg, Germany). Initially, the 5-hole locked plate was positioned on the dorsal side of the metacarpal shaft and centered on the fracture site. Subsequently, two bicortical locked screws were inserted distally to the fracture site, after which two bicortical locked screws were inserted proximally to the fracture site. Throughout the surgical procedure, fracture alignment was maintained through manual axial compression (Fig. 1a).

  • Group 2: Seven specimens were assigned to the volar locked plate (VP) group and stabilized using a 5-hole straight locked plate that was secured with four locked screws with a 2.3-mm diameter (Stryker, Freiburg, Germany). Initially, the 5-hole locked plate was positioned on the volar side of the metacarpal shaft and centered on the fracture site. Subsequently, two bicortical locked screws were inserted distally to the fracture site, after which two bicortical locked screws were inserted proximally to the fracture site. Throughout the surgical procedure, fracture alignment was maintained through manual axial compression (Fig. 1b).

  • Group 3: Seven specimens were assigned to the dorsal and volar locked plate (DP + VP) group. These specimens were stabilized using one 5-hole straight locked plate and one 3-hole straight locked plate that were secured with four locked screws with a 2.3-mm diameter (Stryker, Freiburg, Germany). Initially, the 5-hole locked plate was positioned on the volar side of the metacarpal shaft and centered on the fracture site. Subsequently, one bicortical locked screws were inserted distally to the fracture site, after which one bicortical locked screws were inserted proximally to the fracture site. The 3-hole locked plate was then positioned on the dorsal side of the metacarpal shaft and centered on the fracture site. One bicortical locked screw was then inserted distally to the fracture site, after which one bicortical locked screw was inserted proximally to the fracture site. Throughout the surgical procedure, fracture alignment was maintained through manual axial compression (Fig. 1c).

  • Group 4: Seven specimens were assigned to the two K-wire (2 K) group and secured using two K-wires (diameter, 1.4 mm) that were inserted distally from the metacarpal head; these K-wires traversed through the intramedullary canal of the fracture site and emerged proximally by punching out from the lateral side cortex in the supracondylar region. The two K-wires were applied in a cross-pin fixation configuration, and fracture reduction was maintained through manual axial compression throughout the surgical procedure (Fig. 1d).

Fig. 1
figure 1

Photographs (left) and radiographs (right) of four types of fixation methods involving the use of (a) a locked plate with four locked bicortical screws on the dorsal side, (b) a locked plate with four locked bicortical screws on the volar side, (c) a combination of a 3-hole locked plate with two locked bicortical screws on the dorsal side and a 5-hole locked plate with two locked bicortical screws on the volar side, and (d) two K-wires in a cross-pin fixation configuration

Full size image

Biomechanical test

Based on the research protocols of other studies [19,20,21,22], the present study performed cantilever bending tests to evaluate the four tested methods. Prior to conducting cantilever bending tests, we used molded epoxy clamps to securely hold the proximal end of each artificial third metacarpal bone in a custom fixture. The tests were performed using a material testing system (JSV-H1000, Japan Instrumentation System, Nara, Japan; Fig. 2). A perpendicular load was applied to the dorsal side of a specimen at a point 50 mm distant from the fixture until the specimen failed. In each test, a loading speed of 10 mm/min was maintained. Force-displacement data were recorded, enabling us to determine the maximum fracture force experienced by each tested specimen and its stiffness.

Fig. 2
figure 2

Experimental setup: (a) full view and (b) closeup view

Full size image

Statistical analysis

The present study summarized the results (presented as means and standard deviations) pertaining to the maximum fracture force and stiffness of the specimens with metacarpal shaft fractures, which were treated using five fixation methods. First, one-way analysis of variance and Tukey’s test were conducted at a significance level of 0.05 to compare the fracture force and stiffness of the specimens with fractures. All statistical analyses were performed using SPSS Version 19 (IBM Corporation, Armonk, NY, USA).

Results

The experimental results for yielding force and stiffness are presented in Table 1. Regarding yielding force (Fig. 3a), the DP + VP group (mean ± standard deviation, 164.1 ± 44.0 N) achieved a significantly higher yielding force value relative to the 2 K group (50.7 ± 8.85 N), and the DP group (13.6 ± 3.0 N) and VP group (12.3 ± 1.0 N) achieved lower levels of yielding force relative to the other four groups but did not differ significantly from each other (P > 0.05). For stiffness (Fig. 3b), the DP + VP group (19.8 ± 6.3 N/mm) achieved the highest level of stiffness, and the other three groups did not differ significantly in terms of stiffness (P > 0.05).

Table 1 Yielding force (N) and stiffness (N/mm) achieved through four fixation methods
Full size table
Fig. 3
figure 3

Box plot presenting yielding force (a) and stiffness (b) achieved through the four fixation methods. Post hoc pairwise comparisons were conducted using Tukey’s test. In this box plot, identical lowercase English letters within groups indicate non-statistically significant differences at the 0.05 significance level. Groups: DP group, group in which specimens underwent fixation involving the use of a locked plate with four locked bicortical screws on the dorsal side; VP group, group in which specimens underwent fixation involving the use of a locked plate with four locked bicortical screws on the lateral side; DP + VP group, group in which specimens underwent fixation involving the combined use of a locked plate with two locked bicortical screws on the dorsal side and a locked plate with two locked bicortical screws on the lateral side; 2 K group, group in which specimens underwent fixation involving the use of two K-wires

Full size image

Discussion

Metacarpal shaft fractures are among the most commonly reported hand fractures. Although most studies have focused on investigating and discussing methods for fixing transverse fractures at the midshaft of the metacarpal bone, clinical observations have indicated that wedge-shaped bone defects also frequently occur at this location [15]. Despite this, research on fixation methods specifically tailored for treating metacarpal shaft fractures accompanied by wedge-shaped bone defects remains scarce. The present study preliminarily used artificial bones to investigate the simultaneous use of locked plates on the volar and dorsal sides to treat midshaft metacarpal fractures with wedge-shaped defects, and it revealed that this method led to considerably more favorable fixation outcomes compared to methods that solely involve the use of a dorsal locked plate, a volar locked plate, or K-wires.

In this study, artificial metacarpal bones were utilized due to the challenges associated with obtaining cadaver bones. Another contributing factor is the prevalence of metacarpal fractures among young individuals, whose bodies, characterized by solid bone density, are less readily available for research. Even if accessible, obtaining a sufficient number of metacarpal bones from young cadavers presents logistical difficulties. Previous research has commonly employed either porcine metacarpal bones [23,24,25] or artificial alternatives [19, 27]. Our decision to utilize artificial bones aimed to ensure uniformity and consistency across all test samples, facilitating a fair comparison of fixation abilities among various osteosynthetic techniques. The selection of artificial bones aligns with guidelines provided by the American Society for Testing and Materials (F-1839-08) (17, 27–28), which recognizes artificial bones as the most appropriate material for such research endeavors. This choice also ensures compliance with ethical considerations regarding using human or animal specimens. We chose to conduct cantilever bending tests in this study, which, although slightly different from the physiological loading tests commonly employed in clinical settings, serve as a valuable method for evaluating fixation capabilities. It’s important to note that no existing in vitro biomechanical test perfectly replicates the exact physiological loading conditions. In addition to cantilever bending tests, previous research has utilized various other mechanical testing modes, such as the three-point bending test [26], modified three-point bending test [23, 24], four-point bending test [27], and torsional test [19]. Our study employs cantilever bending tests because relevant literature commonly utilizes this method [19, 21, 22]. Therefore, the present study conducted cantilever bending tests to evaluate the four tested methods. Because our experiment involved the simulation of metacarpal shaft fractures with wedge-shaped bone defects, the locked plates used in DP or VP fixation were likely to permanently deform without causing fractures when a cantilever bending test was performed (Fig. 4.). Therefore, the present study used yielding force as an evaluation criterion instead of maximum fracture force.

Fig. 4
figure 4

Photographs of specimens from four fixation groups after cantilever bending testing: (a) DP specimen, (b) VP specimen, (c) DP + VP specimen, and (d) 2 K specimen. Groups: DP group, group in which specimens underwent fixation involving the use of a locked plate with four locked bicortical screws on the dorsal side; VP group, group in which specimens underwent fixation involving the use of a locked plate with four locked bicortical screws on the volar side; DP + VP group, group in which specimens underwent fixation involving the combined use of a 3-hole locked plate with two locked bicortical screws on the dorsal side and a 5-hole locked plate with two locked bicortical screws on the volar side; 2 K group, group in which specimens underwent fixation involving the use of two K-wires

Full size image

Numerous studies have identified the use of two K-wires as a standard method for fixing metacarpal shaft transverse fractures [2, 14]. Through this method, satisfactory results can be achieved because no bone loss occurs at the fracture site, and cortical bone contact is excellent after fracture reduction and fixation. Consequently, when patients begin grasping/prehension rehabilitation, K-wire fixation can create a tension band effect that allows for effective bone union on both the volar and dorsal side of cortex at the fracture site [28, 29]. On the other hand, when bone loss occurs on the volar side at metacarpal shaft fracture site, a patient who begins grasping/prehension rehabilitation experiences considerable stress at the fracture end on the volar side because of the lack of proper cortical bone contact. In such cases, the entire fixation may fail if the K-wire fixation cannot withstand the forces generated by the movement at the fracture end.

There is a notable scarcity of biomechanical studies comparing fixation methods in metacarpal shaft fractures with wedge-shaped bone defects. Gajendran et al. [30] conducted a biomechanical evaluation comparing the efficacy of double-row locking plates with single- and double-row non-locking plates using a comminuted metacarpal fracture model. This model involved creating a 3-mm gap in fourth-generation biomechanical testing grade composite sawbones by removing a 3-mm block of bone from the diaphysis at the midpoint of each metacarpal [30]. Wedge-shaped bone defects can manifest in any part of the bone, with the formation of the wedge fragment on either the volar or dorsal side, depending on the force causing the fracture. The defect’s size and shape significantly influence the stability of internal fixation. In clinical settings, the force-deforming metacarpal shaft fractures are typically directed towards the volar side, resulting in most malunited metacarpal fractures being dorsally angulated [16,17,18]. Our wedge-shaped bone defect metacarpal fracture model is designed to replicate clinical observations, showing that volar defects are more common than dorsal defects or a combination of both. Through our experiment, we demonstrated that the forces supported by K-wire fixation are comparable to those supported by dorsal or volar locked plate fixation. That is, when bone loss occurs on the volar side at the site of a metacarpal shaft fracture, single-plate fixation does not provide a mechanical advantage over two K-wires fixation. This insufficiency led to the K-wire breakage and permanent plate deformity. For the fixation module involving a combination of dorsal and volar locked plates, fracture occurred at the junction of the plate and bone, and no deformity occurred at the fracture site. These findings indicate that when bone defects occur on the volar side of a metacarpal shaft fracture, to enable patients to begin grasping/prehension training earlier, a combination of dorsal and volar locked plates should be recommended to be applied for fracture fixation. When fixation with K-wire fixation, single dorsal plate fixation, and single volar plate fixation, patients are advised to wear a plaster cast for an extended period until callus formation is visible on X-ray images. At this point, they can commence their rehabilitation program.

Similar to most other studies [19, 22, 31, 32], the present study conducted in vitro mechanical experiments by using artificial bones, which are commonly used in the fields of orthopedics and dentistry; this is because obtaining fresh human bones with similar strengths is difficult. Currently, no optimal design has been established for an in vitro mechanical experiment that simulates the forces applied to metacarpal bones experiencing volar wedge bone defects in the midshaft area. On the basis of the research protocols of other studies [19, 21, 22], the present study performed cantilever bending testing to assess the abilities of several fracture fixation methods. However, our study analyzed only four methods for fixing metacarpal shaft fractures with wedge-shaped bone defects. That is, it did not explore fixation methods such as intramedullary screw fixation, K-pin, and external fixation. Future studies should address this limitation by analyzing additional fixation methods to conduct a more comprehensive experimental analysis.

Conclusion

The present study used artificial bones in a mechanical experiment involving cantilever bending tests. When a midshaft metacarpal fracture is accompanied by a wedge-shaped bone defect, a fixation method involving a combination of dorsal and volar locked plates can lead to more favorable fixation outcomes relative to methods involving a dorsal locked plate, a volar locked plate, or K-wires. Patients treated using a fixation method involving a combination of dorsal and volar locked plates are more likely to achieve successful fracture union and more favorable clinical functional outcomes.

Data availability

All data generated or analyzed during this study are included in this published article.

References

  1. Feehan LM, Sheps SB. Incidence and demographics of hand fractures in British Columbia, Canada: a population-based study. J Hand Surg Am. 2006;31(7):e10681–9.

    Article  Google Scholar 

  2. Kawamura K, Chung KC. Fixation choices for closed simple unstable oblique phalangeal and metacarpal fractures. Hand Clin. 2006;22(3):287–95.

    Article  PubMed  Google Scholar 

  3. Padegimas EM, Warrender WJ, Jones CM, Ilyas AM. Metacarpal neck fractures: a review of surgical indications and techniques. Arch Trauma Res. 2016;5(3):e32933.

    Article  PubMed  PubMed Central  Google Scholar 

  4. Hussain MH, Ghaffar A, Choudry Q, Iqbal Z, Khan MN. Management of fifth metacarpal neck fracture (boxer’s fracture): a literature review. Cureus. 2020;12(7):e9442.

    PubMed  PubMed Central  Google Scholar 

  5. Sahu A, Gujral S, Batra S, Mills S, Srinivasan M. The current practice of the management of little finger metacarpal fractures—a review of the literature and results of a survey conducted among upper limb surgeons in the United Kingdom. Hand Surg. 2012;17(01):55–63.

    Article  CAS  PubMed  Google Scholar 

  6. Orbay JL, Touhami A. The treatment of unstable metacarpal and phalangeal shaft fractures with flexible nonlocking and locking intramedullary nails. Hand Clin. 2006;22(3):279–86.

    Article  PubMed  Google Scholar 

  7. Carlo Biz C, Iacobellis. Comparison of percutaneous intramedullary Kirschner wire and interfragmentary screw fixation of displaced extra-articular metacarpal fractures. Acta Biomed. 2014;85(3):252–64.

    PubMed  Google Scholar 

  8. Fusetti C, Meyer H, Borisch N, Stern R, Della Santa D, Papaloïzos M. Complications of plate fixation in metacarpal fractures. J Trauma Acute Care Surg. 2002;52(3):535–9.

    Article  Google Scholar 

  9. Page SM, Stern PJ. Complications and range of motion following plate fixation of metacarpal and phalangeal fractures. J Hand Surg Am. 1998;23(5):827–32.

    Article  CAS  PubMed  Google Scholar 

  10. Dyrna FG, Avery DM, Yoshida R, Lam D, Oeckenpöhler S, Cote MP, et al. Metacarpal shaft fixation: a biomechanical comparison of dorsal plating, lag screws, and headless compression screws. BMC Musculoskelet Disord. 2021;22(1):1–8.

    Article  Google Scholar 

  11. Boussakri H, Elidrissi M, Azarkane M, Bensaad S, Bachiri M, Shimi M, et al. Fractures of the neck of the fifth metacarpal bone, treated by percutaneous intramedullary nailing: surgical technique, radiological and clinical results study (28 cases). Pan Afr Med J. 2014;18:187.

    Article  PubMed  PubMed Central  Google Scholar 

  12. Low C, Wong H, Low Y, Wong H. A cadaver study of the effects of dorsal angulation and shortening of the metacarpal shaft on the extension and flexion force ratios of the index and little fingers. J Hand Surg Am. 1995;20(5):609–13.

    Article  CAS  Google Scholar 

  13. Pereira BP, Low CK, Ng RTH, Low YP, Wong HP. The effect of fracture malunion at the mid-shaft of the metacarpal on the extrinsic muscle forces. Clin Biomech. 1998;13(7):485–91.

    Article  Google Scholar 

  14. Kozin SH, Thoder JJ, Lieberman G. Operative treatment of metacarpal and phalangeal shaft fractures. J Am Acad Orthop Surg. 2000;8(2):111–21.

    Article  CAS  PubMed  Google Scholar 

  15. Cha SM, Kang JW, Shin HD, Lee SH, Lee CW. Antegrade intramedullary nailing in comminuted, open metacarpal bone fracture: maintenance of the length. Arch Orthop Trauma Surg. 2021;141(10):1815–23.

    Article  PubMed  Google Scholar 

  16. Balaram AK, Bednar MS. Complications after the fractures of metacarpal and phalanges. Hand Clin. 2010;26(2):169–77.

    Article  PubMed  Google Scholar 

  17. Izmalkov SN, Semenkin OM, Bratiichuk AN, Litvinov SA. Opening-wedge V-shaped corrective osteotomy for malunited fractures of metacarpal bones. J Orthop. 2020;19:208–11.

    Article  PubMed  Google Scholar 

  18. Ring D. Malunion and nonunion of the metacarpals and phalanges. Instr Course Lect. 2006;55:121–8.

    PubMed  Google Scholar 

  19. Barr C, Behn AW, Yao J. Plating of metacarpal fractures with locked or nonlocked screws, a biomechanical study: how many cortices are really necessary? Hand (N Y). 2013;8(4):454–9.

    Article  PubMed  Google Scholar 

  20. Chiu Y-C, Hsu C-E, Ho T-Y, Ting Y-N, Tsai M-T, Hsu J-T. Bone plate fixation ability on the dorsal and lateral sides of a metacarpal shaft transverse fracture. J Orthop Surg Res. 2021;16(1):1–10.

    Article  Google Scholar 

  21. Watt AJ, Ching RP, Huang JI. Biomechanical evaluation of metacarpal fracture fixation: application of a 90 degrees internal fixation model. Hand (N Y). 2015;10(1):94–9.

    Article  PubMed  Google Scholar 

  22. Yang C-Y, Liu T-Y, Hsu J-T, Tsai M-T. Biomechanical analysis of new cross locking plates for metacarpal neck fracture. J Med Biol Eng. 2022;42(4):404–13.

    Article  Google Scholar 

  23. Doht S, Meffert RH, Raschke MJ, Blunk T, Ochman S. Biomechanical analysis of the efficacy of locking plates during cyclic loading in metacarpal fractures. ScientificWorldJournal. 2014;2014:648787.

    Article  PubMed  PubMed Central  Google Scholar 

  24. Malasitt P, Owen JR, Tremblay M-A, Wayne JS, Isaacs JE. Fixation for metacarpal neck fracture: a biomechanical study. Hand. 2015;10(3):438–43.

    Article  PubMed  PubMed Central  Google Scholar 

  25. Ochman S, Vordemvenne T, Paletta J, Raschke MJ, Meffert RH, Doht S. Experimental fracture model versus osteotomy model in metacarpal bone plate fixation. ScientificWorldJournal. 2011;11:1692–8.

    Article  CAS  PubMed  PubMed Central  Google Scholar 

  26. Beaumont CM, Beason DP, McKeon KE. Fracture fixation strength in metacarpal plating versus intramedullary nailing using a 3-Point bending model: a cadaveric, biomechanical study. J Hand Surg Am. 2024;49(1):57. e1-57.e6.

    Article  Google Scholar 

  27. Liodaki E, Wendlandt R, Waizner K, Schopp BE, Mailander P, Stang F. A biomechanical analysis of plate fixation using unicortical and bicortical screws in transverse metacarpal fracture models subjected to 4-point bending and dynamical bending test. Med (Baltim). 2017;96(27):e6926.

    Article  Google Scholar 

  28. Maden M, Dulgeroglu AM, Bacaksiz T, Kazimoglu C. Does pin configuration matter in modified tension band wiring for transverse patellar fracture? A biomechanical study. Knee. 2022;39:300–7.

    Article  PubMed  Google Scholar 

  29. Kim Y, Kwon M, Ryu JY, Moon SW. Biomechanical analysis of the Kirschner-Wire depth of the modified tension band wiring technique in transverse patellar fractures: an experimental study using the finite-element method. Clin Orthop Surg. 2021;13(3):315.

    Article  PubMed  PubMed Central  Google Scholar 

  30. Gajendran VK, Szabo RM, Myo GK, Curtiss SB. Biomechanical comparison of double-row locking plates versus single-and double-row non-locking plates in a comminuted metacarpal fracture model. J Hand Surg Am. 2009;34(10):1851–8.

    Article  PubMed  Google Scholar 

  31. Galbraith JG, Huntington LS, Borbas P, Ackland DC, Tham SK, Ek ET. Biomechanical comparison of intramedullary screw fixation, dorsal plating and K-wire fixation for stable metacarpal shaft fractures. J Hand Surg Eur Vol. 2022;47(2):172–8.

    Article  PubMed  Google Scholar 

  32. Jones CM, Padegimas EM, Weikert N, Greulich S, Ilyas AM, Siegler S. Headless screw fixation of metacarpal neck fractures: a mechanical comparative analysis. Hand. 2019;14(2):187–92.

    Article  PubMed  Google Scholar 

Download references

Acknowledgements

Not applicable.

Funding

This research was partially supported by China Medical University, Taiwan (Grant number: CMU111-MF-92 and CMU112-S-10).

Author information

Authors and Affiliations

  1. School of Medicine, China Medical University, Taichung, 404, Taiwan

    Yung-Cheng Chiu, Tsung-Yu Ho & Chen-Wei Yeh

  2. Department of Orthopedic Surgery, China Medical University Hospital, Taichung, 404, Taiwan

    Yung-Cheng Chiu, Tsung-Yu Ho & Chen-Wei Yeh

  3. Department of Orthopaedics, Taichung Veterans General Hospital, Taichung, 407, Taiwan

    Cheng-En Hsu

  4. Sports Recreation and Health Management Continuing Studies-Bachelor’s Degree Completion Program, Tunghai University, Taichung, 407, Taiwan

    Cheng-En Hsu

  5. 3D Printing Medical Research Center, China Medical University Hospital, Taichung, 404, Taiwan

    Yen-Nien Ting

  6. Department of Biomedical Engineering, Hungkuang University, Taichung, 433, Taiwan

    Ming-Tzu Tsai

  7. Department of Biomedical Engineering, China Medical University, Taichung, 404, Taiwan

    Jui-Ting Hsu

  8. School of Dentistry, China Medical University, Taichung, 404, Taiwan

    Jui-Ting Hsu

Authors
  1. Yung-Cheng Chiu
    View author publications

    You can also search for this author in PubMed Google Scholar

  2. Tsung-Yu Ho
    View author publications

    You can also search for this author in PubMed Google Scholar

  3. Cheng-En Hsu
    View author publications

    You can also search for this author in PubMed Google Scholar

  4. Chen-Wei Yeh
    View author publications

    You can also search for this author in PubMed Google Scholar

  5. Yen-Nien Ting
    View author publications

    You can also search for this author in PubMed Google Scholar

  6. Ming-Tzu Tsai
    View author publications

    You can also search for this author in PubMed Google Scholar

  7. Jui-Ting Hsu
    View author publications

    You can also search for this author in PubMed Google Scholar

Contributions

YC, CH and JH participated in the design of the study. YC, CH, TH, CY, YT, MT and JH carried out the measurement. YC, CH, TH, YT, CY, MT and JH carried out the statistical analysis. YC, CH and JH conceived of the study, and participated in its design and coordination and draft the manuscript. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Jui-Ting Hsu.

Ethics declarations

Ethics approval and consent to participate

Not applicable.

Consent for publication

Not applicable.

Consent for publication

Not applicable.

Competing interests

The authors declare no competing interests.

Additional information

Publisher’s Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Rights and permissions

Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data.

Reprints and permissions

About this article

Check for updates. Verify currency and authenticity via CrossMark

Cite this article

Chiu, YC., Ho, TY., Hsu, CE. et al. Biomechanical analysis of plate versus K-wire fixation for metacarpal shaft fractures with wedge-shaped bone defects. BMC Musculoskelet Disord 25, 350 (2024). https://doi.org/10.1186/s12891-024-07482-2

Download citation

  • Received:

  • Accepted:

  • Published:

  • DOI: https://doi.org/10.1186/s12891-024-07482-2

Keywords

BMC Musculoskeletal Disorders

ISSN: 1471-2474

Contact us