A new low-profile anatomic locking plate for fixation of comminuted, displaced greater tuberosity fractures of the proximal humerus

Rational construction of PCL-PEG/CS/AST nanofiber for bone repair and regeneration

Humerus greater tuberosity (HGT) avulsion fracture is one of the most common types of proximal humerus fractures. The presence of motion and gap lead to the failure of implants, due to the force pulling from the supraspinatus. In this work, electrospinning technology was applied to fabricate PCL-PEG/CS/AST nanofiber with superior biocompatibility and mechanical property. Furthermore, PCL-PEG/CS/AST nanofiber could promote proliferation and osteogenic differentiation of bone mesenchymal stem cells (BMSCs) in vitro. We believe that this work indicates a promising way to promote the union of HGT avulsion fractures by using PCL-PEG/CS/AST nanofiber.

Comparison Study Among Three Surgical Methods in the Treatment of Isolated Fractures of the Greater Tuberosity of the Humerus

Introduction

This study aimed to compare the efficacy of three methods for isolated greater tuberosity fractures of the humerus.

Methods

A retrospective review of patients with isolated humeral greater tuberosity fractures between January 2013 and June 2021 in our institution. We recorded data on patient demographics, injury characteristics, preoperative and postoperative imaging findings, length of incision, operative time, and intraoperative blood loss.

Results

A total of 107 patients met the inclusion criteria and were divided into three groups. 50 patients in group A were administered a proximal humeral internal locking system (PHILOS) plate fixed using the deltopectoral approach, 26 patients in group B were administered a PHILOS plate fixed using the deltoid-splitting approach, and 31 patients in group C were administered a novel anatomical plate fixed using the deltoid-splitting approach. No significant differences were identified in sex, age, injury mechanism, type of fracture, dominant side limb, or shoulder anterior joint dislocation. However, the operative time, blood loss, and the length of incision was shorter than in Group C. Moreover, pain was evaluated on the third and fifth days after surgery; pain was lower in Group C, and pain at the last follow-up was not different between the groups. No significant differences were identified in the Constant score, DASH score, and ROM at the last follow-up. 2 patients were diagnosed with subacromial impingement, 1 in Group A one in Group B, and 1 patient in Group B experienced axillary nerve injury after surgery.

Conclusion

The novel anatomical plate fixed using the deltoid-splitting approach can achieve good results in the treatment of isolated humeral greater tubercle fractures with less blood loss, shorter operative time, and shorter surgical incisions, and can relieve pain in the early postoperative period.

Management of greater tuberosity fracture dislocations of the shoulder

Background

Despite extensive literature dedicated to determining the optimal treatment of isolated greater tuberosity (GT) fractures, there have been few studies to guide the management of GT fracture dislocations. The purpose of this review was to highlight the relevant literature pertaining to all aspects of GT fracture dislocation evaluation and treatment.

Methods

A narrative review of the literature was performed.

Results

During glenohumeral reduction, an iatrogenic humeral neck fracture may occur due to the presence of an occult neck fracture or forceful reduction attempts with inadequate muscle relaxation. Minimally displaced GT fragments after shoulder reduction can be successfully treated nonoperatively, but close follow-up is needed to monitor for secondary displacement of the fracture. Surgery is indicated for fractures with >5 mm displacement to minimize the risk of subacromial impingement and altered rotator cuff biomechanics. Multiple surgical techniques have been described and include both open and arthroscopic approaches. Strategies for repair include the use of transosseous sutures, suture anchors, tension bands, screws, and plates. Good-to-excellent radiographic and clinical outcomes can be achieved with appropriate treatment.

Conclusions

GT fracture dislocations of the proximal humerus represent a separate entity from their isolated fracture counterparts in their evaluation and treatment. The decision to employ a certain strategy should depend on fracture morphology and comminution, bone quality, and displacement.

Efficacy of Intramedullary Nailing in the Treatment of Comminuted Proximal Humeral Fractures and Its Influence on Shoulder Joint Function Recovery

In this paper, we have aimed to elucidate the therapeutic effect of intramedullary nailing (IMN) in treating comminuted proximal humeral fractures (CPHFs) and its influence on the recovery of shoulder joint function. For this purpose, 60 cases with CPHFs were selected, particularly from January 2020 to October 2021. In these cases, 28 cases were treated with a locking proximal humeral plate (LPHP) and assigned to the control (Con) group and the remaining 32 patients were treated with IMN and included in the research (Res) group. The therapeutic effect, surgical indicators, total complications, visual analogue scale (VAS) score, and postoperative shoulder joint function score were compared between the two arms. We observed that compared with the Con group, the effective rate in the Res group was higher while the operation time, intraoperative blood loss, and fracture healing time were shorter, the overall complication rate and VAS score were lower, and the postoperative shoulder joint function score was higher, all with statistical significance. The above results indicate that IMN is effective and safe in the treatment of CPHFs, which can validly reduce the discomfort of patients and facilitate the recovery of shoulder joint function.

A new biomechanical classification system for split fractures of the humeral greater tuberosity: guidelines for surgical treatment

Background

Split fractures of the humeral greater tuberosity (HGT) are common injuries. Although there are numerous surgical treatments for these fractures, no classification system combining clinical and biomechanical characteristics has been presented to guide the choice of fixation method.

Methods

We created a standardised fracture of the HGT in 24 formalin-fixed cadavers. Six were left as single-fragment fractures (Group A), six were further prepared to create single-fragment with medium size full-thickness rotator cuff tear (FT-RCT) fractures (Group B), six were cut to create multi-fragment fractures (Group C), and six were cut to create multi-fragment with FT-RCT fractures (Group D). Each specimen was fixed with a shortened proximal humeral internal locking system (PHILOS) plate. The fixed fractures were subjected to load and load-to-failure tests and the differences between groups analysed.

Results

The mean load-to-failure values were significantly different between groups (Group A, 446.83 ± 38.98 N; Group B, 384.17 ± 36.15 N; Group C, 317.17 ± 23.32 N and Group D, 266.83 ± 37.65 N, P < 0.05). The load-to-failure values for fractures with a greater tuberosity displacement of 10 mm were significantly different between each group (Group A, 194.00 ± 29.23 N; Group B, 157.00 ± 29.97 N; Group C, 109.00 ± 17.64 N and Group D, 79.67.83 ± 15.50 N; P < 0.05). These findings indicate that fractures with a displacement of 10 mm have different characteristics and should be considered separately from other HGT fractures when deciding surgical treatment.

Conclusions

Biomechanical classification of split fractures of the HGT is a reliable method of categorising these fractures in order to decide surgical treatment. Our findings and proposed system will be a useful to guide the choice of surgical technique for the treatment of fractures of the HGT.