Permanent reduction plate and intramedullary nailing of open tibia fractures: Do we need to take them out?

INTRODUCTION: Provisional reduction plating has been advocated as a reduction aid for tibial shaft fractures. Concerns regarding soft tissue stripping, infection, wound complications and nonunion have been postulated. Recent studies investigating reduction plating present patient cohorts where plates are removed or left to the discretion of the surgeon. This study aims to identify a cohort of open tibial shaft fractures treated with intramedullary nailing aided by permanent reduction plating. Our hypothesis is that permanent reduction plating in conjunction with intramedullary nailing of open tibia fractures does not increase risk of nonunion, infection or time to fracture union compared to intramedullary nailing alone. METHODS: An IRB approved retrospective study was performed using trauma registry data from January 2014 to June 2018 at a Level 1 trauma center. Open AO/OTA 41A/42 A-C/43A tibial shaft fractures treated with intramedullary nail alone (IM) or intramedullary nail and permanent reduction plates (PP) were included in patients over 18 years of age with at least six month follow up or until fracture union. Patient demographics, fracture characteristics, mechanism of injury, medical comorbidities, and length of follow up were recorded along with time to union, incidence of nonunion and treatment for documented or suspected infections. RESULTS: During the study period, 389 patients underwent tibial intramedullary nailing with 162 identified as open fractures. 91 patients met inclusion criteria with 39 in the PP group and 52 in IM group. Statistical analysis revealed no difference between the two groups except more AO/OTA 42A fractures were noted in the IM group. Average follow up was 8.0 and 10.2 months for PP and IM respectively. Nonunion occurred in 2 PP group patients and 7 in the IM group (p = 0.29). Time to union was 5.5 months for PP group and 6.1 months for IM group (p = 0.39) with 4 infections in the PP group and 10 infections in IM group (p = 0.38). CONCLUSION: Despite the small sample size, this study suggests that permanent reduction plating, in the setting of open tibia fractures, does not delay time to fracture union or increase risk of nonunion or infection.

Splint Padding Thickness: Temperature Effects and X-ray Visualization.

OBJECTIVES: The purpose of this study was to determine if the thickness of splint padding could be determined on X-rays, and whether increasing layers of splint padding have an effect on temperature at the skin after placement. METHODS: Both in vitro and in vivo testing was performed. Ten cadaveric lower extremities were used. A thermocouple was placed on the posterior calf for temperature determination. Cadavers were used with short leg posterior splints with sidebars placed using various thicknesses of padding: (1) 2 layers of Webril, (2) 4 layers of Webril, (3) 2 × 2 padding (Webril followed by kerlix, then repeated), and (4) bulky cotton padding. A splint with no padding was used as a control. Lateral X-rays of the ankle were obtained. The padding thickness was measured. The change in temperature at the level of the skin was measured throughout the process. The test was then repeated in vivo to correlate the cadaver findings with a live subject. RESULTS: The mean thickness of the 5 padding types could be reliably determined on X-ray. Our cadaver temperature data shows that all padding thickness tested decreased temperature change after plaster curing, with no significant difference between wraps. Live subject testing showed similarities between the 2-layer Webril and 2 × 2 padding, and between the 4-layer Webril and bulky padding. CONCLUSIONS: Padding thickness can be consistently determined on X-ray. We determined that at least 2 layers of Webril significantly decrease temperature change at the level of the skin caused by plaster curing. Two layers of Webril can be identified on X-ray by measuring at least 1 mm of padding.

Masquelet's induced membrane technique: Review of current concepts and future directions.

Masquelet's induced membrane technique (MIMT) is a relatively new, two-stage surgical procedure to reconstruct segmental bone defects. First performed by Dr. Masquelet in the mid-1980s, MIMT has shown great promise to revolutionize critical-sized bone defect repair and has several advantages over its alternative, distraction osteogenesis (DO). Also, its success in extremely challenging cases (defects > 15 cm) suggests that its study could lead to discovery of novel biological mechanisms that might be at play during segmental defect healing and fracture non-union. MIMT's advantages over DO have led to a world-wide increase in MIMT procedures over the past decades. However, MIMT often needs to be repeated and so the average initial success rate in adults lags significantly behind that of DO (86% vs 95%, respectively). The autologous foreign-body membrane created during the first stage by the immune system's response to a polymethyl methacrylate bone cement spacer is critical to supporting the morselized bone graft implanted in the second stage. However, the biological and/or physical mechanisms by which the membrane supports graft to bone union are unclear. This lack of knowledge makes refining MIMT and improving the success rates through technique improvements and patient selection a significant challenge and hinders wider adoption. In this review, current knowledge from basic, translational, and clinical studies is summarized. The dynamics of both stages under normal conditions as well as with drug or material perturbations is discussed along with perspectives on high-priority future research directions.

Bone density of first and second segments of normal and dysmorphic sacra.

BACKGROUND: Iliosacral screw fixation is safe and effective but can be complicated by loss of fixation, particularly in patients with osteopenic bone. Sacral morphology dictates where iliosacral screws may be placed when stabilizing pelvic ring injuries. In dysmorphic sacra, the safe osseous corridor of the upper sacral segment (S1) is smaller and lacks a transsacral corridor, increasing the need for fixation in the second sacral segment (S2). Previous evidence suggests that S2 is less dense than S1. The aim of this cross-sectional study is to further evaluate bone mineral density (BMD) of the S1 and S2 iliosacral osseous pathways through morphology stratification into normal and dysmorphic sacra. MATERIALS AND METHODS: Pelvic computed tomography scans of 50 consecutive trauma patients, aged 18 to 50 years, from a level 1 trauma center were analyzed prospectively. Five radiographic features (upper sacral segment not recessed in the pelvis, mammillary bodies, acute alar slope, residual S1 disk, and misshapen sacral foramen) were used to identify dysmorphic characteristics, and sacra with four or five features were classified as dysmorphic. Hounsfield unit values were used to estimate the regional BMD of S1 and S2. Student's t-test was utilized to compare the mean values at each segment, with statistical significance being set at p < 0.05. No change in clinical management occurred as a result of inclusion in this study. RESULTS: A statistical difference in BMD was appreciated between S1 and S2 in both normal and dysmorphic sacra (p < 0.0001), with 28.4% lower density in S2 than S1. Further, S1 in dysmorphic sacra tended to be 4% less dense than S1 in normal sacra (p = 0.047). No difference in density was appreciated at S2 based on morphology. CONCLUSIONS: Our results would indicate that, based on BMD alone, fixation should be maximized in S1 prior to fixation in S2. In cases where S2 fixation is required, we recommend that transsacral fixation should be strongly considered if possible to bypass the S2 body and achieve fixation in the cortical bone of the ilium and sacrum. LEVEL OF EVIDENCE: Level III.

Bilateral Isolated Fractures of the Sustentaculum Tali: A Case Report.

CASE: This article presents a case of bilateral isolated fractures of the sustentaculum tali. Subtle radiographic findings of sustentaculum fractures on routine foot and ankle series are often difficult to detect, which can result in a delayed diagnosis. Early diagnosis and timely operative management allowed for a good short-term outcome. CONCLUSIONS: We emphasize the importance of a thorough physical examination in all high-energy trauma patients and an awareness of less common injury patterns that are subtle on radiographs and may require further workup. When clinical suspicion exists, we recommend the use of computed tomography scans for evaluation.

Masquelet Technique: Effects of Spacer Material and Micro-topography on Factor Expression and Bone Regeneration.

We and others have shown that changing surface characteristics of the spacer implanted during the first Masquelet stage alters some aspects of membrane development. Previously we demonstrated that titanium (TI) spacers create membranes that are better barriers to movement of solutes > 70 kDa in size than polymethyl methacrylate (PMMA) induced-membranes, and roughening creates more mechanically compliant membranes. However, it is unclear if these alterations affect the membrane's biochemical environment or bone regeneration during the second stage. Ten-week-old, male Sprague-Dawley rats underwent an initial surgery to create an externally stabilized 6 mm femoral defect. PMMA or TI spacers with smooth (~ 1 µm) or roughened (~ 8 µm) surfaces were implanted. Four weeks later, rats were either euthanized for membrane harvest or underwent the second Masquelet surgery. TI spacers induced thicker membranes that were similar in structure and biochemical expression. All membranes were bilayered with the inner layer having increased factor expression [bone morphogenetic protein 2 (BMP2), transforming growth factor beta (TGFß), interleukin 6 (IL6), and vascular endothelial growth factor (VEGF)]. Roughening increased overall IL6 levels. Ten-weeks post-engraftment, PMMA-smooth induced membranes better supported bone regeneration (60% union). The other groups only had 1 or 2 that united (9-22%). There were no significant differences in any micro computed tomography or dynamic histology outcome. In conclusion, this study suggests that the membrane's important function in the Masquelet technique is not simply as a barrier. There is likely a critical biochemical, cellular, or vascular component as well.

Masquelet technique: The effect of altering implant material and topography on membrane matrix composition, mechanical and barrier properties in a rat defect model.

The Masquelet technique is a surgical procedure to regenerate segmental bone defects. The two-phase treatment relies on the production of a vascularized foreign-body membrane to support bone grafts over three times larger than the traditional maximum. Historically, the procedure has always utilized a bone cement spacer to evoke membrane production. However, membrane formation can easily be effected by implant surface properties such as material and topology. This study sought to determine if the membrane's mechanical or barrier properties are affected by changing the spacer material to titanium or roughening the surface finish. Ten-week-old, male Sprague Dawley rats were given an externally stabilized, 6 mm femur defect which was filled with a pre-made spacer of bone cement (PMMA) or titanium (TI) with a smooth (∼1 µm) or roughened (∼8 µm) finish. After 4 weeks of implantation, the membranes were harvested, and the matrix composition, tensile mechanics, shrinkage, and barrier function was assessed. Roughening the spacers resulted in significantly more compliant membranes. TI spacers created membranes that inhibited solute transport more. There were no differences between groups in collagen or elastin distribution. This suggests that different membrane characteristics can be created by altering the spacer surface properties. Surgeons may unknowingly effecting membrane formation via bone cement preparation techniques.

Altering spacer material affects bone regeneration in the Masquelet technique in a rat femoral defect.

The Masquelet technique depends on pre-development of a foreign-body membrane to support bone regeneration with grafts over three times larger than the traditional maximum. To date, the procedure has always used spacers made of bone cement, which is the polymer polymethyl methacrylate (PMMA), to induce the foreign-body membrane. This study sought to compare (i) morphology, factor expression, and cellularity in membranes formed by PMMA, titanium, and polyvinyl alcohol sponge (PVA) spacers in the Masquelet milieu and (ii) subsequent bone regeneration in the same groups. Ten-week-old, male Sprague-Dawley rats were given an externally stabilized, 6 mm femur defect, and a pre-made spacer of PMMA, titanium, or PVA was implanted. All animals were given 4 weeks to form a membrane, and those receiving an isograft were given 10 weeks post-implantation to union. All samples were scanned with microCT to measure phase 1 and phase 2 bone formation. Membrane samples were processed for histology to measure membrane morphology, cellularity, and expression of the factors BMP2, TGFß, VEGF, and IL6. PMMA and titanium spacers created almost identical membranes and phase 1 bone. PVA spacers were uniformly infiltrated with tissue and cells and did not form a distinct membrane. There were no quantitative differences in phase 2 bone formation. However, PMMA induced membranes supported functional union in 6 of 7 samples while a majority of titanium and PVA groups failed to achieve the same. Spacer material can alter the membrane enough to disrupt phase 2 bone formation. The membrane's role in bone regeneration is likely more than just as a physical barrier. © 2018 Orthopaedic Research Society. Published by Wiley Periodicals, Inc. J Orthop Res.

Nailing proximal femur fractures: how to choose starting point and proximal screw configuration.

Fractures of the proximal femur can be a challenging treatment dilemma for the orthopaedic surgeon. Complex mechanical forces and anatomic variables in this region combine to make treatment of these injuries difficult and can often result in serious complications. The decision to treat this fracture with an intramedullary device requires the surgeon evaluate many variables in the context of the specific fracture pattern. These include the choice of implant, starting portal location, and positioning of the patient. Assessment of the fracture pattern and its 3 dimensional orientation is usually accomplished with the aid of advanced imaging. The patient's physiological status, body habitus and bone quality must also be incorporated into the treatment algorithm. We review these issues and how they factor into the decision making process in order to develop a successful operative plan for these injuries. We will review the starting portal selection, reduction and insertion techniques and examine options for proximal locking screw configurations.

Orthobiologics in the augmentation of osteoporotic fractures.

Many orthobiologic adjuvants are available and widely utilized for general skeletal restoration. Their use for the specific task of osteoporotic fracture augmentation is less well recognized. Common conductive materials are reviewed for their value in this patient population including the large group of allograft adjuvants categorically known as the demineralized bone matrices (DBMs). Another large group of alloplastic materials is also examined-the calcium phosphate and sulfate ceramics. Both of these materials, when used for the proper indications, demonstrate efficacy for these patients. The inductive properties of bone morphogenic proteins (BMPs) and platelet concentrates show no clear advantages for this group of patients. Systemic agents including bisphosphonates, receptor activator of nuclear factor κß ligand (RANKL) inhibitors, and parathyroid hormone augmentation all demonstrate positive effects with this fracture cohort. Newer modalities, such as trace ion bioceramic augmentation, are also reviewed for their positive effects on osteoporotic fracture healing.

Novel venting technique for intramedullary rod fixation of pathologic fractures.

This article introduces a novel technique to vent the femur and potentially decrease the embolic load created by reaming during intramedullary rod fixation of impending pathologic femur fractures. We used readily available operating room equipment to create a distal femoral vent hole without interfering with standard intramedullary instrumentation and with minimal increase in surgical time. This technique can be used for the prophylactic intramedullary stabilization of impending pathologic femur fractures from metabolic bone disease, metastatic cancer, and bisphosphonate use.