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Background: The mini-open approach with supine patient positioning is a useful technique to consider for acute Achilles rupture repair, ideally performed within 2 weeks from the time of injury. The traditional surgical approach is completed with the patient in the prone position with an extensile midline incision. Here we describe a mini-open approach with supine positioning that utilizes a single incision measuring approximately 3 to 4 cm in length and avoids the pitfalls of prone positioning, which include greater operative time and potential difficult airway management, vision loss, and brachial plexus palsies1. Description: When positioning the patient supine, lower-extremity bolsters are placed beneath the contralateral hip and the operative ankle in order to allow for exaggerated external rotation of the ankle and improved medial visualization. A thigh tourniquet is then applied on the operative side in a standard sterile fashion.After appropriate draping, begin by palpating the tendon rupture site and mark a 3 to 4-cm incision line just medial to the tendon. Sharp dissection through the skin to the level of the paratenon is then performed. Incise the paratenon with a knife, separate the paratenon from the underlying Achilles tendon with a Freer elevator or scissors, subsequently remove any hematoma formation, and cut the paratenon proximally and distally with scissors or a knife. Debride any damaged tendon thoroughly.The steps of the procedure are performed under direct visualization. If the sural nerve is encountered, it is noted and retracted, and extra care is taken to avoid damaging it with instruments or suture.Now that the proximal and distal ends of the Achilles tendon are free, utilize a 4-stranded double Krackow locking stitch with two #2 FiberWires (Arthrex) on both the proximal and the distal stump. The stumps of the ruptured tendon are approximated by tying the free suture ends together with use of a simple surgeon's knot. A running epitendinous repair is performed with use of number-0 Vicryl (Ethicon) suture in a cross-stich weave technique to provide additional strength to the repair. Finally, test the integrity of the repair via an intraoperative Thompson test. The postoperative protocol includes non-weight-bearing with the operative limb in a posterior splint for 2 weeks. At the 2-week follow-up, stitches are removed and the limb is placed in a tall CAM (controlled ankle motion) walker boot with 2 heel wedges measuring 6.35 mm (0.25 inches) apiece. The patient can begin partial weight-bearing with crutches at 2 weeks postoperatively. At 4 weeks postoperatively, 1 heel wedge is removed, and at 6 weeks postoperatively, the second heel wedge is removed. Patients are instructed to begin gentle range-of-motion exercises at 2 weeks, with formal physical therapy scheduled to begin at 6 weeks. Most patients are out of the boot at 8 to 10 weeks postoperatively. Alternatives: Nonoperative treatment of Achilles rupture includes functional bracing or casting with the foot resting in the equinus position and early weight-bearing and rehabilitation. As mentioned earlier, the traditional operative approach with prone positioning is a viable option but is associated with a higher incidence of procedural and anesthesia-related complications, as well as potentially increased cost1. Rationale: Recent studies have shown that a mini-open approach will produce a repair that is comparable with the traditional open approach, while also minimizing the anesthesia and postural complications associated with prone positioning1. Previous studies focusing on supine positioning have generally utilized a larger incision more comparable with that of the traditional prone approach6. Other studies have utilized a minimally invasive approach but require >1 incision and often utilize specialized instrumentation, which may limit the technique to certain facilities7. The technique described in the present article utilizes a single 3 to 4-cm incision that requires no specialized instrumentation, has a minimal learning curve, and can be performed at any facility. Expected Outcomes: McKissack et al. demonstrated that the overall complication rate of the mini-open supine approach (7.7%) was lower than that of the traditional prone approach (9.3%), while the average cost of the prone approach exceeded that of the supine approach by $1,8231. This increased cost, although not significant, may be attributable to longer operating room and post-anesthesia care unit times. Additionally, no patient in either cohort experienced tendon rerupture within the first year after repair, further proving the effectiveness of this technique. We have utilized this mini-open supine technique for acute Achilles ruptures for over 9 years now, with good patient outcomes and satisfaction. Throughout this duration we have not had a single patient experience rerupture of the repaired tendon. In our experience, we find this technique to be effective, with fewer complications than prone positioning. Additionally, this approach may be associated with decreased financial and anesthesia burdens. Important Tips: Always palpate the tendon rupture site to determine the best incision placement.With ruptures close to the tendon insertion site, it can be notoriously difficult to mobilize the distal tendon stump, so extended incisions may be required.Test the integrity of the repair with use of the intraoperative Thompson test.This technique does not utilize any special equipment and thus can be performed at any facility.This supine approach decreases operating room turnover time, anesthesia burden, and complications associated with prone positioning. Acronyms & Abbreviations: AP = anteroposteriorMRI = magnetic resonance imagingUS = ultrasoundDVT = deep vein thrombosisVAS = visual analog scaleNWB = non-weight-bearingCAM = controlled ankle motionPWB = partial weightbearingROM = range of motionPT = physical therapyOR = operating room.
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Objectives: To evaluate the available literature for postoperative fracture rates following implant removal in the pediatric population. Methods: A systematic review of articles in the PubMed and Embase computerized literature databases from January 2000 to June 2022 was performed using PRISMA guidelines. Randomized controlled trials, case-control studies, cohort studies (retrospective and prospective), and case series involving pediatric patients that included data on fracture rate following removal of orthopedic implants were eligible for review. Two authors independently extracted data from selected studies for predefined data fields for implant type, anatomic location of the implant, indication for implantation, fracture or refracture rate following implant removal, mean time to implant removal, and mean follow-up time. Results: Fifteen studies were included for qualitative synthesis. Reported fracture rates following implant removal vary based on several factors, with an overall reported incidence of 0%-14.9%. The available literature did not offer sufficient data for conduction of a meta-analysis. Conclusion: Our systematic review demonstrates that fracture following implant removal in pediatric patients is a relatively frequent complication. In children, the forearm and femur are the most commonly reported sites of fracture following removal of implants. Traumatic fractures treated definitively with external fixation have the highest reported aggregate rate of refracture. Knowledge of the incidence of this risk is important for orthopedic surgeons. There remains a need for well-designed studies and trials to further clarify the roles of the variables that contribute to this complication.
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Coronary artery bypass grafting (CABG) is the standard treatment modality in revascularization of the myocardium. However, the graft failure remains the major complication following CABG procedure. Involvement of mitochondrial damage-associated molecular patterns (mt-DAMPs) in the pathogenesis of vein-graft failure is largely unknown. Here, we investigated the expression of major protein-mt-DAMPs, cytochrome-C (Cyt-C), heat shock protein-60 (Hsp-60), mitochondrial transcription factor A (mtTFA), in the occluded graft and associated tissues, including distal left anterior descending (LAD), LAD adjacent to anastomosis, and left internal mammary artery (LIMA) in the microswine CABG model. The protein expression of peroxisome proliferator-activated receptor gamma coactivator 1-alpha (PGC-1α) was significantly decreased in the graft and LIMA, whereas the protein expression of hypoxia inducible factor-1 alpha (HIF-1α) and Cyt-C was decreased and that of mtTFA and Hsp60 was increased in all tissues compared to controls. There was no significant difference in the protein expression of citrate synthase, complex-1, and mitochondrial pyruvate dehydrogenase in the graft and associated tissues compared to control. Hypoxia in cultured smooth muscle cells (SMCs) significantly upregulated all mitochondrial biomarkers and mt-DAMPs compared to normoxia. The increased reactive oxygen species (ROS) content and compromised membrane integrity in the hypoxic SMCs correlated well with increased mt-DAMPs in the graft and associated tissues, suggesting a possible role of mt-DAMPs in the pathogenesis of graft failure. These findings suggest that the pathological signals elicited by mt-DAMPs could reveal targets for better therapeutic approaches and diagnostic strategies in the management of CABG graft failure.