Calcaneocuboid distraction arthrodesis for children with symptomatic pes planovalgus: does fixation improve outcomes?

Lateral column lengthening is a common surgical procedure for addressing symptomatic pes planovalgus foot deformity. For more severe cases, the use of a calcaneocuboid distraction arthrodesis (CCDA) can allow for more powerful correction. Previous reports have cited an increased risk of graft collapse with loss of correction when this procedure is performed without supplemental hardware fixation. The purpose of this study was to assess the outcomes of CCDA in children with and without supplemental locking fixation. A retrospective review from 2008 to 2016 of CCDA procedures with and without supplemental fixation was performed. The primary endpoint was graft collapse. Secondary objectives included evaluation of radiographic loss of correction, hardware failure, pain at 1-year follow-up, reoperations, and changes in the foot loading pattern foot per pedobarography. Twenty-nine feet in 24 patients were eligible for review. Supplemental locked fixation was used in 18 feet [hardware (HW)], with the remaining 11 feet managed without fixation [no hardware (NoHW)]. The overall failure rate on the basis of graft collapse and loss of correction was 55% (56% for the HW group, 55% for the NoHW group). Eleven patients (61%) in the HW group experienced hardware failure, with six (33%) of these requiring hardware removal. Fifty-six percent of the HW group and 45% of the NoHW group reported continued pain at 1-year follow-up. One patient from each group underwent revision arthrodesis. Supplemental locked fixation did not provide additional benefit in preventing graft collapse and loss of correction in this cohort. Alternative strategies should be considered to improve the outcomes for this procedure.

Embryonic-only arsenic exposure alters skeletal muscle satellite cell function in killifish (Fundulus heteroclitus).

Arsenic is a contaminant found worldwide in drinking water and food. Epidemiological studies have correlated arsenic exposure with reduced weight gain and improper muscular development, while in vitro studies show that arsenic exposure impairs myogenic differentiation. The purpose of this study was to use Fundulus heteroclitus or killifish as a model organism to determine if embryonic-only arsenic exposure permanently reduces the number or function of muscle satellite cells. Killifish embryos were exposed to 0, 50, 200, or 800 ppb arsenite (AsIII) until hatching, and then juvenile fish were raised in clean water. At 28, 40, and 52 weeks after hatching, skeletal muscle injuries were induced by injecting cardiotoxin into the trunk of the fish just posterior to the dorsal fin. Muscle sections were collected at 0, 3 and 10 days post-injury. Collagen levels were used to assess muscle tissue damage and recovery, while levels of proliferating cell nuclear antigen (PCNA) and myogenin were quantified to compare proliferating cells and newly formed myoblasts. At 28 weeks of age, baseline collagen levels were 105% and 112% greater in 200 and 800 ppb groups, respectively, and at 52 weeks of age, were 58% higher than controls in the 200 ppb fish. After cardiotoxin injury, collagen levels tend to increase to a greater extent and take longer to resolve in the arsenic exposed fish. The number of baseline PCNA(+) cells were 48-216% greater in 800 ppb exposed fish compared to controls, depending on the week examined. However, following cardiotoxin injury, PCNA is reduced at 28 weeks in 200 and 800 ppb fish at day 3 during the recovery period. By 52 weeks, there are significant reductions in PCNA in all exposure groups at day 3 of the recovery period. Based on these results, embryonic arsenic exposure increases baseline collagen levels and PCNA(+) cells in skeletal muscle. However, when these fish are challenged with a muscle injury, the proliferation and differentiation of satellite cells into myogenic precursors is impaired and instead, the fish appear to be favoring a fibrotic resolution to the injury.