Legg‐Calvé‐Perthes disease (LCPD) is a juvenile form of ischemic femoral head osteonecrosis, which produces chronic hip synovitis, permanent femoral head deformity, and premature osteoarthritis. Currently, there is no medical therapy for LCPD. Interleukin‐6 (IL‐6) is significantly elevated in the synovial fluid of patients with LCPD. We hypothesize that IL‐6 elevation promotes chronic hip synovitis and impairs bone healing after ischemic osteonecrosis. We set out to test if anti‐IL‐6 therapy using tocilizumab can decrease hip synovitis and improve bone healing in the piglet model of LCPD. Fourteen piglets were surgically induced with ischemic osteonecrosis and assigned to two groups: the no treatment group (n = 7) and the tocilizumab group (15 to 20 mg/kg, biweekly intravenous injection, n = 7). All animals were euthanized 8 weeks after the induction of osteonecrosis. Hip synovium and femoral heads were assessed for hip synovitis and bone healing using histology, micro‐CT, and histomorphometry. The mean hip synovitis score and the number of synovial macrophages and vessels were significantly lower in the tocilizumab group compared with the no treatment group (p < .0001, p = .01, and p < .01, respectively). Micro‐CT analysis of the femoral heads showed a significantly higher bone volume in the tocilizumab group compared with the no treatment group (p = .02). The histologic assessment revealed a significantly lower number of osteoclasts per bone surface (p < .001) in the tocilizumab group compared with the no treatment group. Moreover, fluorochrome labeling showed a significantly higher percent of mineralizing bone surface (p < .01), bone formation rate per bone surface (p < .01), and mineral apposition rate (p = .04) in the tocilizumab group. Taken together, tocilizumab therapy decreased hip synovitis and osteoclastic bone resorption and increased new bone formation after ischemic osteonecrosis. This study provides preclinical evidence that tocilizumab decreases synovitis and improves bone healing in a large animal model of LCPD. © 2020 American Society for Bone and Mineral Research (ASBMR).
Background: Ischemic osteonecrosis of the femoral head produces necrotic cell debris and inflammatory molecules in the marrow space, which elicit a chronic inflammatory repair response. The purpose of this study was to determine the effects of flushing out the necrotic cell debris and inflammatory proteins on bone repair in a piglet model of ischemic osteonecrosis.Methods: Osteonecrosis of the femoral head of the right hindlimb was induced in 12 piglets by tying a ligature tightly around the femoral neck. One week after the surgery, 6 animals were treated with a percutaneous 3-needle bone washing procedure and non-weight-bearing (NWB) of the right hindlimb (wash group). The total saline solution wash volume was 450 mL per femoral head. Serial wash solutions were collected and analyzed. The remaining 6 animals were treated with NWB only (NWB group). At 8 weeks after the surgery, the femoral heads were assessed using radiography, microcomputed tomography (micro-CT), and histological analysis. In addition, we compared the results for these piglets with our published results for 6 piglets treated with multiple epiphyseal drilling (MED) plus NWB without bone washing (MED group).Results: Necrotic cells and inflammatory proteins were present in the bone wash solution collected 1 week after ischemia induction. The protein and triglyceride concentrations decreased significantly with subsequent washing (p < 0.005). At 8 weeks after ischemia induction, the wash group had a significantly higher bone volume than the MED or NWB group (p < 0.0001). Histological bone-formation measures were also significantly increased in the wash group compared with the MED group (p = 0.002) or NWB group (p < 0.0001) while macrophage numbers were significantly decreased in the wash group. Conclusions:The percutaneous 3-needle procedure flushed out cell debris and inflammatory proteins from the necrotic femoral heads, decreased osteoclasts and macrophages, and increased bone formation following induction of ischemic osteonecrosis.Clinical Relevance: We believe that this is the first study to investigate the concept of washing out the necrotic femoral head to improve bone healing. The minimally invasive procedure may be useful to improve the necrotic bone environment and bone repair following ischemic osteonecrosis. Juvenile ischemic osteonecrosis of the femoral head results from a disruption of blood flow to the growing femoral head that produces extensive ischemic cell death in the bone marrow and the trabecular bone. The dying cells are known to release endogenous inflammatory factors called damage-associated molecular patterns (DAMPs), which alert the immune cells of tissue damage. The DAMPs trigger the recruitment of innate immune cells and the production of pro-inflammatory cytokines and chemokines 1,2 . High mobility group box-1 (HMGB1) protein is a prototypical DAMP that normally functions as a chromatin-Disclosure: The authors indicated that no external funding was received for any aspect of this work. On the Disclosure of Potential Conf...
Objective Venous Clinical Severity Score (VCSS) is a widely used standard for assessing and grading the severity of chronic venous disease (CVD). Prior research highlighted its high validity in detecting and quantifying venous disease. However, there is little, if any, known about the precise thresholds at which VCSS discriminates important stages of deep venous disease. This study sought to elucidate the diagnostic accuracy, thresholds, and correlation at which VCSS detects salient CEAP (Clinical-Etiology-Anatomy-Pathophysiology) classes in deep venous disease progression. Methods A registry of 840 patients who presented with chronic proximal venous outflow obstruction (PVOO) secondary to non-thrombotic iliac vein lesions from August 2011 to June 2021 was retrospectively analyzed. VCSS and CEAP classifications were used to evaluate preoperative symptoms. VCSS was compared to CEAP classes to determine the precise VCSS composite values at which the instrument was able to detect CEAP C3 and higher, C4 and higher, and C5 and higher. Receiver operative characteristic (ROC) curve and area under the curve (AUC) were used to evaluate VCSS for its ability to discriminate disease at these stages of CEAP classification. Spearman’s rank coefficient was used to determine the correlation between CEAP VCSS composite as well as individual VCSS components (pain, varicose vein, edema, pigmentation, inflammation, induration, ulcer number, ulcer size, ulcer duration, compression). Results VCSS composite was able to detect venous edema (C3) and higher at a sensitivity of 68.9% and a specificity of 54.8% at an optimized threshold of 8.5 (AUC = 0.648; 95% C.I. = 0.575–0.721). To detect changes in skin and subcutaneous tissue from CVD (C4) and higher, an optimal threshold of 11.5 was found with a sensitivity of 51.7% and specificity of 76.5% (AUC = 0.694; 95% C.I. = 0.656–0.731). Healed venous ulcer (C4) and higher was detectable at an optimized threshold of 13.5 at a sensitivity of 67.7% and a specificity of 88.9% (AUC = 0.819; 95% C.I. = 0.766–0.873). The correlation between VCSS composites and CEAP was weak ( ρ = 0.372; p < .001). Attributes of VCSS that reflect more severe venous disease correlated more closely with CEAP classes, namely pigmentation ( ρ = 0.444; p < .001), inflammation ( ρ = 0.348; p < .001), induration ( ρ = 0.352; p < .001), number of active ulcers ( ρ = 0.497; p < .001), active ulcer size ( ρ = 0.485; p < .001), and ulcer duration ( ρ = 0.497; p < .001). The correlation between CEAP class and the other four components of VCSS were not statistically significant. Conclusion VCSS composite thresholds of 8.5, 11.5, and 13.5 are threshold values for detecting CEAP classification C3 and higher, C4 and higher, and C5 and higher, respectively. Consistent with prior work, VCSS appears to have a better ability to discriminate CVD at more severe CEAP classifications. In this registry, the correlation between VCSS and CEAP was found to be weak while components of VCSS that suggest more advanced disease exhibited the strongest correlation with CEAP.
Introduction: Children with Down syndrome (DS) are 10-20 times more likely than children without DS to develop acute lymphoblastic leukemia (ALL), and they demonstrate a distinctive spectrum of genetic alterations. Approximately 50% of DS-ALL cases demonstrate CRLF2 rearrangements (CRLF2-R), an approximately 10-fold higher frequency than in non-DS ALL. We sought to identify the functional basis for the increased incidence of ALL, and specifically CRLF2-R ALL, in children with DS. Methods: We created retroviral vectors which induce overexpression of CRLF2 and green fluorescent protein (GFP) for transduction into bone marrow (BM) cells isolated from the Dp16(1)Yey (Dp16) mouse model of DS, which is trisomic for the approximately 115 human chromosome 21 gene orthologs present on mouse chromosome 16. Transduced BM cells from Dp16 and wild-type (WT) control mice were co-cultured with OP9 stromal cells for one week to promote B-lymphoid lineage development, and then characterized by flow cytometric Hardy fraction analysis, or grown in B-lymphoid-promoting methylcellulose medium for colony growth assays. Results: We achieved efficient transduction (80-95%) of Dp16 and WT BM enriched for hematopoietic stem cells (HSCs) with CRLF2-GFP+ and control GFP+ viruses. Following OP9 co-culture, transduced HSCs were characterized by Hardy fraction analysis. CRLF2-GFP+ Dp16 lymphoid cells demonstrated significantly higher percentages of immature Fraction A (pre-pro-B) cells compared with GFP+ Dp16 cells (39.9% vs 15.7%, p=0.004, Fig. 1A). This CRLF2-GFP-induced immature immunophenotype was more pronounced in Dp16 versus WT HSCs, with a significantly higher percentage of Fraction A cells (39.9% in Dp16 vs 24.0% in WT, p=0.0002) and a significantly lower percentage of more mature Fraction B (pro-B) cells (24.3% in Dp16 vs 49.1% in WT, p=0.02, Fig. 1A,B). In methylcellulose colony assays, CRLF2-GFP+ Dp16 cells yielded a 36-fold increase in B cell colonies compared to GFP+ Dp16 cells (Fig 1C). Again, the effect of CRLF2 transduction was magnified in the Dp16 versus WT background. CRLF2-GFP+ WT cells demonstrated only a 2.9-fold increase in B cell colonies (Fig 1C). Conclusions: Here we demonstrate that CRLF2 overexpression results in a more immature B-lineage immunophenotype and increased lymphoid colony growth in vitro, and that these effects are significantly greater in a murine DS versus WT genetic background. Experiments to investigate the pathways involved and to evaluate these effects in vivo are ongoing. This work provides functional evidence of the enhanced leukemogenicity of CRLF2 overexpression in DS-ALL, and creates a tractable model system for additional future genetic studies. Disclosures No relevant conflicts of interest to declare.
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