Many current measures of eating disorder (ED) symptoms have 1 or more serious limitations, such as inconsistent factor structures or poor discriminant validity. The goal of this study was to overcome these limitations through the development of a comprehensive multidimensional measure of eating pathology. An initial pool of 160 items was developed to assess 20 dimensions of eating pathology. The initial item pool was administered to a student sample (N = 433) and community sample (N = 407) to determine the preliminary structure of the measure using exploratory and confirmatory factor analyses. The revised measure was administered to independent samples of patients recruited from specialty ED treatment centers (N = 158), outpatient psychiatric clinics (N = 303), and students (N = 227). Analyses revealed an 8-factor structure characterized by Body Dissatisfaction, Binge Eating, Cognitive Restraint, Excessive Exercise, Restricting, Purging, Muscle Building, and Negative Attitudes Toward Obesity. Scale scores showed excellent convergent and discriminant validity; other analyses demonstrated that the majority of scales were invariant across sex and weight categories. Eating Pathology Symptoms Inventory scale scores had excellent internal consistency (median coefficient alphas ranged from .84-.89) and reliability over a 2- to 4-week period (mean retest r = .73). The current study represents one of the most comprehensive scale development projects ever conducted in the field of EDs and will enhance future basic and treatment research focused on EDs.
Objective Von Willebrand factor (VWF), which is synthesized in endothelial cells and megakaryocytes, is known to worsen stroke outcome. In vitro studies suggest that platelet-derived VWF is biochemically different from the endothelial cell-derived VWF. However, little is known about relative contribution of different pools of VWF in stroke. Approach and Results Using bone marrow transplantation, we generated chimeric platelet derived-VWF mice (Plt-VWF), platelet derived-VWF mice that lack ADAMTS13 in platelets and plasma (Plt-VWF/Adamts13−/−), and endothelial cell derived-VWF mice (EC-VWF) to determine relative contribution of different pools of VWF in stroke. In brain ischemia/reperfusion injury model, we found that infarct size, post-ischemic intracerebral thrombo-inflammation (fibrin(ogen) deposition, neutrophil infiltration, IL-1β and TNF-α levels) within lesions were comparable between EC-VWF and WT mice. Infarct size and post-ischemic thrombo-inflammation were comparable between Plt-VWF and Plt-VWF/Adamts13−/− mice, but decreased compared to EC-VWF and/or WT mice (P<0.05) and increased compared to Vwf −/− mice (P<0.05). Susceptibility to FeCl3 injury-induced carotid artery thrombosis was comparable between WT and EC-VWF mice, whereas Plt-VWF and Plt-VWF/Adamts13−/− mice exhibited defective thrombosis. Although most of the injured vessels did not occlude, slope over time showed that thrombus growth rate was increased in both Plt-VWF and Plt-VWF/Adamts13−/− mice compared to Vwf −/− mice (P<0.05), but decreased compared to WT or EC-VWF mice. Conclusions Platelet-derived VWF, either in presence or absence of ADAMTS13, partially contributes to VWF-dependent injury and post-ischemic thrombo-inflammation following stroke. Endothelial cell-derived VWF is the major determinant that mediates VWF-dependent ischemic stroke by promoting post-ischemic thrombo-inflammation.
Hemophilia A, caused by a deficiency in factor VIII (FVIII), is the most severe inherited bleeding disorder. Hemophilia A is an attractive gene therapy candidate because even small increases in FVIII levels will positively alter the phenotype. While several vectors are under investigation, gene addition from an integrated transgene offers the possibility of long term expression. We engineered the DNA transposon-based vector, piggyBac (PB), to carry a codon-optimized B-domain deleted human FVIII cDNA. Evaluation of gene transfer efficiency in FVIII null mice demonstrated that PB containing the FVIII cDNA, delivered via hydrodynamic injection to immunocompetent hemophilia mice, conferred persistent gene expression, attaining mean FVIII activity of approximately 60% with 3/19 developing inhibitors. In addition to efficacious expression, a goal of gene transfer-based therapies is to develop vectors with low toxicity. To assess endoplasmic reticulum stress in hepatocytes stably expressing the transgene, we evaluated levels of ER stress markers via qPCR and found no evidence of cell stress. To evaluate phenotypic correction, a tail clip assay performed at the end of the study revealed reduced blood loss. These data demonstrate that PB can be used to achieve sustained FVIII expression and long-term therapeutic benefit in a mouse model.
BackgroundHemophilia A animal models have helped advance our understanding of factor VIII deficiency. Previously, factor VIII deficient mouse models were reported to have a normal life span without spontaneous bleeds. However, the bleeding frequency and survival in these animals has not been thoroughly evaluated.ObjectiveTo investigate the survival and lethal bleeding frequency in two strains of E-16 hemophilia A mice.MethodsWe prospectively studied factor VIII deficient hemizygous affected males (n = 83) and homozygous affected females (n = 55) for survival and bleeding frequency. Animals were evaluated for presence and location of bleeds as potential cause of death.Results and ConclusionsHemophilia A mice had a median survival of 254 days, which is significantly shortened compared to wild type controls (p < 0.0001). In addition, the hemophilia A mice experienced hemorrhage in several tissues. This previously-underappreciated shortened survival in the hemophilia A murine model provides new outcomes for investigation of therapeutics and also reflects the shortened lifespan of patients if left untreated.
Hemophilia A, caused by a deficiency in factor VIII (FVIII), is the most severe inherited bleeding disorder, affecting about 1 out of 5,000 males; those affected suffer disabling joint and muscle hemorrhages. Hemophilia A is an attractive gene therapy candidate, because even small increases in FVIII levels (5-10%) will alter the phenotype. Non-viral vector systems are used increasingly in gene targeting technologies and as tools for gene transfer applications. Nonviral DNA transposons are genetic elements consisting of inverted terminal DNA repeats which in their naturally occurring configuration flank a transposase coding sequence. The transposase follows a “cut and paste” mechanism to excise the transposon from its original genomic location and insert it into a new locus. The insect derived piggyBac (PB) can be engineered to carry a therapeutic transgene between the inverted terminal repeats. Advantages of this novel nonviral vector system include a large transgene cassette capacity, ease of production and purification, and potential for site-specific integration. We hypothesize that a PB transposon vector carrying a codon-optimized human FVIII cDNA along with a hyperactive transposase (iPB7) will confer persistent gene expression and correction of the hemophilia A bleeding phenotype. We engineered PB transposon to carry a codon-optimized human FVIII B-domain deleted cDNA (coFVIII-BDD). We evaluated the in vivo gene transfer efficiency in hemophilia A mice by hydrodynamic tail-vein injection using PB coFVIII-BDD driven by the murine albumin enhancer/human alpha anti-trypsin promoter. Factor VIII null mice received 25 micrograms each of the PB coFVIII-BDD transposon and iPB7 to determine long term expression and phenotypic correction. FVIII activity and antigen levels were measured prior to injection and then every 4 weeks for 24 weeks. Results revealed therapeutic levels (50-225%) of factor VIII activity and antigen post gene transfer with stable expression for 24 weeks in most mice. A goal of gene transfer based therapies is to develop the most efficacious expression vectors with the least toxicity. To assess endoplasmic reticulum stress in the livers of treated and untreated mice, we evaluated BiP, CHOP, and EDEM levels via q-PCR. All experimental mice, null mice, and transposon treated mice without the coFVIII-BDD cassette revealed no evidence of cell stress. These data indicate codon-optimized FVIII and the piggyBac transposon vector system may provide a safe long term gene transfer strategy. To evaluate phenotypic correction, a tail clip assay was performed at the end of the study. More than 75% of mice receiving PB coFVIII-BDD transposon and iPB7 demonstrated functional correction via tail clip. These data show that the PB vector can be used to deliver transgene expression to the liver and achieve long term expression and phenotypic correction. Disclosures: No relevant conflicts of interest to declare.
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