Right ventricular (RV) dysfunction is associated with poor clinical outcome following pulmonary embolism (PE). Previous studies in our laboratory show that influx of neutrophils contributes to acute RV damage seen in an 18 h rat model of PE. The present study describes the further progression of inflammation over 6 weeks and compares the neutrophil and monocyte responses. The RV outflow tract became white in colour by day 1 with influx of neutrophils (tissue myeloperoxidase activity increased 17-fold) and mononuclear cells with characteristics of M1 phenotype (high in Ccl20, Cxcl10, CcR2, MHCII, DNA microarray analysis). Matrix metalloproteinase activities were increased and tissue was thinned to produce a translucent appearance in weeks 1 through 6 in 40% of hearts. RV contractile function was significantly reduced at 6 weeks of PE. In this later phase, there was accumulation of myofibroblasts, the presence of mononuclear cells with M2 characteristics (high in scavenger mannose receptors, macrophage galactose lectin 1, PDGFR1, PDGFRbeta), enrichment of the subendocardial region of the RV outflow tract with neovesels (alpha-smooth muscle immunohistochemistry) and deposition of collagen fibres (picrosirius red staining) beginning scar formation. Thus, while neutrophil response is associated with the early, acute inflammatory events, macrophage cells continue to be present during the proliferative phase and initial deposition of collagen in this model, changing from the M1 to the M2 phenotype. This suggests that the macrophage cell response is biphasic.
Right ventricular (RV) dysfunction is a strong risk factor for poor clinical outcome following pulmonary embolism (PE), the third most prevalent cardiovascular disease. Previous studies in our laboratory demonstrated that RV failure during PE is mediated, in part, by neutrophil-dependant cardiac inflammation. In this study we use DNA microarray analysis of gene expression to demonstrate that PE results in increased expression of the CXC chemokines CINC-1 and CINC-2 between 6 and 18 h after the start of PE in a rat model of PE. Neutrophils accumulate in RV tissue by 18 h, and this inflammation is associated with decreased right heart function. Treatment of rats with Abs to CINC-1 significantly suppressed neutrophil accumulation in RVs during PE (52% reduction in tissue myeloperoxidase) and ameliorated RV failure. In addition, plasma concentration of cardiac troponin I, an established diagnostic marker for cardiac damage, was reduced by 90%. These results suggest that selective anti-inflammatory therapies targeted at neutrophil chemoattractants will reduce cardiac inflammation and reduce RV damage in the setting of PE.
Background: The emergence of drug resistant viruses, together with the possibility of increased virulence, is an important concern in the development of new antiviral compounds. Cidofovir (CDV) is a phosphonate nucleotide that is approved for use against cytomegalovirus retinitis and for the emergency treatment of smallpox or complications following vaccination. One mode of action for CDV has been demonstrated to be the inhibition of the viral DNA polymerase.
Right ventricular (RV) damage contributes to poor clinical outcome after pulmonary embolism (PE). Our studies show that neutrophils contribute to RV dysfunction in rat PE. Present studies examine effects of the nonsteroidal anti-inflammatory drug, ketorolac, upon RV inflammation and dysfunction. RV inflammatory gene expression significantly increased 6 and 18 hours after PE [cytokine-induced neutrophil chemoattractant-1 (CINC-1) 18-fold and 24-fold; cyclooxygenase-2 21-fold and 32-fold]. Eighteen hours after PE, there was significant upregulation of adhesion molecules (selectin E 18-fold; intercellular adhesion molecule 1 14-fold), influx of neutrophils (myeloperoxidase activity 21-fold), depressed RV function (RV peak systolic pressure = 24 +/- 3 vs. 40 +/- 1 mm Hg; maximum rate of pressure development = 444 +/- 79 vs. 1533 +/- 146; maximum rate of pressure decrease = -357 +/- 50 vs. -651 +/- 44), and release of cardiac troponin I (7.8 +/- 1.9 ng/mL) compared with vehicle. Ketorolac (10 mg/kg, intraperitoneally) significantly reduced expression of CINC-1, cyclooxygenase-2, selectin E, and intercellular adhesion molecule 1, lowered neutrophil influx, improved RV function (RV peak systolic pressure was 34 +/- 3 mm Hg; maximum rate of pressure development = 1288 +/- 146; maximum rate of pressure decrease = -611 +/- 92), and marginally reduced cardiac troponin I release (P < 0.07) compared with PE alone. Ketorolac reduced CINC-1 stimulated chemotaxis of isolated neutrophils. PE converted cardiac tissue into a proinflammatory phenotype. Ketorolac reduced RV inflammatory genes, reduced neutrophil influx, and improved RV function in rat PE.
Moderate to severe pulmonary embolism (PE) can cause pulmonary arterial hypertension and right ventricular (RV) heart damage. Previous studies from our laboratory indicate that the basal outflow tract of the RV is injured and has acute inflammation followed by tissue remodeling while the apex appears normal. The present studies examine transcription responses to chronic PE in RV apex and outflow tracts using DNA microarrays to identify transcription responses by region. Changes predominated in the RV outflow tract (8,575 genes showed >/=1.5-fold expression change). Gene ontology and KEGG analyses indicated a significant decrease in genes involved in cellular respiration and energy metabolism and increases in inflammatory cell adhesion molecules and extracellular matrix proteins. Signal pathways for wound healing such as fibroblast growth factor, collagen synthesis, and CCN proteins (named for the first three members of the family: cysteine-rich protein 61, connective tissue growth factor, and nephroblastoma overexpressed gene) were strongly upregulated. In comparison, few genes (422) showed significant change in the RV apex tissue. Apex-selective genes included two genes affecting metabolism and a stretch-sensitive transcription factor (ankyrin repeat domain 1). We conclude that the RV outflow tract is subject to strong proinflammatory and profibrotic remodeling transcriptional responses in chronic PE. Severe loss of genes involved in cellular respiration is consistent with previous histology indicating a shift in cell types present within the outflow tract tissue away from highly energy-dependant cardiomyocytes to less metabolically active cells during remodeling. The apex region of the RV had few compensating adaptations.
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