Usefulness of a molecular strategy for the detection of bacterial DNA in patients with severe sepsis undergoing continuous renal replacement therapy.

INTRODUCTION: Sepsis is a major cause of morbidity and mortality in critically ill patients. Sepsis is associated with cell necrosis and apoptosis. Circulating plasma levels of DNA have been found in conditions associated with cell death, including sepsis, pregnancy, stroke, myocardial infarction and trauma. Plasma DNA can also derive from bacteria. We have recently implemented a method to detect bacterial DNA and, in the present study, we validated this technique comparing it to standard blood culture in terms of diagnostic efficacy. METHODS: We examined a cohort of 9 critically ill patients with a diagnosis of severe sepsis and acute renal failure requiring continuous renal replacement therapy (CRRT). We analyzed bacterial DNA in blood, hemofilters, and ultrafiltrate (UF) by polymerase chain reaction amplification of 16S rRNA gene sequence analysis. Standard blood cultures were performed for all patients. RESULTS: The blood cultures from 2 of the 9 (22%) patients were positive. However, bacterial DNA was identified in the blood of 6 patients (67%), including the 2 septic patients with positive blood cultures. In 9 (100%) patients bacterial DNA was found on the filter blood side, whereas in 7 (78%) subjects it was found in the dialysate compartment of the hemofilters. Bacterial DNA was never detected in the UF. CONCLUSIONS: Using the 16S rRNA gene, the detection of bacterial DNA in blood and adsorbed within the filter could be a useful screening tool in clinically septic, blood culture-negative patients undergoing CRRT. However, the identification of the etiologic agent is not feasible with this technique because specific primers for the defined bacteria must be used to further identify the suspected pathogenic organisms.

Pulse high-volume hemofiltration in critically ill patients: a new approach for patients with septic shock.

Mortality rates in septic shock remain unacceptably high despite advances in our understanding of the syndrome and its treatment. Humoral factors are increasingly recognized to participate in the pathogenesis of septic shock, giving a biological rationale to therapies that might remove varied and potentially dangerous humoral mediators. While plasma water exchange in the form of hemofiltration can remove circulating cytokines in septic patients, the procedure, as routinely performed, does not have a substantial impact on their plasma levels. More intensive plasma water exchange, as high-volume hemofiltration (HVHF)can reduce levels of these mediators and potentially improve clinical outcomes. However, there are concerns about the feasibility and costs of HVHF as a continuous modality--very high volumes are difficult to maintain over 24 hours and solute kinetics are not optimized by this regimen. We propose pulse HVHF (PHVHF)-HVHF of 85 ml/kg/hr for 6-8 hours followed by continuous venovenous hemofiltration (CVVH) of 35 ml/kg/hr for 16-18 hours-as a new method to combine the advantages of HVHFimprove solute kinetics, and minimize logistic problems. We treated 15 critically ill patients with severe sepsis and septic shock using daily PHVHF in order to evaluate the feasibility of the technique, its effects on hemodynamics, and the impact of the treatment on pathologic apoptosis in sepsis. Hemodynamic improvements were obtained after 6 hours of PHVHF and were maintained subsequently by standard CVVHas demonstrated by the reduction in norepinephrine dose. PHVHFbut not CVVHsignificantly reduces apoptotic plasma activity within 1 hour and the pattern was maintained in the following hours. PHVHF appears to be a feasible modality that may provide the same or greater benefits as HVHFwhile reducing the workload and cost.

Protective effect of urate oxidase on uric acid induced-monocyte apoptosis.

Uremic patients have a higher risk of infection and malignancy than normal subjects. Previous studies have deomonstrated that monocytes isolated from uremic patients display an increased apoptosis rate compared to normal subjects; furthermore uremic plasma can increase apoptosis rates on U937, a human monocytic cell line. In several pathological conditions, precipitation of uric acid crystals can lead to renal insufficiency or acute renal failure by different mechanisms. In recent studies uric acid has been shown to induce inflammatory response from monocytes and it has been suggested to be involved in cell dysfunction. Rasburicase is a new recombinant urate oxidase developed to prevent and treat hyperuricaemia in patients with cancer or renal failure; it degrades uric acid to allantoin, a less toxic and more soluble product. In the present study, we aimed at determining whether uric acid may be a factor affecting U937 apoptosis, and whether urate oxidase may reduces or even prevent uric acid induced cell apoptosis. Hoechst staining and internucleosome ledder fragmentation of DNA showed that uric acid increased the percentage of apoptotic cells comparing to the control and that when the U937 cells were incubated with uric acid and urate oxidase the percentage of apoptosis significantly decreased (from 43+/-7% to 19+/- 3%, p<0.05). Also, the activity of caspase-8 and caspase-3 showed the same trend (caspase 3: from 2.7+/-0.53 to 1.6+/-0.42; caspase-8: from 2.2+/-0.43 to 1.3+/-0.57). A reduction of intracellular reduced glutathione (GSH) concentration was found in uric acid treated cells while the addition of urate oxidase in the uric acid incubated cells decreased the GSH extrusion. The concentration of TNF-alpha was increased in the sample incubated with uric acid comparing to the control. Uric acid is an inducer of apoptosis on U937 cell line, and therefore it may be a component of the mosaic of uremic toxins both in acute and chronic renal disease. We can hypothesize that uric acid might be directly involved in the apoptotic process trough the activation of both death receptor and mitochondrial-mediated pathways. We have, also, demonstrated that urate oxidase is able to prevent at least in part, the effect of uric acid on U937 apoptosis. This effect might be a result of different mechanisms of action.