The role of bradykinin and the effect of the bradykinin receptor antagonist icatibant in porcine sepsis.

Bradykinin (BK) is regarded as an important mediator of edema, shock, and inflammation during sepsis. In this study, we evaluated the contribution of BK in porcine sepsis by blocking BK and by measuring the stable BK metabolite, BK1-5, using anesthetized pigs. The effect of BK alone, the efficacy of icatibant to block this effect, and the recovery of BK measured as plasma BK1-5 were first investigated. Purified BK injected intravenously induced an abrupt fall in blood pressure, which was completely prevented by pretreatment with icatibant. BK1-5 was detected in plasma corresponding to the doses given. The effect of icatibant was then investigated in an established model of porcine gram-negative sepsis. Neisseria meningitidis was infused intravenously without any pretreatment (n = 8) or pretreated with icatibant (n = 8). Negative controls received saline only. Icatibant-treated pigs developed the same degree of severe sepsis as did the controls. Both groups had massive capillary leakage, leukopenia, and excessive cytokine release. The plasma level of BK1-5 was low or nondetectable in all pigs. The latter observation was confirmed in supplementary studies with pigs undergoing Escherichia coli or polymicrobial sepsis induced by cecal ligation and puncture. In conclusion, icatibant completely blocked the hemodynamic effects of BK but had no beneficial effects on N. meningitidis-induced edema, shock, and inflammation. This and the fact that plasma BK1-5 in all the septic pigs was virtually nondetectable question the role of BK as an important mediator of porcine sepsis. Thus, the data challenge the current view of the role of BK also in human sepsis.

Cinacalcet's effect on the pharmacokinetics of tacrolimus, cyclosporine and mycophenolate in renal transplant recipients.

BACKGROUND: The calcimimetic drug cinacalcet offers a novel therapeutic option to treat post-transplant hypercalcemia and hyperparathyroidism; however, the interaction with calcineurin inhibitors and mycophenolate has not been evaluated. METHODS: In the present study the effects of cinacalcet on the pharmacokinetics of cyclosporine A (CsA), tacrolimus (Tac) and mycophenolate were investigated in 14 renal transplant recipients with stable renal function (mean creatinine 126.4 +/- 45.3 micromol/L). The patients were treated with either CsA (n = 8) or Tac (n = 6) in combination with mycophenolate/azathioprine and steroids. Twelve-hour pharmacokinetic investigations to measure CsA and its six main metabolites, Tac and mycophenolate concentrations were performed before and after 1-week treatment with 30 mg cinacalcet once daily. RESULTS: Cinacalcet treatment induced a significant 14.3 +/- 12.1% decrease in Tac AUC(0-12) (P = 0.039). Tac C(max), T(max) and T(1/2) also tended to decrease. The pharmacokinetics of CsA and mycophenolate were not significantly affected by concomitant treatment with cinacalcet. However, the secondary CsA metabolite, AM19, showed a significant increase of 9.0 +/- 9.5% during cinacalcet treatment (P = 0.040). Renal function decreased significantly from 78 +/- 11 to 72 +/- 12 mL/min (P = 0.019) and correlated with the increased levels of metabolite AM19 in the CsA group. Renal function was unchanged in the Tac group. CONCLUSION: Cinacalcet treatment showed a moderate effect on the Tac, but not CsA or mycophenolate, pharmacokinetics after 1-week concomitant treatment. This interaction appears to have minor clinical relevance. However, it is advisable to monitor renal function in CsA-treated patients due to the observed decrease in renal function.

Determination of ciclosporin A and its six main metabolites in isolated T-lymphocytes and whole blood using liquid chromatography-tandem mass spectrometry.

A specific and sensitive method for determination of intracellular ciclosporin A (CsA) and its six main metabolites AM1, AM9, AM1c, AM1c9, AM19 and AM4N, in isolated T-lymphocytes and whole blood is described. T-lymphocytes were separated from whole blood using Prepacyte. The analytes were extracted and purified from isolated lymphocytes and whole blood by protein precipitation followed by solid-phase extraction (SPE). The analytes and the internal standard, ciclosporin C (CsC), were separated on a reversed phase C8 column (30 mm x 2.1mm, 3 microm) with a 10 mm x 2 mm, 5 microm Drop-In Guard Cartridge, using gradient elution chromatography and tandem ion trap mass spectrometry detection. The method has been validated in accordance with FDA guidelines and showed linear range from 0.25 to 500 ng/mL for CsA, 0.5 to 500 ng/mL for AM1, AM9 and AM19, 1 to 500 ng/mL for AM4N, AM1c and AM1c9 in intracellular matrix, and 2.5 to 3000 ng/mL for all analytes in whole blood. The applicability of the method is shown on patient samples.

Atorvastatin does not affect the pharmacokinetics of cyclosporine in renal transplant recipients.

OBJECTIVE: The aim of the present study was to evaluate the possible influence of atorvastatin on the pharmacokinetics of cyclosporine (INN ciclosporin) and its main metabolites, AM1 and AM9, in renal transplant recipients. METHODS: Whole blood samples from 18 renal transplanted patients on cyclosporine-based immunosuppressive therapy were collected prior to and after 4 weeks of treatment with atorvastatin (10 mg/day) and analysed with regard to both cyclosporine and its main metabolites, AM1 and AM9, using a specific chromatographic method with ultraviolet detection. RESULTS: On average, AUC(0-12) [area under the whole blood concentration versus time curve in the dosing interval (0-12 h)] of cyclosporine was 5% (-16, 5) (90% confidence interval) lower upon co-administration with atorvastatin. No statistically significant changes in any of the calculated pharmacokinetic variables [AUC(0-12), maximum whole blood concentration (C(max)), whole blood concentration 12 h post dose (C(12)), time to C(max) (t(max)), terminal half-life (t(1/2))] for cyclosporine or the two metabolites, AM1 and AM9, upon atorvastatin treatment were observed. On average, atorvastatin did not affect the ratio between the CYP3A4-mediated metabolite AM9 and cyclosporine, suggesting that atorvastatin does not affect the CYP3A4 metabolism of cyclosporine to any significant extent. However, the influence of atorvastatin on the ratio between AM9 and cyclosporine showed large interindividual variability. CONCLUSION: The results of this study indicate that atorvastatin does not, on average, affect cyclosporine pharmacokinetics in renal transplant recipients.

Screening for central nervous system-stimulating drugs in human plasma by liquid chromatography with mass spectrometric detection.

Liquid chromatography and electrospray mass spectrometry was evaluated for screening of more than 70 central nervous system-stimulating drugs in human plasma. Protein precipitation was utilized as a simple sample preparation procedure, and the subsequent screening procedure involved two injections in a liquid chromatography-mass spectrometry system for each sample; a first screening without source induced dissociation to maximize sensitivity where potential positive identifications were based on retention time and molecular ion masses, and secondly a source induced dissociation confirmation based on retention time, molecular ions, and one or two fragment ions for each target generated by a 25 V fragmentation energy. The majority of central nerve system stimulating drugs were possible to identify within the actual therapeutic ranges. Experiences with 175 real samples supported this and strongly indicated that information reported by patients on their consumption of central nerve system stimulating drugs is highly unreliable. Thus, protein precipitation and liquid chromatography-mass spectrometry may be a valuable tool for broad drug screening in human plasma in the future.