Keith A. Rodvold

Diagnosis and Management of Complicated Intra-abdominal Infection in Adults and Children: Guidelines by the Surgical Infection Society and the Infectious Diseases Society of America

Evidence-based guidelines for managing patients with intra-abdominal infection were prepared by an Expert Panel of the Surgical Infection Society and the Infectious Diseases Society of America. These updated guidelines replace those previously published in 2002 and 2003. The guidelines are intended for treating patients who either have these infections or may be at risk for them. New information, based on publications from the period 2003-2008, is incorporated into this guideline document. The panel has also added recommendations for managing intra-abdominal infection in children, particularly where such management differs from that of adults; for appendicitis in patients of all ages; and for necrotizing enterocolitis in neonates.

Relationship between Initial Vancomycin Concentration-Time Profile and Nephrotoxicity among Hospitalized Patients

BACKGROUND Data suggest that higher doses of vancomycin can increase the risk of nephrotoxicity. No study has been undertaken to determine the pharmacodynamic index (ie, the area under the curve [AUC] or the trough value) that best describes the relationship between vancomycin exposure and onset of nephrotoxicity. METHODS A retrospective study was conducted among patients who received vancomycin for a suspected or proven gram-positive infection during the period from 1 January 2005 through 31 December 2006 at Albany Medical Center Hospital. Patients were included in our study if they (1) were > or =18 years old, (2) had an absolute neutrophil count of > or =1000 cells/mm(3), (3) received vancomycin for >48 h, (4) had 1 vancomycin trough level collected within 96 h of vancomycin therapy, and (5) had a baseline serum creatinine level of <2.0 mg/dL. Patients were excluded if they (1) had a diagnosis of cystic fibrosis, (2) received intravenous contrast dye within 7 days of starting vancomycin or during therapy, or (3) required vasopressor support during therapy. Demographics, comorbid conditions, and treatment data were collected. The highest observed vancomycin trough value within 96 h of initiation of vancomycin therapy and the estimated vancomycin AUC were analyzed as measures of vancomycin exposure. The vancomycin AUC value from 0 to 24 h at steady state (in units of mg x h/L) for each patient was estimated by use of the maximum a posteriori probability Bayesian procedure in ADAPT II. Nephrotoxicity was defined as an increase in serum creatinine level of 0.5 mg/dL or 50%, whichever was greater, following initiation of vancomycin therapy. Logistic and Cox proportional hazards regression models identified the vancomycin pharmacodynamic index that best describes the relationship between vancomycin exposure and toxicity. RESULTS During the study period, 166 patients met the inclusion criteria. Both initial vancomycin trough values and 0-24-h at steady state AUC values were associated with nephrotoxicity in the bivariate analyses. However, the vancomycin trough value, modeled as a continuous variable, was the only vancomycin exposure variable associated with nephrotoxicity in the multivariate analyses. CONCLUSIONS The results indicate that a vancomycin exposure-toxicity response relationship exists. The vancomycin trough value is the pharmacodynamic index that best describes this association.

Diagnosis and management of complicated intra-abdominal infection in adults and children: guidelines by the Surgical Infection Society and the Infectious Diseases Society of America.

Evidence-based guidelines for managing patients with intra-abdominal infection were prepared by an Expert Panel of the Surgical Infection Society and the Infectious Diseases Society of America. These updated guidelines replace those previously published in 2002 and 2003. The guidelines are intended for treating patients who either have these infections or may be at risk for them. New information, based on publications from the period 2003-2008, is incorporated into this guideline document. The panel has also added recommendations for managing intra-abdominal infection in children, particularly where such management differs from that of adults; for appendicitis in patients of all ages; and for necrotizing enterocolitis in neonates.

Doxorubicin clearance in the obese.

A study was carried out to examine the effect, if any, of obesity on doxorubicin pharmacokinetics. Body weight was found to be significantly related to doxorubicin clearance (r = -.75; P less than .001) and elimination half-life (r = .62; P = .003). Thus, the contribution of obesity on pharmacokinetics of antineoplastic agents should be taken into consideration in the analysis of clinical data with respect to toxicity and tumor response. Twenty-one patients were studied with their first course of doxorubicin (50 to 70 mg/m2) administered as a 60-minute intravenous (IV) infusion. Patients were divided into three groups on the basis of percentage of ideal body weight (IBW): normal (less than 115% IBW), mildly obese (115% to 130% IBW), and obese (greater than 130% IBW). Blood samples were collected up to 48 hours after the infusion and analyzed for doxorubicin and its metabolite, doxorubicinol, by high performance liquid chromatography. Doxorubicin area under the curve (AUC) was greater in obese than in normal patients (2,209 v 1,190 ng h/mL; P less than .05), yielding correspondingly reduced systemic clearance of the agent in obese patients (891 v 1,569 mL/min; P less than .001). The mean elimination half-life (T1/2) was 20.4 hours in the obese patients and 13.0 hours in the normal patients. The apparent volume of distribution (Vss) was not significantly different among the three groups of patients, indicating that the prolonged T1/2 in the obese patients is due to the reduction in clearance. The AUC and T1/2 of doxorubicinol were similar among all patient groups.

Vancomycin pharmacokinetics in patients with various degrees of renal function.

The influence of age, protein binding, and renal function on the pharmacokinetics of intravenous vancomycin was evaluated in 37 adult patients with various degrees of renal function. Patients were categorized into three groups based on measured creatinine clearance (CLCR): groups 1, 2, and 3 had 24-h CLCRs of greater than 70, 40 to 70, and 10 to 39 ml/min per 1.73 m2, respectively. After 1 h of intravenous infusion, concentrations of vancomycin in serum declined in a biexponential manner in all patients. Diminished renal function in groups 2 and 3 was accompanied by a lower total body vancomycin clearance (CL) (52.6 and 31.3, respectively, versus 98.4 ml/min per 1.73 m2) and a lower renal vancomycin clearance (CLR) (48.2 and 19.8, respectively, versus 88.0 ml/min per 1.73 m2) than in group 1. No significant differences in apparent distribution volume of the central compartment or apparent distribution volume at steady state were observed. Mean serum protein binding of vancomycin was 30% and was not significantly affected by renal function. Stepwise multiple linear regression analysis revealed that CLCR was the strongest predictor of vancomycin CL (r = 0.77, P less than 0.001) and vancomycin CLR (r = 0.87, P less than 0.001). Age did not significantly improve these correlations once CLCR was included. The relationship of vancomycin CL and CLCR was utilized to develop the following equation to dose vancomycin in the majority of renally impaired patients: dose (milligrams per kilogram per 24 h) = 0.227CLCR + 5.67, where CLCR is standardized to milliliters per minute per 70 kg. The practical dosing intervals that the calculated dose can be divided into and administered include 8, 12, 24, and 48 h based on the CLCR of the patient.

Vancomycin: We Can't Get There From Here

BACKGROUND We sought to characterize the pharmacodynamic profile of the more intensive vancomycin dosing regimens currently used in response to the recent vancomycin guidelines. METHODS A series of Monte Carlo simulations was performed for vancomycin regimens ranging from .5 g intravenous (IV) Q12H to 2 g IV Q12H. The probability of achieving an AUC/MIC ratio ≥ 400 for each dosing regimen was calculated for minimum inhibitory concentrations (MICs) from .5 to 2 mg/L. The risk of nephrotoxicity for each regimen was derived from a previously published vancomycin trough-nephrotoxicity logistic regression function. Restricted analyses were performed that only included subjects with troughs between 15 and 20 mg/L. RESULTS At a MIC of 2 mg/L, even the most aggressive dosing regimen considered (2 g every 12 h) only yielded a probability of target attainment (PTA) of 57% while generating a nephrotoxicity probability upward of 35%(.) At a MIC of 1 mg/L, ≥3 g per day provided PTA in excess of 80% but were associated with unacceptable risks of nephrotoxicity. In the restricted analyses of subjects with troughs between 15 and 20 mg/L, all regimens produced a PTA of 100% at MICs ≤1 mg/L. The PTA was variable among the regimens at a MIC of 2 mg/L and was highly dependent on the total daily dose administered. CONCLUSIONS This study indicates that vancomycin may not be useful for treating serious methicillin-resistant Staphylococcus aureus (MRSA) infections with MIC values > 1 mg/L where PTA is questionable. Since an AUC/MIC ratio ≥ 400 is target associated with efficacy, one should consider incorporating computation of AUC when monitoring vancomycin.

Clinical pharmacokinetics of clarithromycin.

Clarithromycin is a macrolide antibacterial that differs in chemical structure from erythromycin by the methylation of the hydroxyl group at position 6 on the lactone ring. The pharmacokinetic advantages that clarithromycin has over erythromycin include increased oral bioavailability (52 to 55%), increased plasma concentrations (mean maximum concentrations ranged from 1.01 to 1.52 mg/L and 2.41 to 2.85 mg/L after multiple 250 and 500mg doses, respectively), and a longer elimination half-life (3.3 to 4.9 hours) to allow twice daily administration. In addition, clarithromycin has extensive diffusion into saliva, sputum, lung tissue, epithelial lining fluid, alveolar macrophages, neutrophils, tonsils, nasal mucosa and middle ear fluid.Clarithromycin is primarily metabolised by cytochrome P450 (CYP) 3A isozymes and has an active metabolite, 14-hydroxyclarithromycin. The reported mean values of total body clearance and renal clearance in adults have ranged from 29.2 to 58.1 L/h and 6.7 to 12.8 L/h, respectively. In patients with severe renal impairment, increased plasma concentrations and a prolonged elimination half-life for clarithromycin and its metabolite have been reported. A dosage adjustment for clarithromycin should be considered in patients with a creatinine clearance <1.8 L/h.The recommended goal for dosage regimens of clarithromycin is to ensure that the time that unbound drug concentrations in the blood remains above the minimum inhibitory concentration is at least 40 to 60% of the dosage interval. However, the concentrations and in vitro activity of 14-hydroxyclarithromycin must be considered for pathogens such as Haemophilus influenzae. In addition, clarithromycin achieves significantly higher drug concentrations in the epithelial lining fluid and alveolar macrophages, the potential sites of extracellular and intracellular respiratory tract pathogens, respectively. Further studies are needed to determine the importance of these concentrations of clarithromycin at the site of infection.Clarithromycin can increase the steady-state concentrations of drugs that are primarily depend upon CYP3A metabolism (e.g., astemidole, cisapride, pimozide, midazolam and triazolam). This can be clinically important for drugs that have a narrow therapeutic index, such as carbamazepine, cyclosporin, digoxin, theophylline and warfarin. Potent inhibitors of CYP3A (e.g., omeprazole and ritonavir) may also alter the metabolism of clarithromycin and its metabolites. Rifampicin (rifampin) and rifabutin are potent enzyme inducers and several small studies have suggested that these agents may significantly decrease serum clarithromycin concentrations. Overall, the pharmacokinetic and pharmacodynamic studies suggest that fewer serious drug interactions occur with clarithromycin compared with older macrolides such as erythromycin and troleandomycin.

Antimicrobial Dosing in Obese Patients

Although the dose of some drugs is commonly adjusted for weight, weight-related dosage adjustments are rarely made for most antimicrobials. We reviewed the English-language literature on antimicrobial pharmacokinetics and dosing in obesity. Although there are many potential pharmacokinetic consequences of obesity, the actual effect on the pharmacokinetics and clinical efficacy of most antimicrobials is unknown. Since approximately 30% of adipose is water, an empirical approach is use of the Devine formula to calculate ideal body weight (IBW), to which is added a dosing weight correction factor (DWCF) of 0.3 times the difference between actual body weight (ABW) and IBW (IBW + 0.3 x [ABW-IBW]) to arrive at a weight on which to base dosage of hydrophilic antibiotics. No studies confirm this approach for beta-lactam drugs. Clinical studies suggest a DWCF of approximately 0.40 for aminoglycosides and 0.45 for quinolones. Final dosage adjustments for antimicrobials with a narrow toxic-therapeutic window should be based on serum concentrations.

Pharmacokinetics and pharmacodynamics of doxorubicin in patients with small cell lung cancer

The pharmacokinetics and pharmacodynamics of doxorubicin and its metabolite, doxorubicinol, were studied in 35 adult (mean age, 66½ years) patients with small cell lung cancer after a 1‐hour intravenous infusion at a dose ranging from 45 to 72 mg/m2. All patients also received concomitant therapy with cyclophosphamide and vincristine. Serum concentrations were sampled to 48 hours after dosing. Wide interpatient variability was observed for all pharmacokinetic parameters with coefficients of variation for apparent volume of distribution, clearance, and area under the curve (AUC) of 62%, 65%, and 65%, respectively. Four patients with impaired liver function showed a significant (p < 0.05) decrease in clearance (239 versus 666 ml/min/m2) and increases in AUC (4610 versus 1834 ng · hr/ml) and elimination half‐life (49.3 versus 25.6 hours) compared with patients with normal hepatic function. A significant relationship was found between systemic exposure of doxorubicin (defined by AUC) and surviving factor of white blood cells (r = 0.57, p = 0.0025). No relationships were noted between doxorubicinol exposure and surviving factor of white blood cells or platelets. These findings show the important relationship between systemic exposure of doxorubicin and the degree of myelosuppression in patients with small cell lung cancer.

Pharmacodynamic Profiling of Piperacillin in the Presence of Tazobactam in Patients through the Use of Population Pharmacokinetic Models and Monte Carlo Simulation

ABSTRACT The primary objectives of this analysis were to determine which pharmacokinetic model most accurately describes the elimination pathways for piperacillin in the presence of tazobactam through population pharmacokinetic modeling and to characterize its pharmacodynamic profile. Once the optimal pharmacokinetic model was identified, Monte Carlo simulation of 10,000 subjects with ADAPT II was performed to estimate the probability of attaining a target free-piperacillin concentration greater than the MIC for 50% of the dosing interval for 3.375 g every 6 h or every 4 h given as a 0.5-h infusion at each MIC between 0.25 and 32 μg/ml. In the population pharmacokinetic analysis, measurements of bias and precision, observed-predicted plots, and r2 values were highly acceptable for all three models and all three models were appropriate candidates for the Monte Carlo simulation evaluation. Visual comparison of the distribution of the piperacillin concentrations at the pharmacodynamic endpoint—h 3 concentrations of a 6-h dosing interval—between the simulated populations and raw data revealed that the linear model was most reflective of the raw data at the pharmacodynamic endpoint, and the linear model was therefore selected for the target attainment analysis. In the target attainment analysis, administration of 3 g of piperacillin every 6 h resulted in a robust target attainment rate that exceeded 95% for MICs of ≤8 mg/liter. The 4-h piperacillin administration interval had a superior pharmacodynamic profile and provided target attainment rates exceeding 95% for MICs of ≤16 mg/liter. This study indicates that piperacillin-tazobactam should have utility for empirical therapy of hospital-onset infections.