Scalp arteriovenous malformation associated with a superior sagittal sinus, sinus pericranii.

Scalp arteriovenous malformations (AVMs) and sinus pericranii are two rare vascular lesions of the scalp that are part of the differential diagnosis in patients with scalp masses. The necessity of treatment of sinus pericranii, due to its risk of catastrophic hemorrhage or scalp necrosis, makes its diagnosis imperative. There are several theories on the pathogenesis of sinus pericranii with some of them stressing the importance of altered hemodynamic parameters in the affected area. An 8-year-old girl presented with a five centimeter soft, reducible scalp mass that had been present since birth. Clinical and radiographic evaluation revealed a sinus pericranii in association with a scalp AVM. She underwent resection of the sinus pericranii followed by embolization and planned separate en bloc resection of the AVM. During resection of the scalp AVM at a later date, the sinus pericranii was noted to have recurred. Concurrent treatment of all vascular anomalies associated with a sinus pericranii appears to be the key to its complete eradication.

Nonhelical acquisition CT angiogram after aneurysmal clipping: in vitro testing shows diminished artifact.

Imaging of the cerebral vessels with use of CT angiogram (CTA) after placement of aneurysmal clips is often limited by clip artifacts. We used a phantom to demonstrate a visible reduction in metal artifact when using the axial technique, compared with the usual CTA helical acquisition. This approach may have some advantage when used for CTA with 64-section scanners in the specific circumstance of immediate postoperative imaging after placement of cerebral aneurysmal clips.

Phase I trial, including pharmacokinetic and pharmacodynamic correlations, of combination paclitaxel and carboplatin in patients with metastatic non-small-cell lung cancer.

PURPOSE: To determine the maximum-tolerated dose of paclitaxel with carboplatin with and without filgrastim support in patients with metastatic non-small-cell lung cancer (NSCLC) and to investigate the pharmacokinetics of paclitaxel and carboplatin and correlate these with the pharmacodynamic effects. PATIENTS AND METHODS: Thirty-six chemotherapy-naive patients with metastatic NSCLC were entered into this phase I dose-escalation and pharmacokinetic study. Paclitaxel was initially administered as a 24-hour infusion at a fixed dose of 135 mg/m2, and the carboplatin dose was escalated in cohorts of three patients, using Calvert's formula [dose(mg) = area under the concentration time curve (glomerular filtration rate + 25)], to target areas under the concentration time curve (AUCs) of 5, 7, 9, and 11 mg/mL x minute. A measured 24-hour urinary creatinine clearance was substituted for the glomerular filtration rate. Once the maximum-tolerated AUC (MTAUC) of carboplatin was reached, the paclitaxel dose was escalated to 175, 200, and 225 mg/m2. When the paclitaxel dose escalation began, the AUC of carboplatin was reduced to one level below the MTAUC. RESULTS: Myelosuppression was the major dose-limiting toxicity. Thrombocytopenia was observed at a carboplatin AUC of 11 mg/mL x minute after course 2 and thereafter. End-of-infusion plasma paclitaxel concentrations and median duration of time above 0.05 microM were similar in course 1 versus course 2 at the 135 and 175 mg/m2 dose levels. The neutropenia experienced by patients was consistent with that observed in patients who had received paclitaxel alone. Measured carboplatin AUCs were approximately 12% (20% v 3% with course 1 v course 2, respectively) below the desired target, with a standard deviation of 34% at all dose levels. A sigmoid-maximum effect model describing the relationship between relative thrombocytopenia and measured free platinum exposure indicated that patients who received the combination of carboplatin with paclitaxel experienced less severe thrombocytopenia than would be expected from carboplatin alone. Of the 36 patients entered onto the study, one experienced a complete response and 17 had partial responses, for an overall response rate of 50%. The recommended doses of paclitaxel (24-hour infusion) and carboplatin for future phase II studies of this combination are (1) paclitaxel 135 mg/m2 with a carboplatin dose targeted to achieve an AUC of 7 mg/mL x minute without filgrastim support; (2) paclitaxel 135 mg/m2 with a carboplatin dose targeted to achieve an AUC of 9 mg/mL x minute with filgrastim support; and (3) paclitaxel 225 mg/m2 with a carboplatin dose targeted to achieve an AUC of 7 mg/mL x minute with filgrastim support. CONCLUSION: The regimen of paclitaxel and carboplatin is well-tolerated and has promising activity in the treatment of NSCLC. There is no pharmacokinetic interaction between paclitaxel and carboplatin, but there is a pharmacodynamic, platelet-sparing effect on this dose-limiting toxicity of carboplatin.

Pharmacokinetics of paclitaxel and carboplatin in combination.

We studied the pharmacokinetics of paclitaxel (Taxol; Bristol-Myers Squibb Company, Princeton, NJ) and carboplatin administered in combination to 21 patients with advanced non-small cell lung cancer. Paclitaxel was administered as a 24-hour intravenous infusion at doses of 135 to 200 mg/m2. Carboplatin, dosed to a target area under the concentration-time curve of 5, 7, 9, or 11 mg/mL.min, was administered as a 20-minute infusion immediately following paclitaxel. Neither the paclitaxel concentrations at the end of the infusion nor the terminal elimination of paclitaxel, as assessed by the duration of time that plasma paclitaxel concentrations were 0.05 mumol/L or greater, were different compared with historical data of paclitaxel as a single agent. Thus, we concluded that carboplatin had no perceived effect on the pharmacokinetics of paclitaxel in this schedule. The observed areas under the concentration-time curves for carboplatin were consistently 10% to 15% less than the target values. Although this may indicate a possible interaction between paclitaxel and carboplatin, it also may have been a result of inadequate assessment of glomerular filtration rate, which was used to determine the carboplatin dose.

Effects of storage on the binding of carboplatin to plasma proteins.

Plasma ultrafiltrates are routinely used in pharmacokinetic studies of carboplatin. Experiments were performed to detect and quantitate artifactual decreases in the platinum concentration of ultrafiltrates prepared from plasma samples stored at -20 degrees C and -70 degrees C. Carboplatin was added to anticoagulated, whole human blood to produce a 20 microgram/ml concentration. Plasma produced from the blood was stored frozen at either -20 degrees C or -70 degrees C. Aliquots from each storage condition were thawed and ultrafiltered once a week for up to 100 days. Platinum concentrations in ultrafiltrates and plasma were determined by flameless atomic absorption spectrometry. There was no loss of ultrafilterable platinum in plasma samples stored at -70 degrees C, whereas there was a steady decrease in free platinum concentration in ultrafiltrates prepared from plasma samples stored at -20 degrees C. These results imply that pharmacokinetic studies of carboplatin should use ultrafiltrates prepared immediately or that plasma for such studies should be stored at -70 degrees C. Storage of carboplatin-containing plasma at -20 degrees C and subsequent ultrafiltration is not acceptable, because measurement of platinum in such ultrafiltrates will be artifactually low.

Potentiation by interleukin 1 alpha of cisplatin and carboplatin antitumor activity: schedule-dependent and pharmacokinetic effects in the RIF-1 tumor model.

We have previously demonstrated that the cytokine interleukin 1 alpha (IL-1 alpha) significantly potentiates the antitumor activity of a variety of chemotherapeutic agents, including cisplatin (cDDP). In studies described here, we examined the potential of combining IL-1 alpha and the platinum analogue carboplatin (CBDCA) and compared the schedule-dependent and pharmacokinetic effects for IL-1 alpha combinations with cDDP and CBDCA. RIF-1 tumor-bearing mice (C3H/HeJ) received i.p. injections of varying doses of CBDCA, alone or concurrently with IL-1 alpha (48 or 480 micrograms/kg). Clonogenic cell kill and tumor regrowth delay were significantly increased when CBDCA was combined with IL-1 alpha, at both doses, compared to either CBDCA or IL-1 alpha alone (P < 0.001 and P < 0.01, respectively). Although pretreatment with IL-1 receptor antagonist blocked the acute tumor hemorrhagic response induced by IL-1 alpha alone, IL-1 receptor antagonist only partially blocked IL-1 alpha enhancement of CBDCA or cDDP-mediated tumor cell kill. The IL-1 alpha enhancement of CBDCA-mediated tumor cell kill was highly schedule dependent, with maximum antitumor activity observed when IL-1 alpha was administered 4-12 h before CBDCA. In contrast, administration of IL-1 alpha from 24 h before or as late as 6 h after cDDP resulted in the same antitumor activity as simultaneous administration of cDDP and IL-1 alpha. Tumor and normal tissue platinum content were significantly increased by IL-1 alpha in animals treated with CBDCA (P < 0.01) but not in those treated with cDDP. The observed differences between cDDP and CBDCA may be explained by their known differential rates of clearance and protein binding affinities and are compatible with an induced alteration in CBDCA pharmacokinetics.

Effect of cimetidine, probenecid, and ketoconazole on the distribution, biliary secretion, and metabolism of [3H]taxol in the Sprague-Dawley rat.

Male Sprague-Dawley rats had their bile ducts cannulated and were dosed with [3H]taxol (2 mg/kg, 68-77 microCi/mg) as a continuous intravenous infusion for 6 hr so that the plasma concentrations, tissue distribution, metabolism, and biliary secretion of taxol could be studied. Defining potential drug-drug interactions of taxol with cimetidine (90 mg/kg), probenecid (360 mg/kg), and ketoconazole (50 mg/kg) was motivated by frequent concomitant clinical use or the potential to reduce clearance of taxol so that lower doses could be used. At 6 hr, rats were killed. Samples of blood (plasma), lung, spleen, liver, kidney, heart, skeletal muscle, brain, testes, and fat were obtained. Taxol and metabolites were measured by total radioactivity counting and HPLC separation using on-line radioactivity detection. Concentrations of taxol in plasma increased to 0.19 microM in the control rats and did not reach steady-state by 6 hr. Lung, spleen, liver, and kidneys had the greatest tissue taxol concentrations [4.7-5.7 nmol/g (microM)] and were > 25-fold higher than the simultaneous 6-hr plasma taxol concentration. Taxol concentrations in brain and testes were negligible, 0.06 and 0.07 nmol/g, respectively. Radioactive metabolites were not found in plasma or most tissues. Only liver had appreciable concentrations of taxol and metabolites; however, > 80% of hepatic radioactivity was parent taxol. Through 6 hr of collection, 24% of the dose was secreted in the bile approximately 38% of which was as parent taxol. Cimetidine had no effect on the distribution, metabolism, or elimination of [3H]taxol. Probenecid did not effect tissue distribution or plasma concentrations of taxol.(ABSTRACT TRUNCATED AT 250 WORDS)