Cetuximab concomitant with gemcitabine and radiotherapy in advanced squamous cell carcinomas of upper aerodigestive tract: a pilot study

PURPOSE: To explore the response and toxicity of advanced non-metastatic squamous cell carcinomas of upper aerodigestive tract (SCC-UADT) to a combination of cetuximab concomitant with gemcitabine and radiotherapy. METHODS: We managed patients with concomitant treatment of cetuximab (400 mg/m(2) as uploading dose, then 250 mg/m(2), IV) concomitant with gemcitabine (50 mg/m(2)) weekly for seven courses, and radiotherapy in classical fractionation until completion of 70 Gy. Primary endpoints were complete response (CR) to treatment and toxicity. We evaluated patients for toxicity on a weekly basis; evaluation of response included physical examination, endoscopy, computed tomography (CT) scan and biopsy when indicated, and was performed 6 weeks after completion of radiotherapy. Additional evaluations were done every 3 months to document disease status. Between November 2004 and November 2005, 20 patients were included. RESULTS: CR was 82.4%, overall response was 100%. Neck disease reached CR in 61.5% and partial in 38.5% of patients. The main toxicities were nausea, lymphopenia, neutropenia and mucositis. Grade 3 and 4 side effects were presented in 70.6% of patients, but mucositis, and lymphopenia without clinical repercussions, occurred in 88.2% of patients. Gastrostomy was required in 11.8% of patients to maintain nutrition. Radioepithelitis developed in 76.5%, but only three of these (23.1%) were grade III. Median overall survival was 53 months (range 6-55 months) and median progression-free survival has not yet been reached at the time of evaluation. CONCLUSIONS: Although toxicity is important, this approach has interesting activity and deserves further investigation (AU)

Bioavailability of etoposide after oral administration of the solution marketed for intravenous use: therapeutic and pharmacoeconomic perspectives.

BACKGROUND: Oral etoposide administration is a suitable alternative to the intravenous route; therefore, commercial capsules have been developed. Before these capsules were available in Mexico, we studied drug bioavailability after oral administration of the intravenous etoposide solution (IVES). METHODS: Eight adult cancer patients received a 50-mg oral etoposide dose as IVES and blood samples were collected over a period of 24 h. Plasma etoposide concentration was determined by high-performance liquid chromatography, plasma concentration against time curves were constructed, and bioavailability parameters were calculated. RESULTS: Oral IVES yielded an adequate bioavailability profile because Cmax was 2.38 +/- 0.30 micrograms/mL, AUC was 12.87 +/- 2.02 micrograms/mL and half-life was 6.72 +/- 0.97 h. CONCLUSIONS: Considering that the pharmacokinetic aim is to maintain plasma concentrations between 0.5 and 1.0 microgram/mL for several hours while avoiding high concentrations, i.e., of 10 micrograms/mL or higher, oral administration of 50-mg etoposide as IVES appears to be a suitable dosing option. In addition, oral IVES is considerably less expensive than intravenous administration in terms of both drug presentation and administration.

Prenatal hormones alter antioxidant enzymes and lung histology in rats with congenital diaphragmatic hernia.

Prenatal administration of dexamethasone (Dex) and thyrotropin-releasing hormone (TRH) synergistically enhances lung maturity, but TRH suppresses the antioxidant enzyme activity. Prenatal hormonal therapy improves alveolar surfactant content and lung compliance in rats with congenital diaphragmatic hernia (CDH). In full term neonatal rats with CDH we studied the effects of prenatal Dex or Dex+TRH on antioxidant enzyme activity at birth, on survival, and on lung morphometry after 4 h of ventilation with 100% O2. CDH was induced by administration of 2,4-dichlorophenyl-p-nitro-phenylether (Nitrofen) on gestational day 10. Dex+TRH-treated CDH rats had lower activity of glutathione reductase after birth than did sham-treated CDH pups. Dex-treated and sham-treated pups had similar antioxidant enzyme activity. Hormonal treatment did not change survival during ventilation. The average airspace volume increased in Dex-treated CDH pups after ventilation, with a small synergistic effect after addition of TRH. On the basis of our findings, we speculate that prenatal administration of Dex is the best choice to improve lung maturity and airspace volume in CDH patients.

Prenatal glucocorticoids improve pulmonary morphometrics in fetal sheep with congenital diaphragmatic hernia.

PURPOSE: Prenatal glucocorticoids reverse pulmonary immaturity in rodents with pharmacologically induced congenital diaphragmatic hernia (CDH). The authors applied quantitative stereologic morphometric techniques to test whether these effects could be reproduced in large animals (sheep) with surgically created CDH. METHODS: Diaphragmatic hernias were created surgically in fetal lambs at gestational day 80. The fetuses were treated with intravenous cortisol (n = 6) or normal saline control (n = 5) from days 133 to 135. Lungs distended at 15 cm pressure from each group were harvested at day 136, processed histologically, and studied by brightfield microscopy at 400 x using a 42-point equidistant counting grid. Ten morphometric parameters (Mean +/- SEM) were measured by point-counting 60 fields/lung, and analysis of variance was performed. RESULTS: The CDH-cortisol-treated lungs showed striking significant maturational improvements when compared with lungs of CDH-normal saline controls by seven of ten morphometric parameters. CONCLUSIONS: (1) Prenatal glucocorticoids accelerate lung maturity in fetal lambs with CDH by seven quantitative morphometric parameters. (2) The observation that prenatal glucocorticoid therapy improves measures of maturity for both CDH rodent and sheep models encourages proceeding with a Phase I human clinical trial in ultrasound-confirmed CDH.

Müllerian inhibiting substance inhibits branching morphogenesis and induces apoptosis in fetal rat lung.

Müllerian inhibiting substance (MIS) is a glycoprotein hormone required for normal male reproductive tract development; it is presumed to signal through a heteromeric complex of type I and type II receptors. MIS exposure produces a paracrine-mediated regression of the embryonic Müllerian duct with histological changes consistent with apoptosis. MIS has also been shown to inhibit fetal lung development in vitro and in vivo, although the mechanism of this inhibition is unknown. The primordial lung and gonad are anatomically proximate on embryonic day 13.5, raising the possibility of a paracrine-mediated influence of MIS in male embryos on lung as well as MIS effecting dissolution of the Müllerian duct. We hypothesized that a negative regulatory event(s) might occur in the lung, as occurs in the duct, at the onset of MIS protein expression; thus, apoptosis and branching morphogenesis were studied in explanted fetal rat lungs incubated with proteolytically activated MIS. MIS exposure resulted in reduced total lung bud number as well as lung perimeter length. Explanted lungs exposed to MIS also exhibited numerous apoptotic bodies. To assess whether this MIS-induced phenomenon in lung might be mediated by the MIS type II receptor (MIS RII), reverse transcriptase-PCR performed on multiple fetal rat lung RNA samples using oligonucleotide primers designed from the 3'-untranslated region of rat MIS RII complementary DNA showed a product of the expected size that when sequenced was nearly identical to rat MIS RII. Northern blot analysis using polyadenylated fetal rat lung RNA and a 3'-MIS RII probe revealed a 2-kilobase transcript that was also seen in testicular messenger RNA. These studies show that the putative ligand binding receptor for MIS is expressed in embryonic lung, where MIS negatively modulates branching and activates apoptosis. We speculate that the mechanism of MIS-induced inhibition of lung development in the male fetus begins with MIS binding to the MIS RII, followed by a signaling cascade resulting in delayed airway branching temporally associated with enhanced apoptosis.

Prenatal glucocorticoid therapy reverses pulmonary immaturity in congenital diaphragmatic hernia in fetal sheep.

OBJECTIVE: To assess the feasibility of conducting clinical trials of prenatal steroid therapy for congenital diaphragmatic hernia (CDH) in humans, the authors tested whether prenatal glucocorticoid, currently the standard treatment to minimize respiratory distress syndrome in premature infants, might improve the pulmonary immaturity in severe CDH in a large animal model. SUMMARY BACKGROUND DATA: The authors have used the nitrofen-induced rat model of CDH, which demonstrates immature lungs by biochemical, morphometric, and molecular biologic criteria. They also have shown that the lethally immature lungs of the full-term CDH rats can be improved by biochemical, morphometric, physiologic, and molecular criteria by treating the mothers with parenteral steroids at doses extrapolated from the current therapy used to accelerate lung development of premature human babies. METHODS: During a 3-year period in 88 fetal sheep, 1) left-sided diaphragmatic hernias were created surgically at varying gestational ages (day 78-90; term = 142-145 days) and size to maximize severity (n = 45), 2) placement and design of indwelling fetal intravenous catheters were optimized (n = 13), and 3) timing and dosage of cortisol administration were determined (n = 17). As a result, diaphragmatic hernias were created on day 80, intravenous catheters were placed on day 120, and twice-daily intravenous cortisol injections (n = 8) or saline as the control (n = 5) were administered (days 133-135). Lambs were delivered on day 136 via cesarean section to avoid steroid-induced abortion; vascular access was obtained, and the fetuses were ventilated at standard settings. Physiologic data were collected, and lungs were harvested for biochemical and histologic analysis. RESULTS: Significant improvements were measured in postductal arterial oxygen pressure ([PaO2] 38 +/- 6 mmHg after cortisol therapy compared with 20 +/- 3 mmHg for saline controls; p = 0.002) and in dynamic compliance (0.42 +/- 0.05 mL/cm H2O vs. 0.29 +/- 0.01 mL/cm H2O; p = 0.01). Lung glycogen levels in the right lung of the cortisol group were significantly better than controls (4.6 +/- 0.3 mg/g lung vs. 6.8 +/- 0.4 mg/g; p = 0.002), as were protein/DNA levels (8.3 +/- 0.9 mg/mg vs. 14.5 +/- mg/mg; p < 0.05). Striking morphologic maturation of airway architecture was observed in the treated lungs. CONCLUSIONS: Prenatal glucocorticoids correct the pulmonary immaturity of fetal sheep with CDH by physiologic, biochemical, and histologic criteria. These data, combined with previous small animal studies, have prompted the authors to initiate a prospective phase I/II clinical trial to examine the efficacy of prenatal glucocorticoids to improve the maturation of hypoplastic lungs associated with CDH.

Prenatal hormonal therapy improves pulmonary morphology in rats with congenital diaphragmatic hernia.

The high mortality of congenital diaphragmatic hernia (CDH) is due to associated pulmonary hypoplasia, which resembles that seen in premature newborns with respiratory distress syndrome (RDS). By use of successful therapies extrapolated from RDS, quantitative stereologic morphometry techniques were applied to evaluate pulmonary development following prenatal hormonal therapy in rats with nitrofen-induced CDH. Antenatal hormonal therapy was administered on Days 18.5 and 19.5 prior to delivery on Day 21.5 (term = Day 22), using dexamethasone (Dex), thyrotropin-releasing hormone (TRH), Dex-TRH, or normal saline (NS) as vehicle control. Lungs from CDH rats (n = 5) and non-nitrofen-fed controls (n = 5) were studied, and 10 morphometric airspace parameters were determined by point counting 18-30 fields/lung/animal. Indices of maturation, including total internal surface area (SA), airspace volume fractions (V(Valv)), duct fractions (V(Vducts)), and radial alveolar count (RAC), were improved by Dex and Dex-TRH compared with NS-CDH controls (P = 0.0001), as were five other morphometric airspace parameters (P < 0.05). Strikingly, Dex and Dex-TRH treatment corrected average airspace volume (AAV) and the volume fraction of air-conducting elements (V(Vducts)) toward normal values seen in non-nitrofen-fed control animals. TRH therapy alone had minimal beneficial effects. Prenatal steroid +/- TRH thus improved multiple morphometric parameters of lung maturity in CDH rats, supporting the potential use of in utero hormonal therapy to treat humans with antenatally diagnosed CDH.