Faranak Azarbayjani

The Anti-VEGF Antibody Bevacizumab Potently Reduces the Growth Rate of High-Risk Neuroblastoma Xenografts

Neuroblastoma (NB) is a rapidly growing, well-vascularized childhood cancer that often presents with metastases. The overall five-year survival in NB is approximately 45% despite multimodality treatment, and therefore there is a clinical need for new therapeutic strategies. NB frequently overexpresses the angiogenic factor VEGF (vascular endothelial growth factor). The aim of this study was to investigate the effect of bevacizumab (Avastin®, Genentech/Roche), a humanized anti-VEGF-A antibody, on NB growth in three different xenograft models, chosen to resemble high-risk NB. The human NB cell lines SK-N-AS, IMR-32 and SH-SY5Y, which are poorly differentiated and overexpress VEGF-A, were injected s.c. in immunodeficient mice. Bevacizumab was given intraperitoneally twice weekly at 5 mg/kg body weight, starting at a tumor volume of 0.3 mL. Bevacizumab significantly (p < 0.01–0.05) reduced NB growth in vivo without toxicity by causing a 30–63% reduction of angiogenesis, but had no effect on NB cell survival in vitro. Serum concentrations of VEGF-A increased two- to six-fold during bevacizumab therapy which did not result in faster tumor growth compared with control animals. Based on our experimental data we suggest consideration of bevacizumab in treatment of high-risk NB that does not respond to conventional therapy and that overexpresses VEGF.

Initiation of phenytoin teratogenesis: Pharmacologically induced embryonic bradycardia and arrhythmia resulting in hypoxia and possible free radical damage at reoxygenation

The aim of this study was to investigate if phenytoin has the capacity to induce embryonic hypoxia mediated via adverse effects on the embryonic heart. Mouse embryos of different strains (CD-1, C57B1/6J and A/J) as well as Sprague Dawley (SD) rat embryos were cultured in vitro (in 75-80% rat serum) by the whole embryo technique. Effects on the heart were examined on gestational day 10 for mouse embryos and days 11 and 13 for rat embryos. Phenytoin was dissolved in water to give concentrations of 50-800 microM. In the mouse embryo studies, phenytoin caused a concentration-dependent decrease in embryonic heart rate in all three strains, with a slight decrease at 100 microM (2-7%) and a more pronounced effect at 200 microM (approximately 20%). Temporary or permanent cardiac arrest occurred in 86% of the CD-1 embryos at 500 microM, in 67% of the C57B1/6JM at 400 microM, and in all A/J embryos at 300 microM. Arrhythmias was observed in 8% in CD-1 embryos at 200 microM, in 18% at 150 microM in C57B1/6J embryos, and in 67% of the A/J embryos at 100 microM (lowest tested concentrations where arrhythmias occurred). In rat embryos, a concentration-dependent decrease in heart rate was observed on both days 11 and 13 at similar concentrations as in the mouse embryo studies. In a separate experiment, the effects on the heart rate of free phenytoin (not serum protein bound) were examined in rat embryos cultured in serum-free medium. Already at 12 microM a significant decrease in heart rate was observed. Altogether, the results support the hypothesis that phenytoin teratogenicity is initiated by pharmacologically induced embryonic hypoxia. A genetic susceptibility to the adverse effects of phenytoin on the embryonic heart may be of importance to explain strain and species differences in phenytoin teratogenicity.

Pharmacologically induced embryonic dysrhythmia and episodes of hypoxia followed by reoxygenation: A common teratogenic mechanism for antiepileptic drugs?

Antiepileptic drugs (AEDs), such as phenytoin (PHT), carbamazepine (CBZ), trimethadione (TMD), and phenobarbital (PB), have all been associated with a similar pattern of malformations, as well as growth retardation and developmental delay. Valproic acid (VPA) has been associated with a different pattern of malformations. Recent studies suggest that PHTs fetal adverse effect is related to its membrane stabilizing pharmacological properties (blockage of voltage-dependent ion channels). During a restricted sensitive period, this results in induction of concentration-dependent bradyarrhythmia in the embryo and episodes of hypoxia/reoxygenation. The aim of this study was to compare the potential of PHT, CBZ, PB, TMD, and dimethadione (DMD; the active metabolite of TMD) to cause bradyarrhythmias. All of these AEDs exert mainly their pharmacological effect via blockage of ion channels. VPA and vigabatrin (VGB), which are pharmacologically active mainly by other mechanisms, were also tested. C57 Bl/6J mouse embryos were cultured in vitro on gestation day 10 in vitro (in 20% rat serum). The drugs were suspended in either water or dimethylsulfoxide and administered into the culture medium in increasing concentrations up to 20 times the human therapeutic plasma concentration. A scoring system was employed in order to rank the drugs based on their potential to cause bradycardia, ventricular arrhythmia, and cardiac arrest in relation to human therapeutic concentrations. Based on this system, the drugs were ranked as follows: DMD = PHT >> PB = CBZ > TMD = VPA >> VGB (no potential). The results correlate well with the available clinical/experimental data of the tested AEDs potential to induce hypoxia-related fetal adverse effects, such as oral clefts, distal limb defects, growth retardation, and developmental delay. The results support the idea that adverse fetal effects after in utero exposure to PHT, PB, CBZ, and TMD (via the active metabolite DMD) are initiated via a common pharmacological mechanism: blockage of ion channels in the developing heart in the early embryo resulting in bradyarrhythmias, hemodynamic alterations, and hypoxia/reoxygenation damage.

Embryonic arrhythmia by inhibition of HERG channels : a common hypoxia-related teratogenic mechanism for antiepileptic drugs?

Summary:  Purpose: There is evidence that drug‐induced embryonic arrhythmia initiates phenytoin (PHT) teratogenicity. The arrhythmia, which links to the potential of PHT to inhibit a specific potassium channel (Ikr), may result in episodes of embryonic ischemia and generation of reactive oxygen species (ROS) at reperfusion. This study sought to determine whether the proposed mechanism might be relevant for the teratogenic antiepileptic drug trimethadione (TMO).

Class III Antiarrhythmics and Phenytoin: Teratogenicity Due to Embryonic Cardiac Dysrhythmia and Reoxygenation Damage

Class III antiarrhythmic drugs, like almokalant, dofetilide and ibutilide, cause a spectrum of malformations in experimental teratology studies. The pattern of developmental toxic effects is very similar to those reported for phenytoin, which is an established human and animal teratogen. The toxic effects are characterised by embryonic death, decreased fetal weights, and stage specific malformations, such as distal digital reductions, orofacial clefts and cardiovascular defects. Class III antiarrhythmics decrease the excitability of cardiac cells by selectively blocking the rapid component of the delayed rectified potassium channel (IKr), resulting in prolongation of the repolarisation phase of the action potential. Phenytoin, which decrease the excitability of neurones, has recently also been shown to block IKr, in addition to its known blockade of sodium channels. Animal studies indicate that IKr is expressed in the embryo and that the embryonic heart is extremely susceptible to IKr-blockers during a restricted period in early development. At concentrations not affecting the maternal heart, the embryonic heart reacts with bradycardia, arrhythmia and cardiac arrest when exposed to such drugs. Available studies strongly support the idea that birth defects after in utero exposure to both selective and non-selective IKr-blockers (like phenytoin) are initiated by concentration dependent embryonic bradycardia/arrhythmia resulting in 1) hypoxia; explaining embryonic death and growth retardation, 2) episodes of severe hypoxia, followed by generation of reactive oxygen species within the embryo during reoxygenation, causing orofacial clefts and distal digital reductions, and 3) alterations in embryonic blood flow and blood pressure, inducing cardiovascular defects.

Metronomic administration of the drug GMX1777, a cellular NAD synthesis inhibitor, results in neuroblastoma regression and vessel maturation without inducing drug resistance

High‐risk neuroblastoma is a rapidly growing tumor with a survival rate below 50%. A new treatment strategy is to administer chemotherapeutic drugs metronomically, i.e., at lower doses and frequent intervals. The aim of the study was to investigate the effects of GMX1777, a chemotherapeutic drug affecting cellular energy metabolism, in a mouse model for high‐risk neuroblastoma. Female SCID mice were injected s.c. with MYCN‐amplified human neuroblastoma cells and randomized to either treatment with GMX1777 or vehicle. In some animals, treatment was discontinued allowing tumor relapse. Treatment response was evaluated using the pediatric preclinical testing program (PPTP). Immunohistochemistry and qRT‐PCR was performed on tumor cryosections to investigate the microscopic and molecular changes in tumors in response to GMX1777. Despite an increase in vessel density, tumor regression and a high group response score according to PPTP criteria was induced by GMX1777 without inducing drug resistance. Treatment resulted in inhibition of tumor cell proliferation, vessel maturation, reduced hypoxia, increased infiltration of MHC class II negative macrophages and expansion of the nonvascular stromal compartment. Decreased stromal VEGF‐A and PDGF‐B mRNA in response to treatment together with the structural data suggest a “deactivation” or “silencing” of the tumor stroma as a paracrine entity. In conclusion, GMX1777 was highly efficient against high‐risk neuroblastoma xenografts through modulation of both the tumor cell and stromal compartment.

Regression of orthotopic neuroblastoma in mice by targeting the endothelial and tumor cell compartments.

BackgroundHigh-risk neuroblastoma has an overall five-year survival of less than 40%, indicating a need for new treatment strategies such as angiogenesis inhibition. Recent studies have shown that chemotherapeutic drugs can inhibit angiogenesis if administered in a continuous schedule. The aim of this study was primarily to characterize tumor spread in an orthotopic, metastatic model for aggressive, MYCN-amplified neuroblastoma and secondarily to study the effects of daily administration of the chemotherapeutic agent CHS 828 on tumor angiogenesis, tumor growth, and spread.MethodsMYCN-amplified human neuroblastoma cells (IMR-32, 2 × 106) were injected into the left adrenal gland in SCID mice through a flank incision. Nine weeks later, a new laparotomy was performed to confirm tumor establishment and to estimate tumor volume. Animals were randomized to either treatment with CHS 828 (20 mg/kg/day; p.o.) or vehicle control. Differences between groups in tumor volume were analyzed by Mann-Whitney U test and in metastatic spread using Fishers exact test. Differences with p < 0.05 were considered statistically significant.ResultsThe orthotopic model resembled clinical neuroblastoma in respect to tumor site, growth and spread. Treatment with CHS 828 resulted in tumor regression (p < 0.001) and reduction in viable tumor fraction (p < 0.001) and metastatic spread (p < 0.05) in correlation with reduced plasma levels of the putative tumor marker chromogranin A (p < 0.001). These effects were due to increased tumor cell death and reduced angiogenesis. No treatment-related toxicities were observed.ConclusionThe metastatic animal model in this study resembled clinical neuroblastoma and is therefore clinically relevant for examining new treatment strategies for this malignancy. Our results indicate that daily scheduling of CHS 828 may be beneficial in treating patients with high-risk neuroblastoma.

Is the risk of narcolepsy also increased with non-adjuvanted flu vaccines?

In line with previous studies, Miller and colleagues find an increased risk of narcolepsy after vaccination with AS03 adjuvanted pandemic A/H1N1 2009 influenza vaccine (Pandemrix; odds ratio 16.2, 95% CI 3.1 to 84.5) and call for similar studies on other flu vaccines.1 Several flu vaccines are available in Europe, both adjuvanted and non-adjuvanted. All suspected adverse vaccine reactions must be reported to pan-European database EudraVigilance (www.adrreports.eu), which will soon be fully publicly accessible. The first suspected case of narcolepsy associated with a non-adjuvanted flu …