Carboplatin, in the schedule used in this study, produced disease stabilization or improvement in a majority of children with progressive low-grade glioma, with manageable toxicity. Improved treatment strategies are particularly required for patients with diencephalic tumors.
Objectives: To describe the location of treatment, recruitment to clinical trials and outcomes for adolescents and young adults treated for cancer in Victoria. Design and setting: Retrospective review of all adolescents and young adults aged 10–24 years diagnosed with cancer between 1992 and 1996, identified from the Victorian Cancer Registry. Main outcome measures: Treatment regimen (clinical trial, treatment protocol or neither), compliance with treatment and 5‐year survival. Results: Questionnaires were completed for 576 of 665 eligible adolescents and young adults (87% response rate). Recruitment into clinical trials decreased with increasing age. Adolescents aged 10–19 years were more likely to be recruited to a clinical trial if treated at a paediatric hospital. For all cancers, 5‐year survival was similar across the age groups and was not influenced by the place of treatment. Only 1% of adolescents and young adults failed to complete planned therapy due to non‐compliance. Conclusions: Despite a similar incidence of cancer to that in younger children, adolescents and young adults with cancer are poorly recruited into clinical trials in Victoria. Establishment of a cancer resource network in Victoria may provide information to both paediatric and adult oncologists about currently available clinical trials.
Previous pharmacological studies have demonstrated that pulmonary endothelial cells and noradrenergic neurones possess the same transporter for inward transport of catecholamines, uptake1. In noradrenergic neurones, it has been shown that uptake1 is also involved in the carrier-mediated outward transport, or efflux, of noradrenaline and dopamine. The aim of the present study was to examine the efflux of noradrenaline and dopamine from perfused lungs of rats to determine whether uptake1, in addition to diffusion, mediates efflux of catecholamines from pulmonary vascular endothelial cells. The effects of reducing the cellular sodium gradient and of substrates and inhibitors of uptake1 on the efflux of 3H-noradrenaline and 3H-dopamine from rat lungs were measured. Isolated perfused lungs of rats (monoamine oxidase and catechol-O-methyltransferase inhibited) were loaded with 3H-(-)-noradrenaline or 3H-dopamine for 10 min followed by perfusion with either (1) a low sodium, amine-free Krebs solution, in which NaCl was replaced by either Tris.HCl or LiCl, for 15 or 10 min, respectively or (2) amine-free Krebs solution for 30 min in the absence or presence of a substrate or inhibitor of uptake1 for the last 15 min. The rate constants for spontaneous efflux of noradrenaline and dopamine from the lungs were 0.0163 min-1 and 0.0466 min-1, respectively. When NaCl was replaced by Tris.HCl during efflux, the rate constants for efflux of noradrenaline and dopamine were increased 2.5-fold and 3-fold, respectively, whereas, when NaCl was replaced by LiCl, the rate constants were increased 8-fold and 4-fold, respectively. The uptake1 substrates, dopamine (1 and 3 mumol/l) and adrenaline (40 mumol/l), both caused a rapid and marked increase in the efflux of noradrenaline, while noradrenaline (4 mumol/l) had a similar effect on the efflux of dopamine. The uptake1 inhibitors, imipramine (3 and 10 mumol/l) and nisoxetine (50 nmol/l), caused small and gradual increases in the efflux of noradrenaline and dopamine from rat lungs. These results demonstrate that efflux of noradrenaline and dopamine from rat lungs is affected by alterations in the normal sodium gradient across the cell and by drugs that interact with the uptake1 transporter. Thus, it can be concluded that the spontaneous efflux of catecholamines from pulmonary vascular endothelial cells is mediated predominantly by uptake1. In addition, efflux of catecholamines from the lungs has a diffusional component, which, combined with inhibition of reuptake, accounts for the small increase in amine efflux by inhibitors of uptake1.
The Wilms' tumor 1 gene, WT1, encodes a zinc-finger protein that is implicated in the development of Wilms' tumor. Mutant or aberrantly expressed WT1 isoforms have also been described in desmoplastic small round cell tumor, acute leukemias, mesothelioma, breast tumors and melanoma. During early development, WT1 is expressed in the brain and spinal cord, however its role in the malignancies that affect these tissues has not been previously investigated. In our study we have examined neural tumors including brain tumors and neuroblastomas for WT1 expression and for mutations affecting the zinc-fingers. Although WT1 expression was detected in gliomas, medulloblastomas and neuroblastomas, neither zinc-finger region mutations nor splicing anomalies affecting the KTS site were detected. We therefore conclude that WT1 does not play a significant role in the etiology of human neural tumors.
STIM1 (GOK) maps to a region of human Chromosome (Chr) 11p15.5 that is implicated in several embryonal tumors, and some evidence indicates that STIM1 may have a growth suppressor role in rhabdomyosarcoma. In this study we have mapped the murine homolog, Stim1, to the same position as Hbb on distal mouse Chr 7. This region is separated by 20 cM from the region of distal Chr 7 that contains Igf2, H19, and other imprinted genes. Using strain-specific polymorphisms, we have shown that Stim1 is expressed from both parental alleles in fetal and neonatal mouse tissues. Similar analyses of human Wilms' tumor and normal kidney tissues demonstrated biallelic expression of STIM1 in the majority of samples. These data demonstrate that Stim1 expression is not regulated by genomic imprinting in either mouse or human tissues. Thus, if STIM1 is a tumor suppressor at 11p15.5, loss of expression is not due to imprinting effects.
The aim of this study was to investigate the deamination of dopamine in the intact pulmonary circulation of isolated lungs of the rat. The first part of the study showed that dopamine is not converted to noradrenaline by dopamine-beta-hydroxylase (DBH) when dopamine is perfused through isolated lung preparations with monoamine oxidase (MAO) and catechol-O-methyltransferase (COMT) inhibited. Hence, it was not necessary to inhibit DBH in subsequent experiments. The metabolite profile for deamination of dopamine in the lungs was examined by determining whether MAO and semicarbazide-sensitive amine oxidases (SSAO) contribute to the deamination of dopamine (and noradrenaline), and by determining the activity of MAO (kMAO) for the metabolism of dopamine. Lungs were perfused with 1 nmol/l 3H-dopamine or 3H-noradrenaline with COMT inhibited and, in experiments to determine the contribution of SSAO to deamination, with MAO inhibited. Inhibition of MAO reduced the deamination of dopamine and noradrenaline by 99.8% and 98.6%, respectively, indicating that MAO, and not SSAO, was responsible for deamination of the catecholamines in the lungs. The kMAO value for deamination of dopamine was 3.89 min-1. Further experiments were carried out to determine the contributions of MAO-A and MAO-B to the deamination of dopamine in lungs perfused with 1 nmol/l 3H-dopamine and 100 nmol/l lazabemide or 300 nmol/l Ro41-1049, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)
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