Malignancies in Down syndrome.

Down Syndrome (DS) is associated with an increased incidence of malignancies, especially leukaemias. We came across 8 DS children presenting with malignancies and having trisomy 21 as the sole cytogenetic abnormality. Of these 8 DS cases, 4 presented with acute lymphocytic leukaemia, 2 with acute myeloid leukaemia and one case each with Hodgkin's disease and Wilms' tumour. There are contradictory reports regarding the distribution of myeloid versus lymphoid malignancies in DS children and their response to therapy. The exact mechanism by which patients with DS are predisposed to develop malignancies is unclear. However, presence of the extra chromosome no. 21 is presumed to disrupt the genetic balance which increases generalized susceptibility to genetic and environmental trauma. Furthermore, an increased methotrexate toxicity observed in these patients should also be taken into consideration in designing treatment for DS children with malignancies.

Psychosocial adjustment and the role of functional status for children with asthma.

This study examined the psychosocial adjustment of children with asthma compared to children with diabetes, with cancer, and healthy children and the role of functional status in psychosocial adjustment. The total sample included 100 children, aged 8-16 years, (mean = 11.5 years), consisting of 48 boys and 52 girls. Children with asthma scored significantly higher on measures of affective adjustment (depression and internalizing behavior), significantly lower on self-esteem, and evidenced significantly greater functional impairment. Children with cancer missed significantly more school days. After controlling for functional status, no significant differences remained in affective adjustment but absences remained significantly higher for the children with cancer.

Bone marrow transplantation.

Bone marrow transplantations have a definite role in treatment of leukemias and lymphomas. In acute myeloid leukemia and CML an allogeneic transplant using an HLA identical donor certainly provides a far superior survival than chemotherapy. Patients with Ph' chromosome need to be transplanted in first remission if a suitable donor is available. In recurrent lymphomas the best results are achieved if the patient is transplanted in complete remission. Transplantation done using minor mismatched family donors or unrelated donors are still considered experimental and more data is needed before final recommendations can be made. Availability of supportive services is an absolute must prior to establishing transplant program. Selection of patients for transplantation should be done after carefully reviewing the indications and discussing with the family the emotional, financial and physical burden of the procedure. For selected indications in leukemias and lymphomas, BMT may be the only viable treatment option and therefore must be considered.

Ceftazidime versus ceftazidime plus tobramycin in febrile neutropenic children.

Although the effectiveness of antibiotic monotherapy in febrile neutropenic patients remains unproven, ceftazidime has been shown previously to be effective monotherapy for the empiric treatment of selective patients. The efficacy and safety of ceftazidime versus ceftazidime plus tobramycin was evaluated in the treatment of febrile children (range 8 months to 18 years) with neutropenia secondary to cancer chemotherapeutic agents. Of the evaluable 89 patients, 45 received ceftazidime and 44 received ceftazidime plus tobramycin for 5 to 10 days. At the end of therapy, 30 (67%) of the 45 ceftazidime-treated patients were clinically cured compared with 38 (86%) of 44 combination-treated patients. Thirteen (29%) of the patients treated with ceftazidime failed to respond clinically to treatment, versus four (9%) of the patients treated with ceftazidime/tobramycin (p = 0.046). This study suggests that ceftazidime as monotherapy in febrile neutropenic children may be inferior to combination therapy for optimal clinical response in these patients.

Oncogenes: present status.

Oncogenes are genes associated with causation of cancer. They were originally associated with the ability of retroviruses to cause tumors in animals. These viral oncogenes (V-onc) have their cellular counterparts (C-onc) called Proto oncogenes. Function of Proto oncogenes is to maintain cellular growth and development. Activation of these proto-oncogenes can occur due to mutation which leads to uncontrolled cell growth. The Proto oncogenes can be grouped into different categories based on their protein products, i.e. protein kinases, growth factors, growth factor receptors, and DNA binding proteins. There are also genes that normally suppress malignant transformation and these are called anti oncogenes. Loss of their suppressor activity leads to unimpeded growth. Oncogene abnormalities are seen in pediatric leukemias, lymphomas, and various solid tumors. Anti oncogenes are associated with retinoblastoma (Rb gene), Wilms' tumor, rhabdomyosarcoma and neuroblastoma, etc. Identification of these abnormalities have diagnostic, prognostic and therapeutic implications. The utility of oncogenes in classification of human cancer and monitoring cancer therapy is quite clear, but the future of these for therapeutic interventions remains uncertain. Role of c-abl oncogene in chronic myeloid leukemia (CML), bcl-2, in lymphomas, N-myc in neuroblastomas and retinoblastoma (Rb) gene in retinoblastomas is well understood and used in designing proper therapeutic approaches. Since oncogenes also control normal cellular function, their use for therapy may be limited by the amount of damage to normal cells. Their maximum therapeutic benefit may be realized only when used in combination with other modalities.

A phase I/II study of the use of Fluosol as an adjuvant to radiation therapy in the treatment of primary high-grade brain tumors.

The main objective of this study was to evaluate the safety and efficacy of a perfluorochemical emulsion, Fluosol, with short-term high inspired oxygen tension as an adjuvant to radiation therapy in the treatment of high-grade tumors of the brain. Radiation was delivered to the whole brain at 1.8 Gy per daily treatment for 5 weeks to a total dose of 45 Gy. The radiation portals were then reduced in size to encompass the known volume of tumor, as determined by the presurgical contrast-enhancing ring on computed tomography (CT), plus a 3-cm margin. An additional 10 treatments of 2 Gy each were given to the smaller volume, to bring the total tumor dose to 65 Gy in 7 weeks. This report describes the experience of the first 18 patients treated at the University of Kansas Medical Center on this study, whose median follow-up time from the date of surgery is 77 weeks (62-115 w). Immediately following Fluosol administration on a Monday, patients breathed 100% oxygen for at least 45 minutes prior to and throughout their radiation treatment. On each subsequent day of the weeks in which they received Fluosol, patients breathed 100% oxygen. Hematology and blood chemistries were also drawn prior to Fluosol treatment each Friday during treatment and at the 2-week, 3-month, and 6-month follow-up visits. The median age of the patients was 45 years (16-72); 13 patients were male and 15 carried the diagnosis of glioblastoma multiforme (3 had anaplastic astrocytoma). Two thirds of the patients had an initial allergic reaction to the Fluosol consisting of back pain, shortness of breath, and flushing, but all responded to 50-100 mg of Benadryl. During radiation therapy, all patients developed scalp erythema and complete alopecia by the end of 3 weeks, but no patient required a treatment rest. The serum levels of SGOT, SGPT, and alkaline phosphatase were examined before and throughout the Fluosol treatment and, by week 5, 11/18 of the patients had increased values of all three enzymes above the upper range of normal. These increases persisted through the end of treatment, but most values returned to essentially normal by the 3-month follow-up visit. We conclude that Fluosol, given in the manner described above, appears to be associated with minimal significant side effects and no changes could be detected in the white matter of any of the patients at the time of their magnetic resonance imaging study at 6 months follow-up.(ABSTRACT TRUNCATED AT 400 WORDS)

Combination of radiation therapy and intracranial bleomycin in the 9L rat brain tumor model.

The rat 9L brain tumor model was used to investigate the therapeutic potential of a combined modality approach using intracranial Bleomycin and radiation therapy. Bolus Bleomycin was delivered intracranially into the tumor volume via cannula guides; for continuous infusions, osmotic mini-pumps were implanted subcutaneously between the scapulae with flexible tubing to deliver the drug directly into the tumor and brain. Two to six bolus injections of Bleomycin (1 unit/kg each) over 5-11 days produced modest (usually statistically significant, p less than 0.05) increases in the median survival time compared to controls. Continuous infusion of Bleomycin by osmotic pump (10 units/kg over 7 days or 15 units/kg over 14 days) was also effective at significantly increasing median survival times compared to that of controls. Radiation therapy schedules of 10 daily fractions in 12 days (2 weeks) or 10 twice-daily fractions in 5 days produced dose-dependent increases in median survival time. Multiple bolus injections of Bleomycin when combined with fractionated radiation therapy significantly increased the median survival time due to fractionated radiation therapy alone for low doses (40 or 50 Gy). However, at higher radiation doses, the addition of Bleomycin either had no effect on median survival time or actually shortened it. Continuous infusion of Bleomycin by osmotic pump was effective when added to low dose radiation therapy in several experiments, twice for a total radiation dose of 50 Gy and once for radiation therapy of 60 Gy. However, it was also observed (once for 60 Gy and twice for 70 Gy) that the addition of continuous infusion Bleomycin either had no effect or served to decrease the improvement of median survival time obtained by radiation therapy alone. Thus, we conclude that increases in normal tissue toxicity can prevent full attainment of improved therapeutic advantage from the addition of Bleomycin to fractionated radiation therapy in the rat 9L model. These results should be considered when attempts are made to combine radiation therapy and intracranial Bleomycin for the treatment of patients with primary malignant brain tumors.

Effect of spirogermanium and radiation therapy on the 9L rat brain tumor model.

Spirogermanium (SPG) was investigated in the 9L rat brain tumor model in vivo and in vitro. Used at a single ip dose of 50 or 60 mg/kg or at 5 daily doses of 10 mg/kg, SPG was ineffective in prolonging survival of rats burdened with the intracerebrally implanted tumor, i.e., the median survival time (MST) was the same as that for the controls. Only a schedule of 3 X 20 mg SPG/kg every other day improved the MST compared with controls. Single-dose (20-Gy) radiation therapy (RT, cesium-137 whole-head irradiation) did prolong survival. However, when single-dose SPG was combined with RT (1 hr or 1 day before, or 1 hr after RT), the survival response was worse than after RT alone. When the daily SPG was combined with daily RT (5 doses of 6 Gy), survival was no better than after daily RT alone. In vitro, SPG produces a concentration-dependent, exponential decrease in cell survival as measured by colony formation assay. When combined with radiation, there is an additive effect on cell lethality. Aside from the possibility that SPG does not penetrate the rat brain tumor itself, we have no explanation why SPG shows some activity against human brain tumors and is cytotoxic against 9L cells in vitro, yet is both ineffective by itself and fails to potentiate RT in the 9L rat brain tumor model.

Potentiation of rat brain tumor therapy by fluosol and carbogen.

We have been using the 9L rat brain tumor model to investigate the effect of the combination of a perfluorochemical emulsion, Fluosol-DA 20%, and carbogen breathing on the therapy of brain tumors. The combination of Fluosol, carbogen breathing, and carmustine (BCNU) was more effective at prolonging survival than was BCNU alone. This difference was small but significant (P less than 0.25). neither Fluosol without carbogen nor carbogen without Fluosol significantly altered the effect of BCNU. Fluosol and carbogen alone did not affect the survival of tumor-burdened rats. Fluosol and carbogen breathing did not alter the effect of single doses of radiation on these tumors. This result supports the hypothesis that 9L brain tumors contain few, if any, critical hypoxic cells. However, these tumors may contain cells which are oxygen deficient but not radiobiologically hypoxic. The Fluosol-carbogen combination may be changing the intratumor environment in such a way that the metabolism or activity of BCNU is altered.

Intraperitoneal bleomycin for ventriculoperitoneal spread of a hypothalamic astrocytoma.

A pediatric patient is presented in whom malignant ascites developed after ventriculoperitoneal shunt placement for a suprasellar astrocytoma. Paracentesis followed by intraperitoneal bleomycin resulted in decreased fluid re-accumulation with minimal side effects. A review of the literature shows that intracavitary chemotherapy, including bleomycin, can result in safe, effective relief of malignant effusion associated with adult tumors. We have demonstrated that such treatment is also applicable to the pediatric population. In this case, the effectiveness of intracavitary bleomycin may be related to its direct action against brain glioma cells. The need for effective treatment of malignant effusions in pediatric patients is growing because of their increased survival time with tumor. We propose that intracavitary bleomycin may provide relief from this potential complication of childhood solid tumors.

Mitoxantrone in refractory acute leukemia in children: a phase I study.

Nine children with acute non-lymphocytic leukemia (ANLL), ages 16 months to 16 years (median 7 years), and 15 children with acute lymphocytic leukemia (ALL), ages 10 months to 18 years (median 5 years), were treated with 5-day courses of mitoxantrone (Novantrone; dihydroxyanthracenedione) as induction therapy. All the children had leukemia which was resistant to conventional therapy and all but one patient had received anthracycline therapy prior to the initiation of this trial. Three patients (two with ANLL, one with ALL) received the drug at a dose of 6 mg/m2/day i.v. for 5 days. Both patients with ANLL achieved partial remissions (PR) (105 and 87 days duration). The child with ALL failed to respond to two courses of the drug, and died of progressive disease 45 days after the institution of therapy. Twenty-one patients (14 with ALL, seven with ANLL) were treated with 8 mg/m2/day i.v. mitoxantrone for 5 days. There were three early deaths (all ALL) which were not felt to be secondary to drug toxicity. Four of the 18 children achieved complete remission (CR) (one ANLL - 35 days; three ALL - 39, 31 and 13 days). One child with ANLL achieved a PR (13 days) and one child with ALL showed improvement in his bone marrow status. Twelve children failed to respond to this therapy. Dose-limiting toxicity was not seen among the patients who received 6 mg/m2/day for 5 days. There were five patients who had mucositis and one patient who had nausea and vomiting among those patients who received 8 mg/m2/day for 5 days.(ABSTRACT TRUNCATED AT 250 WORDS)

Management of children with isolated testicular leukemia.

Since 1975, nine children with testicular leukemia were treated at the University of Kansas Medical Center on a standard protocol. Six patients presented with overt testicular leukemia and three patients had microscopic testicular leukemia detected on a biopsy done after 3 years of continuous complete remission. All patients had an M1 bone marrow at the time of testicular relapse and one patient had a concomitant central nervous system (CNS) relapse. Therapy consisted of testicular irradiation, CNS chemoprophylaxis, and systemic reinduction chemotherapy. Systemic maintenance therapy after the testicular relapse consisted of 6-mercaptopurine and methotrexate with vincristine/prednisone pulses administered in the same basic dose and schedule as the patient's original maintenance regimen. These nine patients had a mean duration of first remission of 33 months and a mean duration of second remission of 45+ months. Four patients have relapsed (two bone marrow, one CNS, one CNS + bone marrow), but five patients remain in their second complete remission for 33+ to 94+ months from the time of testicular relapse. These results demonstrate that, in some children, testicular leukemia represents a site of temporary drug resistance and long-term second remissions can be obtained (once local disease is controlled) by using the initial maintenance chemotherapy regimen.

Development of normal tissue damage in the rat subsequent to thoracic irradiation and prior treatment with cancer chemotherapeutic agents.

The effect of combined modalities (radiotherapy-chemotherapy) on the development of long-term normal tissue damage was investigated in rats. Animals received single I.P. injections of Hank's balanced saline solution, adriamycin (ADR, 1.0 mg/kg), bleomycin (BLM, 10 units/kg), or dihydroxyanthraquinone (DHAQ, 3.0 mg/kg); and/or irradiation of the chest with 25 MV x-rays (12 Gy) at 0, 43, 93, or 199 days after drug treatment. Only animals treated with DHAQ displayed appreciable toxicity, with more animals dying at less than 200 days when radiation was added at 0 or 43 days. Although animals treated with BLM or radiation exhibited evidence of lung damage (histologically by 199 days and radiographically by 300 days), their survival was not compromised. The simultaneous administration of x-ray and BLM produced enhanced effects as compared to either agent alone. These results demonstrate an enhancement of normal tissue damage by combined treatment with radiation and chemotherapeutic agents, not only for acute toxicity but also for long-term effects. This damage was ultimately expressed as alteration of lung structure (histologically and radiographically) in the case of BLM, and as animal lethality in the case of DHAQ. In addition, there was a reduction in the degree of enhancement observed as a function of the separation in time between treatment with chemotherapeutic agents and subsequent irradiation. These factors should be considered when combined modality therapy is used for treatment of cancer in the thoracic region.