Pediatric chordoid glioma with chondroid metaplasia.

Chordoid gliomas are uncommon primary brain tumors that arise in the region of the third ventricle. Reports of this entity to date have been limited to adults. We present a case of a chordoid glioma arising in the hypothalamic/third ventricle region of a 12-year-old male who presented with visual symptoms. The neoplasm consisted of cords and clusters of well-differentiated, spindled-to-rounded cells containing abundant eosinophilic cytoplasm within a prominent mucinous matrix. Unlike other chordoid gliomas, this lesion contained islands and sheets showing cartilaginous differentiation intermixed with the glial component. A graded transition between neoplastic glial and chondroid regions was evident, and cells in both regions were strongly immunoreactive for GFAP and S-100. Cartilaginous metaplasia is infrequent in gliomas, but occurs most often in pediatric neoplasms of the midline such as this chordoid glioma. Thus, chondroid metaplasia represents an unusual histopathologic feature of chordoid glioma-in this case, presenting in a child.

Neonatal brain tumors: a review.

This article presents two cases of infants with brain tumors and reviews the literature pertinent to congenital and neonatal brain tumors. Information regarding epidemiology, presentation, prognosis, and clinical management are also addressed with specific regard to differences between neonatal and childhood brain tumors. An appeal is made to consider (1) coordination of the care of these children through pediatric multidisciplinary neuro-oncology programs; (2) enrollment, whenever possible, in clinical trials; and (3) submission of available tumor tissue to pediatric tumor banks to assure its availability to interested researchers.

Karyotype studies in 18 ependymomas with literature review of 107 cases.

Cytogenetic studies from 17 pediatric ependymomas and 1 ependymoblastoma are presented. Eight tumors had abnormal karyotypes. Another 107 published cases of cytogenetic analyses from pediatric and adult ependymomas or ependymoblastomas were reviewed. Of the total 125 tumors, 83 (66%) had abnormal karyotypes, of which 24 had a sole autosomal abnormality. Approximately one third had monosomy 22 (-22) or breakpoint 22q11-13, with a higher incidence in adult (56%) versus pediatric (28%) tumors. Structural abnormalities of chromosomes 1, 6, and 17, and numerical abnormalities of 7, 9, 12, and 20, in particular, are also discussed. Although no primary cytogenetic abnormality is evident, these findings may provide direction for additional investigations regarding the classification of these tumors.

Chromosome analyses in a rhabdoid tumor of the brain.

A malignant rhabdoid tumor of the brain from a 19-month-old child was studied. Two related clones, 46,XX,-8,+der(8)t(8;22)(p11;q?12)x2,-22,del(22)(q12q?13) and 46,XX-8,+der(8)t(8;22) (p11;q?12) x2,-22,r(22) were found after chromosome analyses of primary and recurrent tumor, and multiple nude mouse passages of the tumor. Breakpoints were studied using FISH.

Trilateral retinoblastoma with suprasellar involvement.

"Trilateral retinoblastoma" (TRB) is the association of a midline intracranial tumor with familial bilateral retinoblastoma. Classically, the intracranial tumor is a pineal region tumor (pineoblastoma) with histology similar to retinoblastoma. We present a 7-month-old child with bilateral orbital retinoblastoma with a third tumor arising in the chiasmatic cistern. The presentation and prognosis of patients with this association differ from those children with "classical" TRB. The presentation, treatment, and outcome are described, with a review of the literature.

Contribution of in vivo proliferation/differentiation studies toward the development of a combined functional and morphologic system of classification of neoplastic diseases.

Proliferation kinetics of both leukemia and a variety of solid tumors have been assessed after in vivo infusions of the thymidine analogues, iododeoxyuridine (IUdR) and bromodeoxyuridine (BrdU). In acute myeloid leukemia (AML), these data indicate that the pretherapy cell cycle time (Tc) of myeloblasts is a prognostic indicator for remission duration since patients with slowly cycling myeloblasts had more durable remissions. The presence of in vivo differentiation detected from the day 7 biopsy after chemotherapy was also of favorable prognosis as these individuals had statistically significant improvement in their remission duration. The data in solid tumors are not mature enough for determining their clinical significance. Since cell kinetic information is readily available in a prompt fashion using these novel techniques, data can be used to plan therapeutic strategies for patients. This review discusses the state-of-the-art techniques available for cell cycle kinetic studies and the clinical and prognostic utility of data that have been generated thus far.

Cell cycle kinetic studies in human cancers. Development of three DNA-specific labels in three decades.

Controversy has epitomized the prognostic and clinical significance accorded to cell cycle kinetic studies in neoplastic diseases. Recent introduction of monoclonal antibodies to thymidine analogues such as iododeoxyuridine and bromodeoxyuridine has unveiled a spectacular new area of research. Large numbers of patients with liquid and solid tumors have been interrogated by introducing iododeoxyuridine and bromodeoxyuridine as DNA-specific probes in vivo. Further in vitro incubation of S-phase cells already double-labeled in vivo with tritiated thymidine has added a whole new dimension to the kinds of questions that can now be addressed with alacrity. Time is rapidly approaching when this information will be available in a prompt enough fashion to be useful for planning therapeutic strategies. Reviewed are the salient features of the rapid progress achieved in the last decade in this exciting discipline.

Comparison of two double labeling techniques to measure cell cycle kinetics in myeloid leukemias.

Five patients with acute myeloid leukemia (AML) received a one hour infusion of iododeoxyuridine (IUdR) 100 mg/M2 to label S-phase cells in vivo. The aspirate was labeled in vitro either with tritiated thymidine (3HTdr) or bromodeoxyuridine (BrdU) to measure the duration of S-phase (Ts). The mean Ts using 3HTdr (Ts1) was 15.9h (13.1-19.8h) and using BrdU (Ts2) was 17.1h (14.5-20.6h). Total cell cycle time (Tc) ranged between 44.7h to 158.8h using Ts1 and 54.0h to 170.5h using Ts2. Based on this close approximation between the results, we confirm the reliability of the newly developed method that relies purely on immunohistochemical reaction.

Simultaneous immunohistochemical detection of IUdR and BrdU infused intravenously to cancer patients.

Cell cycle kinetics of solid tumors in the past have been restricted to an in vitro labeling index (LI) measurement. Two thymidine analogues, bromodeoxyuridine (BrdU) and iododeoxyuridine (IUdR), can be used to label S-phase cells in vivo because they can be detected in situ by use of monoclonal antibodies (MAb) against BrdU (Br-3) or IUdR (3D9). Patients with a variety of solid tumors (lymphoma, brain, colon cancers) received sequential intravenous IUdR and BrdU. Tumor tissue removed at the end of infusion was embedded in plastic and treated with MAb Br-3 and 3D9 sequentially, using a modification of a previously described method. Clearly single and double labeled cells were visible, which enabled us to determine the duration of S-phase (Ts) and the total cell cycle time (Tc), in addition to the LI in these tumors. Detailed control experiments using tissue culture cell lines as well as bone marrow cells from leukemic patients are described, including the comparison of this double label technique with our previously described BrdU-tritiated thymidine technique. We conclude that the two methods are comparable and that the IUdR/BrdU method permits rapid and reliable cell cycle measurements in solid tumors.

Observations regarding DNA replication sites in human cells in vivo following infusions of iododeoxyuridine and bromodeoxyuridine.

In studies using bromodeoxyuridine (BrdUrd) and/or iododeoxyuridine (IdUrd) to label S phase cells in cancer patients, several unique observations were made regarding DNA replication sites and the organization of newly synthesized DNA in post-mitotic cells. While the majority of tumour specimens removed at the end of infusions demonstrated concentration of replication sites around the nuclear membrane, biopsies obtained in leukaemic patients 1 week later demonstrated several distinct patterns of labelling. For example, one, two or all lobes of granulocytes were labelled. Scavenger macrophages bearing labelled leukaemic cells in their cytoplasm were also seen. Sequential IdUrd/BrdUrd labelling of solid tumours showed various patterns of nuclear/nucleolar/membrane labelling, allowing more precise localization of early versus late replication sites.