A comparison of targeting of neuroblastoma with mIBG and anti L1-CAM antibody mAb chCE7: therapeutic efficacy in a neuroblastoma xenograft model and imaging of neuroblastoma patients.

Iodine-131 labelled anti L1-CAM antibody mAb chCE7 was compared with the effective neuroblastoma-seeking agent 131I-labelled metaiodobenzylguanidine (MIBG) with regard to (a) its therapeutic efficacy in treating nude mice with neuroblastoma xenografts and (b) its tumour targeting ability in neuroblastoma patients. The SK-N-SH tumour cells used in the mouse experiments show good MIBG uptake and provide a relatively low number of 6,300 binding sites/cell for mAb chCE7. Tumours were treated with single injections of 131I-MIBG (110 MBq) and with 131I-labelled mAb chCE7 (17 MBq) and both agents showed antitumour activity. After therapy with 131I-chCE7, the subcutaneous tumours nearly disappeared; treatment with 131I-MIBG was somewhat less effective, resulting in a 70% reduction in tumour volume. A calculated tumour regrowth delay of 9 days occurred with a radioactivity dose of 17 MBq of an irrelevant control antibody mAb 35, which does not bind to SK-N-SH cells, compared with a regrowth delay of 34 days with 131I-mAb chCE7 and of 24 days with 131I-MIBG. General toxicity appeared to be mild, as assessed by a transient, approximate 10% maximum decrease in body weight during the treatments. The superior growth inhibition achieved by 131I-chCE7 compared with 131I-MIBG can be explained by its prolonged retention in the tumours, due to slower normal tissue and plasma clearance. Cross-reaction of mAb chCE7 with L1-CAM present in normal human tissues was investigated by direct binding of radioiodinated mAb to frozen tissue sections. Results showed a strong reaction with normal human brain tissue and weak but detectable binding to normal adult kidney sections. Seven patients with recurrent neuroblastoma were sequentially imaged with 131I-MIBG and 131I-chCE7. The results underlined the heterogeneity of neuroblastoma and showed the two imaging modalities to be complementary. 131I-chCE7 scintigraphy may have clinical utility in detecting metastases which do not accumulate 131I-MIBG, and the antibody may hold potential for radioimmunotherapy, either by itself or in combination with 131I-MIBG.

A comparison of targetting of neuroblastoma with mIBG and anti L1-CAM antibody mAb chCE7: therapeutic efficacy in a neuroblastoma xenograft model and imaging of neuroblastoma patients.

Iodine-131 labelled anti L1-CAM antibody mAb chCE7 was compared with the effective neuroblastoma-seeking agent (131)I-labelled metaiodobenzylguanidine (MIBG) with regard to (a) its therapeutic efficacy in treating nude mice with neuroblastoma xenografts and (b) its tumour targetting ability in neuroblastoma patients. The SK-N-SH tumour cells used in the mouse experiments show good MIBG uptake and provide a relatively low number of 6,300 binding sites/cell for mAb chCE7. Tumours were treated with single injections of (131)I-MIBG (110 MBq) and with (131)I-labelled mAb chCE7 (17 MBq) and both agents showed antitumour activity. After therapy with (131)I-chCE7, the subcutaneous tumours nearly disappeared; treatment with (131)I-MIBG was somewhat less effective, resulting in a 70% reduction in tumour volume. A calculated tumour regrowth delay of 9 days occurred with a radioactivity dose of 17 MBq of an irrelevant control antibody mAb 35, which does not bind to SK-N-SH cells, compared with a regrowth delay of 34 days with (131)I-mAb chCE7 and of 24 days with (131)I-MIBG. General toxicity appeared to be mild, as assessed by a transient, approximate 10% maximum decrease in body weight during the treatments. The superior growth inhibition achieved by (131)I-chCE7 compared with (131)I-MIBG can be explained by its prolonged retention in the tumours, due to slower normal tissue and plasma clearance. Cross-reaction of mAb chCE7 with L1-CAM present in normal human tissues was investigated by direct binding of radioiodinated mAb to frozen tissue sections. Results showed a strong reaction with normal human brain tissue and weak but detectable binding to normal adult kidney sections. Seven patients with recurrent neuroblastoma were sequentially imaged with (131)I-MIBG and (131)I-chCE7. The results underlined the heterogeneity of neuroblastoma and showed the two imaging modalities to be complementary. (131)I-chCE7 scintigraphy may have clinical utility in detecting metastases which do not accumulate (131)I-MIBG, and the antibody may hold potential for radioimmunotherapy, either by itself or in combination with (131)I-MIBG.

Targeting of meta-iodobenzylguanidine to SK-N-SH human neuroblastoma xenografts: tissue distribution, metabolism and therapeutic efficacy.

The clinical results of [(131)I]meta-iodobenzylguanidine (MIBG)-targeted radiotherapy in neuroblastoma patients is highly variable. To assess the therapeutic potential of [(131)I]MIBG, we used the SK-N-SH human neuroblastoma, xenografted in nude mice. The model was first characterized for basic parameters of MIBG handling in the host species. This demonstrated the presence of both strain- and nu/nu mutation-related differences in [(131)I]MIBG biodistribution. Fecal and urinary clearance rates of [(131)I]MIBG in mice roughly resemble those in humans, but mice metabolize MIBG more extensively. In both species, enzymatic deiodination in vivo was not an important metabolic route. Therapy with increasing [(131)I]MIBG doses (25-92 MBq) given as single i.v. injections resulted in proportionally increasing specific growth delay values (tumor regrowth delay/doubling time) of 1 to 5. Using gamma-camera scintigraphy for non-invasive dosimetry, the corresponding calculated absorbed tumor radiation doses ranged from 2 to 11 Gy. We also compared the therapeutic effects of a single [(131)I]MIBG administration with those resulting from a more protracted exposure by fractionating the dose in 2 to 6 injections or with high dose rate external-beam irradiation. No therapeutic advantage of a fractionated schedule was observed, and 5.5 Gy delivered by low dose-rate [(131)I]MIBG endo-irradiation was equi-effective with 5.0 Gy X-rays. The SK-N-SH neuroblastoma xenograft model thus appears suitable to evaluate possible treatment improvements to reach full potential of MIBG radiotherapy.

[(131)I] and [(125)I] metaiodobenzylguanidine therapy in macroscopic and microscopic tumors: a comparative study in SK-N-SH human neuroblastoma and PC12 rat pheochromocytoma xenografts.

[(131)I]Metaiodobenzylguanidine ([(131)I]MIBG) targeted radiotherapy is effective in debulking childhood neuroblastoma. The high-energy beta-emitter [(131)I]MIBG is, however, not very well suited to treat submillimeter tumors. The [(125)I]MIBG emission is more fully absorbed in small target volumes and therefore advocated for treatment of microscopic neuroblastoma. We investigated whether i.v. [(125)I]MIBG can have a therapeutic advantage over i.v. [(131)I]MIBG in realistic animal models. We used BALB/c nu/nu mice, bearing neuroadrenergic xenografts which differ in MIBG handling, i.e., extragranular vs. granular MIBG storage in the SK-N-SH human neuroblastoma and PC12 rat pheochromocytoma, respectively. Groups of 4-9 animals were treated with 10-100 MBq radioiodinated MIBG. Responses were calibrated against the effect of 4-5 Gy of external beam X-rays. SUBCUTANEOUS XENOGRAFTS: Due to the more extensive MIBG accumulation, the estimated MIBG exposure of the PC12 tumor was nearly 20-fold higher compared with the SK-N-SH xenograft which corresponded with a marked, i.e., nine-fold increased tumor growth delay after radioiodinated MIBG therapy. Both xenografts were equally sensitive to high-dose rate local irradiation. In neuroblastoma as well as pheochromocytoma, the therapeutic efficacy of [(131)I]MIBG was 6 times higher compared to the [(125)I]MIBG which is in reasonable agreement with the reported "131-I over 125-I" ratio of approximately 9 for the calculated absorbed radiation doses per unit of radioactivity. Apparently, the neuroblastoma was not relatively more sensitive to the (ultra)short range emitter [(125)I]MIBG than the pheochromocytoma, indicating that its therapeutic efficacy is independent of the intracellular MIBG storage mode. MICROSCOPIC TUMORS: The pheochromocytoma model consisted of widespread disease after i.v. cell injection with survival as endpoint. For the neuroblastoma, we induced focal intrahepatic microscopic tumors by intrasplenic injection and evaluated total liver weights 26 days after therapy. Theoretically, the therapeutic potential of [(125)I]MIBG at the cellular level should be at least as high as [(131)I]MIBG, but we failed to show any effect of [(125)I]MIBG therapy in both models. In contrast, measurable responses were obtained with [(131)I]MIBG, but these were lower than in the s.c. tumors when related to the responses induced by external X-rays. In conclusion, [(131)I]MIBG is decreasingly effective in microscopic disease and can therefore not be curative as a single agent. Our results strongly argue against the clinical use of [(125)I]MIBG and indicate that conventional total body irradiation was superior to [(131)I]MIBG for microscopic neuroblastoma. Int. J. Cancer (Radiat. Oncol. Invest.) 90, 312-325 (2000).

Mutational analysis of Bax and Bcl-2 in childhood acute lymphoblastic leukaemia.

In childhood acute lymphoblastic leukaemia there are large interpatient variations in levels of the apoptosis-regulating proteins Bax and Bcl-2, but the molecular basis for this variation is unknown. Point-mutations in bax have been reported in cell lines derived from haematological malignancies. Frameshift mutations, which result in reduced Bax levels, have also been found in colon cancer of the microsatellite mutator phenotype. Bcl-2 overexpression, or gain of function mutations in the open reading frame (ORF) or in the translational repressor, the upstream ORF(uORF) of bcl-2, might also be important in deregulating its function or expression. We have therefore analyzed 21 bone marrow aspirates from untreated childhood acute lymphoblastic leukaemia and 2 from myeloid leukaemia for mutations in box and bcl-2. DNA sequence analysis of the ORFs of bax and bcl-2 and of the uORF of bcl-2 revealed no mutations, despite the large range in expression levels. Thus, mutations within the (u)ORFs of bax and bcl-2 that (in)activate or deregulate Bax and Bcl-2 are infrequent in primary childhood acute leukaemia and do not play a major role in regulation of the encoded proteins in this disease.

In vitro evaluation of N-(fluoro)isopropyl norephedrine as potential cardiac imaging agents for PET.

N-Isopropylnorephedrine (INE) and N-fluoroisopropylnorephedrine (FINE) were found to have a poor affinity for either beta-adrenoceptors and the norepinephrine carrier protein. The low affinity of both compounds for Uptake-1 is probably due to the introduction of a bulky substituent on the nitrogen atom. It is concluded that INE and FINE cannot be used for cardiac imaging with PET.