131I]metaiodobenzylguanidine therapy in advanced neuroblastoma.

Forty-two children with advanced neuroblastoma who either failed with first-line therapy or relapsed after achieving a complete remission, were considered for treatment with [131I]metaiodobenzylguanidine (131I-MIBG). We subdivided 42 cases into 5 groups, in accordance with the stage of disease at diagnosis, response to first-line therapy and relapse. A total of 99 courses of 131I-MIBG were administered with doses ranging from 2.8 to 6.0 GBq. One child received six courses, 3 four courses, 18 three courses, 6 two courses and 15 one course of 131I-MIBG. The total delivered dose in single measurable lesions ranged from 286 to 1691 cGy with an uptake factor ranging from 3% to 10%. We obtained a major response in primary tumors, and a long-term response was observed in 5 cases, lasting more than 2 years without further chemotherapy.     

131I]metaiodobenzylguanidine therapy after conventional therapy for neuroblastoma.

[131I]Metaiodobenzylguanidine (131I-MIBG) is used for diagnostic scintigraphy and targeted therapy in a range of neural crest tumors, which exhibit an active uptake-1 mechanism at the cell membrane and cytoplasmatic storage in neurosecretory granules. A good and selective concentration and a long retention in the tumor, as is generally the case in neuroblastoma, are the basis for successful 131I-MIBG treatment. At The Netherlands Cancer Institute a phase II study was carried out in 53 patients with progressive recurrent disease after conventional therapy had failed. Despite the unfavorable basis for treatment, 131I-MIBG therapy induced 7 complete remissions, 23 partial remissions and arrest of disease (no change) in 10. Nine patients had progressive disease and one patient was lost to follow-up. The palliative effect of the treatment under these conditions was impressive. The duration of remissions varied from 2 to 38 months. The best results were obtained in patients with voluminous soft tissue disease. In general the treatment was well tolerated by children and the toxicity was mild, provided the bone marrow was not invaded by the disease. It is concluded that 131I-MIBG therapy has a definitive place in the treatment of neuroblastoma after conventional treatment has failed. As the invasiveness and toxicity of this therapy compare favorably with that of chemotherapy, immunotherapy and external beam radiotherapy, 131I-MIBG therapy is the best palliative treatment for patients with advanced recurrent neuroblastoma.     

Preoperative [131I]metaiodobenzylguanidine therapy of neuroblastoma at diagnosis ("MIBG de novo").

The observed response of [131I]metaiodobenzylguanidine (131I-MIBG) therapy in advanced neuroblastoma after conventional therapy had failed, the noninvasiveness of the procedure, and the high metabolic activity of untreated tumors led to a new protocol to use 131I-MIBG therapy in newly diagnosed patients instead of combination chemotherapy prior to surgery. The objectives of this study are to improve the overall outcome of patients with neuroblastoma by introducing 131I-MIBG therapy as the first therapy in the treatment schedule, in order to reduce the tumor volume, enabling adequate surgical resection and avoiding toxicity and the induction of early drug resistance. The advantages of this approach are that the child's general condition is unaffected before surgical resection is performed and that chemotherapy is reserved to treat minimal residual disease. So far, 13 patients with inoperable neuroblastoma (stage III and IV) were treated with 131I-MIBG initially and then submitted to surgery. More than 50% decrease of the volume of the primary tumor was noted in 7 of 10 evaluable patients; 8 patients have so far been operated with complete resection in 2, greater than 95% resection in 5 and 80% resection in one patient. Three patients are still undergoing 131I-MIBG treatment. The toxicity of 131I-MIBG de novo is in contrast with the previous experience of 131I-MIBG therapy after conventional therapy: only 4 patients had thrombocytopenia and only 1 of 7 patients with bone marrow involvement developed bone marrow depression.(ABSTRACT TRUNCATED AT 250 WORDS)     

Experience with palliative [131I]metaiodobenzylguanidine therapy in advanced neuroblastoma.

Our experience with palliative [131I]metabenzylguanidine (131I-MIBG) therapy in 7 patients (6 children and 1 adult) affected by advanced neuroblastoma is reported. All patients (classified as IV stage) showed a progression following initial intensive therapy, including chemotherapy and, in some cases, hemi-body irradiation and surgery for their primary tumor. 131I-MIBG activity ranged for a single course between 2.77 GBq to 5.55 GBq on the basis of age, intensity of uptake, and the hematological assessment. Four patients received only one course of therapy due to progressive disease (2), early death (1) or persistent thrombocytopenia unrelated to 131I-MIBG therapy (1). Two patients received two courses and showed a partial response lasting 4 months and stable disease lasting 3 months respectively. Therapy was thereafter discontinued due to progression. One patient received 4 courses of therapy (cumulative activity = 19.61 GBq) in 5 months. A partial response for 9 months in the bone metastases was documented, but the therapy was discontinued due to persistent thrombocytopenia (58,000 plts/microL) lasting 4 months. Thrombocytopenia was the major side-effect, occurring in 5/7 patients over 8 courses of therapy for a mean period of 37 days (7-120 d). Thus, in our experience thrombocytopenia is the major factor limiting the therapeutic effect of 131I-MIBG therapy in palliative treatment.     

Treatment of neuroblastoma with [131I]metaiodobenzylguanidine: long-term results in 25 patients.

From 1984 to 1990 we have treated altogether 25 children with [131I]metaiodobenzylguanidine (131I-MIBG) for a refractory, relapsed or metastasized neuroblastoma. Three children had stage III and 22 children had stage IV of the disease; at diagnosis their ages were between 4 months and 10 years. Children with stage III disease had at diagnosis a median age of 3.0 years and at treatment 3.8 years. After first-line chemotherapy 2 children had achieved a complete remission (CR), while in 1 child the tumor did not respond (NR) to the initial treatment. At the time of 131I-MIBG treatment 2 children had relapsed and in the other one no further response was achievable. The children were treated by a 13.5 +/- 12.9 mCi/kg BW per course with a mean total dose of 280.7 +/- 243.9 mCi. One child achieved CR by 131I-MIBG alone, while in 2 cases no measurable success was observed. All 3 children were treated additionally by surgery, chemotherapy and bone marrow transplantation (BMT). Two children have died but one is alive and in CR. The 22 children with stage IV disease were treated in two different study groups. In group A, 14 children were studied for side-effects and response to 131I-MIBG. All children were pretreated with standard chemotherapy. Five were treated in relapse, 5 in progression and 3 at a refractory state of the disease; only 1 child was in complete remission when being treated with 131I-MIBG. Group A patients were treated with a mean of 2.4 courses, with 10.3 mCi/kg BW for each course.(ABSTRACT TRUNCATED AT 250 WORDS)     

Efficacy and safety of [131I]metaiodobenzylguanidine therapy for patients with refractory neuroblastoma.

Metaiodobenzylguanidine (MIBG) is a guanethidine derivative that is selectively concentrated in sympathetic nervous tissue. MIBG labeled with 123I or 131I has proven to be a specific and sensitive tool for detection of primary and metastatic pheochromocytoma and neuroblastoma. Eleven patients, with refractory stage IV neuroblastoma were treated with a total of 23 courses of 131I-MIBG, 100-400 mCi/m2/course. Total activity administered per course ranged from 90-550 mCi; maximum cumulative radioactivity per patient was 1356 mCi. The 131I-MIBG was given as a 2 hour infusion. Total body dose was calculated from whole body activity measurements, ranging from 73-250 cGy. The main toxicity was thrombocytopenia, with platelet nadirs to less than 25,000/microL in 5/23 courses (5 patients), all occurring in patients with greater than 25% replacement by tumor in the bone marrow. Neutropenia to a nadir of less than 500/microL was seen in only 2 patients, both with greater than 50% bone marrow replacement after 2 and 4 courses of 131I-MIBG, respectively. Tumor doses were calculated in patients with an evaluable measurable lesion, and ranged from 312-6329 cGy per course. Two of the eleven patients had partial responses, with one long-term survivor with stage IV neuroblastoma with no evidence of active disease now 4 years off treatment. Two other patients survive with stable disease after 3 treatments, at 3+ and 5+ months. Seven patients died with progressive disease. This study shows that treatment with 131I-MIBG is safe and can be effective in refractory neuroblastoma, particularly in patients who do not have extensive bone and bone marrow involvement.     

131I]metaiodobenzylguanidine therapy in paraganglioma.

Our experience with [131I]metaiodobenzylguanidine (131I-MIBG) therapy in a 10 year old boy is reported. At disease onset, in May 1988, this boy presented a large mass in the upper left abdominal quadrant, which was resected with a histopathological diagnosis of extra-adrenal malignant pheochromocytoma (paraganglioma). He subsequently underwent two further surgical resections and chemotherapy. When 131I-MIBG therapy was started, in June 1990, skeletal and abdominal metastases were present. These localizations were revealed by 131I-MIBG scans and confirmed by x-ray examination. At present 6 courses of therapy have been performed with a cumulative activity of 29.6 GBq. Side-effects have been limited to vomiting and mild thrombocytopenia, lasting 2 weeks during the second course of therapy. After 15 months of therapy, a progressive reduction of MIBG uptake, coupled with a stabilization of the lythic lesions, has been observed.     

Long-term results of [131I]metaiodobenzylguanidine treatment of refractory advanced neuroblastoma.

Fourteen patients with advanced neuroblastoma, which was unresponsive to or had relapsed despite conventional therapy, were entered into a phase I/II trial of [131I]metaiodobenzylguanidine (131I-MIBG). Doses ranged from 1.85-8.14 GBq each (50-220 mCi), with cumulative doses of 1.85-24.20 GBq (50-654 mCi) in one to three doses. Side effects included mild nausea and vomiting and moderate myelosuppression which occurred in nine patients. Subjective responses occurred in five patients. Four patients had objective responses (one partial, two minor and one mixed). Two of these patients remain alive 80 and 60 months after beginning 131I-MIBG therapy. Comparison of the 131I-MIBG treated patients with 11 carefully matched control patients treated with an advanced current chemotherapy protocol (CCG 8605) was performed by means of Kaplan-Meier life table analysis. The 14% four-year survival with 131I-MIBG compared favorably with the 6% achieved by salvage chemotherapy. We thus believe 131I-MIBG may have a role in the management of neuroblastoma.     

131I]metaiodobenzylguanidine and high-dose chemotherapy with bone marrow rescue in advanced neuroblastoma.

High-dose chemotherapy (HDT) and autologous bone marrow rescue (ABMR) is routinely used as consolidation treatment in advanced neuroblastoma. This study is presently examining the efficacy and toxicity of combined [131I]metaiodobenzylguanidine (131I-MIBG) therapy with HDT and ABMR. Five children (4 male, 1 female), median age of 8 years (range 4-11 years) were treated, 3 at relapse and 2 after initial chemotherapy. A single infusion of 131I-MIBG (median activity 11.1 GBq, range 7.4-11.2 GBq) was followed by HDT and ABMR 14-32 days later. High-dose chemotherapy consisted of carboplatin and melphalan in 4 patients, and vincristine, etoposide, carboplatin and melphalan in 1. One patient developed a septicaemia and died, and another failed to engraft; both had extensive bone marrow infiltration at the time of 131I-MIBG therapy. The combined therapy was well tolerated by the three other patients. Two children have relapsed and died (including one who failed to engraft), and 2 are alive 17 and 41 months after ABMR. In the absence of extensive bone marrow metastases, combined therapy offers potential as a means of consolidating treatment in advanced neuroblastoma.     

131I]metaiodobenzylguanidine therapy in carcinoid tumors.

Our experience with [131I]metaiodobenzylguanidine (131I-MIBG) therapy in two patients with carcinoid tumor is described. These patients were selected because of multiple areas of uptake on 131I-MIBG scan, consistent with the extent of the disease. Both patients presented diarrhea and liver metastases. Para-aortical lymphonodes and skeletal metastases were present in the first and the second patient, respectively. Previous treatment involved r-alpha-interferon, surgery or radiotherapy. In both cases 131I-MIGB therapy was started in December 1990 and is still continuing. No haematologic or hepatic side-effects have been observed. Mild hypotension (90/60 mmHg) occurred in one patient during the first course of therapy and was resolved by corticoid treatment. A stabilization of disease and a progressive reduction of diarrhea have been observed in both patients. In the second patient an initial decrease in liver metastases was confirmed by ultrasonography 7 months after the beginning of therapy.     

131I]metaiodobenzylguanidine therapy in 20 patients with malignant pheochromocytoma.

Twenty patients, 16 male and 4 female (aged 11-76 years), with metastatic pheochromocytoma were treated in our Institution between 1985 and 1990. Metastases occurred in all patients: at presentation in 11 patients, with a 10 to 30 month delay in 7 patients, and 9 and 28 years later respectively in 2 patients. Catecholamines hyperproduction was present in all patients. Metaiodobenzylguanidine (MIBG) uptake was found in 16 patients after a diagnostic dose and only after a therapeutic dose in 1 patient. Surgery was performed on primary tumor (18 patients) and on distant metastases (10 patients). 131I-MIBG therapy was performed in 11 patients, 9 of whom were evaluable. The cumulative activity ranged from 3.7 to 26.3 GBq (100 to 711 mCi) in 1 to 6 courses. We observed symptomatic improvement (5 patients) and partial tumor response in 2 patients, which lasted for 28 and 9 months respectively, terminating with a rapidly progressing disease involving the bone marrow. Stabilisation was observed in 3 patients. Moderate myelosuppression occurred in 4 patients. Fifteen patients died with a median survival of 16 months (range 3-60). Response to therapy was poor and further evaluation of the presently available therapeutic approaches is needed.     

Outcome of [131I]metaiodobenzylguanidine therapy of neuroblastoma: seven years after.

Beginning in 1984 and based on a total of 40 treatments with [131I]metaiodobenzylguanidine (131I-MIBG) in most cases with a follow-up of 5 years or more, it seems to be worthwhile reevaluating our clinical data and draw some final conclusions: We treated 12 children with a neuroblastoma (NB) IV and 3 with a NB III. In no case 131I-MIBG was the primary therapy. The great majority suffered from recurrence. The mean treatment interval after chemotherapy was 6 months (range 0-54). We calculated a median cumulative tumor dose of 77 Gy (range 0-259) in patients with stage III and 30 Gy (range 4-267) in stage IV NB. The tumor half-life time of 131I-MIBG does not significantly differ between stage III (3 days) and IV (2-5 days). Although the median tumor dose of stage III NB exceeded that of stage IV, we found in NB IV a significant tumor remission in 7 out of 12 cases. On the other hand, a slight reduction of tumor size was seen in only 1 case of stage III NB. This indicates a lower radiation sensitivity of stage III NB. Despite this fact, the two patients with stage III NB who presented a sufficient 131I-MIBG-tumor uptake turned to become operable after 131I-MIBG. Stage IV patients improved, too, even if most of them suffered from recurrence with a very poor prognosis: 3 patients of stage IV lived longer than 48-60 month or are still alive. However, no one of this group remitted completely.(ABSTRACT TRUNCATED AT 250 WORDS)     

The use of [131I]metaiodobenzylguanidine in the treatment of neuroblastoma after conventional therapy.

Eleven cases of neuroblastoma (10 males and 1 female; 9 aged 1-13 years, and two aged 17 and 38 years, respectively) ten of which were refractory to chemotherapy, were submitted to treatment with [131I]metaiodobenzylguanidine (131I-MIBG). The therapeutic procedure consisted essentially of single doses (2.6-9.5 GBq) of 131I-MIBG mostly split into two parts, administered by slow i.v. infusion and given in several therapeutic courses, usually at 1-2 month intervals. The treatment resulted in: 1 complete response, 1 partial response, 1 minor response, 4 stabilized diseases and 2 progressive diseases (two patients were not evaluable due to rapid progression of the disease). Pain relief was observed in all cases and particularly in four patients who suffered severe tumor pain. The major side-effects recorded were: hypertensive crises over a 6-day period in one case, fever lasting a few days in another and bone marrow depression in two intensively pretreated patients. A slight hematologic toxicity was observed, however, in almost all cases.     

131I]metaiodobenzylguanidine treatment of a malignant paraganglioma.

The bone metastases of a malignant, non-secreting paraganglioma were treated with [131I]metaiodobenzylguanidine (131I-MIBG) over a 10-year period. Initial treatment (131I-MIBG: 9.6 GBq) resulted in a decrease in the number of bone metastases from 16 to 2. At three years, a relapse with primary tumor regrowth and liver metastasis was again treated with 131I-MIBG (22.2 GBq). A decrease in the number of bone metastases and MIBG uptake was again observed.     

Therapy of pheochromocytoma with [131I]metaiodobenzylguanidine.

Fourteen patients with chromaffin tumors were treated with [131]metaiodobenzylguanidine (131I-MIBG); 13 of them suffered from malignant and one from benign pheochromocytoma. In all patients clinical symptoms were improved. In some of these patients tumor shrinkage was observed. In one patient surgery of all tumor tissue was made possible by 131I-MIBG treatment. As shown in one patient, close follow-up is necessary in any case because remnant tumor tissue may start growing again after a long period of rest.     

Role of [131I]metaiodobenzylguanidine therapy in carcinoids.

From cumulative reported data the sensitivity of [131I]metaiodobenzylguanidine (131I-MIBG) scintigraphy of carcinoids appears to be greater than 60%; at our Institute 131I-MIBG scintigrams were positive in 51 of 70 patients with metastatic carcinoid. Twenty patients with symptomatic, metastatic disease have received 7.4 GBq doses of 131I-MIBG for palliation. Most of these patients had multiple large metastases showing no response to other therapies. No objective response (greater than 50% tumor volume reduction) was ever observed; however, 13 patients were relieved of symptoms, such as flushes, diarrhea, anorexia and pain. Palliation in some of these patients was meaningful and long lasting. Possible explanations for a palliative effect in the absence of objective remission are discussed. Treatment with escalating doses of stable MIBG (up to 80 mg) in 9 patients does not support the hypothesis that the palliation is due to a purely pharmacological effect. Palliation might be explained by the observation that carcinoid liver metastases may present both as hot and cold lesions; 131I-MIBG therapy will thus target exclusively at metabolically active metastases, which are responsible for the patient's symptoms.     

Treatment of neuroblastoma with [125I]metaiodobenzylguanidine.

To find a treatment that may be effective against micrometastases of advanced, stage III or IV neuroblastoma, [125I]metaiodobenzylguanidine (125I-MIBG) was used in a phase I toxicity trial. In seven patients, thrombocytopenia was encountered with absorbed whole body doses of 85-135 rad from 125I-MIBG, but the dosimetry was imprecise in predicting bone marrow injury. Three patients survived for over one year, results that may indicate efficacy of 125I-MIBG therapy.     

Results of [131I]metaiodobenzylguanidine treatment in metastatic carcinoid.

The results obtained with [131I]metaiodobenzylguanidine (131I-MIBG) treatment in 6 patients affected by metastatic carcinoid are reported. 131I-MIBG was given in single doses of 3.7-8.0 GBq, reaching a maximum cumulative dose of 29.5 GBq in 4 courses. Objective responses were not observed, but in 4 cases an apparent stabilisation of the disease for more than 1 year was obtained. A subjective response regarding the carcinoid syndrome was observed in 4 cases. No response was seen in 2 cases. No adverse side-effects of any importance were observed, usually being prevented by a mild medication.     

Results of [131I]metaiodobenzylguanidine treatment in metastatic malignant phaeochromocytoma.

The results obtained with [131I]metaiodobenzylguanidine (131I-MIBG) treatment in 6 patients affected by metastatic phaeochromocytoma are reported. Single doses of 3.7-7.4 GBq were given, in 1-6 courses, up to cumulative doses of 5.4-37.8 GBq. Objective responses were observed in 5 patients (2 tumour shrinkages, even if small; 5 lowering of blood pressure), which were only temporary in 3 patients and stable in 2. Complete disappearance of pain was obtained in 2/2 patients. No adverse side-effects were observed. The problem of treatment strategy in situations of stable disease deserves further study.     

Role of [131I]metaiodobenzylguanidine therapy in medullary thyroid carcinoma.

In recent years several radiopharmaceuticals have become available, offering new possibilities for the diagnosis and therapy of medullary thyroid carcinoma (MTC). For the diagnosis and follow-up 201TI-chloride and 99mTc(V)-DMSA are the tracers of choice. Imaging with [131I]metaiodobenzylguanidine (131I-MIBG) and 131I-anti-CEA or anti-calcitonin antibodies or fragments is less sensitive but very specific. These tracers can be used to evaluate their potential therapeutic use. Cumulative reported data on the diagnostic use of 131I-MIBG in 178 MTC patients indicate that overall 34.5% of medullary cancers concentrate MIBG. At The Netherlands Cancer Institute 131I-MIBG scintigraphy was positive in 8 of 23 patients with MTC. Four of these patients have received therapeutic amounts of 131I-MIBG, resulting in 1 partial remission and meaningful palliation in 3 patients with metastatic MTC. It is concluded that, although the preliminary experience suggests that the objective response of MTC to 131I-MIBG therapy is limited, the palliation provided to these patients, for whom there is little other treatment, may be very meaningful.