Martin C. Graham

A phase I trial of monoclonal antibody M195 in acute myelogenous leukemia: specific bone marrow targeting and internalization of radionuclide.

Ten patients with myeloid leukemias were treated in a phase I trial with escalating doses of mouse monoclonal antibody (mAb) M195, reactive with CD33, a glycoprotein found on myeloid leukemia blasts and early hematopoietic progenitor cells but not on normal stem cells. M195 was trace-labeled with iodine-131 (131I) to allow detailed pharmacokinetic and dosimetric studies by serial sampling of blood and bone marrow and whole-body gamma-camera imaging. Total doses up to 76 mg were administered safely without immediate adverse effects. Absorption of M195 onto targets in vivo was demonstrated by biopsy, pharmacology, flow cytometry, and imaging; saturation of available sites occurred at doses greater than or equal to 5 mg/m2. The entire bone marrow was specifically and clearly imaged beginning within hours after injection; optimal imaging occurred at the lowest dose. Bone marrow biopsies demonstrated significant dose-related uptake of M195 as early as 1 hour after infusion in all patients, with the majority of the dose found in the marrow. Tumor regressions were not observed. An estimated 0.33 to 1.0 rad/mCi 131I was delivered to the whole body, 1.1 to 6.1 rad/mCi was delivered to the plasma, and up to 34 rad/mCi was delivered to the red marrow compartment. 131I-M195 was rapidly modulated, with a majority of the bound immunoglobulin G (IgG) being internalized into target cells in vivo. These data indicate that whole bone marrow ablative doses of 131I-M195 can be expected. The rapid, specific, and quantitative delivery to the bone marrow and the efficient internalization of M195 into target cells in vivo also suggest that the delivery of other isotopes such as auger or alpha emitters, toxins, or other biologically important molecules into either leukemia cells or normal hematopoietic progenitor cells may be feasible.

Quantitative imaging of I-124 using positron emission tomography with applications to radioimmunodiagnosis and radioimmunotherapy.

Positron emission tomography (PET) is potentially useful for the quantitative imaging of radiolabeled antibodies, leading in turn to improved dosimetry in radioimmunotherapy. Iodine-124 is a positron-emitting nuclide with appropriate chemical properties and half-life (4.2 days) for such studies since the radiolabeling of antibodies with iodine is well understood and the half-life permits measurements over several days. Unfortunately, I-124 has a complex decay scheme with many high-energy gamma rays and a positron abundance of only 25%. It has therefore been largely ignored as a PET-imaging nuclide. However, measurements made with phantoms and animals under realistic conditions using a BGO-based PET scanner have shown that satisfactory imaging and quantitation can be achieved. Investigations of spatial resolution, the linearity of regional observed count rate versus activity in the presence of other activity, and the visualization and quantitation of activity in spheres with different surrounding background activities were carried out with phantoms up to 22 cm in diameter. Compared with F-18, spatial resolution was only slightly degraded (13.5 mm FWHM vs 12 mm FWHM) while linearity was the same over a 10:1 activity range (0.015 to 0.15 MBq/ml for I-124). The visualization and quantitation of spheres was also slightly degraded when using similar imaging times. Increasing the imaging time for I-124 reduced the difference. To verify that the technique would work in vivo, measurements were made of human neuroblastoma tumors in rats which had been injected with I-124 labeled 3F8 antibody. Although the number of samples was small, good agreement was achieved between image-based measurements and direct measurements of excised 4-g tumors. Thus quantitative imaging of I-124 labeled antibodies appears to be possible under realistic conditions.

A phase I toxicity, pharmacology, and dosimetry trial of monoclonal antibody OKB7 in patients with non-Hodgkin's lymphoma: effects of tumor burden and antigen expression.

Eighteen patients with relapsed non-Hodgkins lymphoma (NHL) were infused with escalating doses of monoclonal antibody (mAb) OKB7, trace-labeled with iodine-131 (131I), in order to study toxicity, pharmacology, antibody localization, and dosimetry of radioiodine. OKB7 is a noncytotoxic mouse immunoglobulin G2b (IgG2b) mAb reactive with B cells and most B-cell NHL. Three patients each were treated at six dose levels ranging from 0.1 mg to 40 mg. All patients had radionuclide imaging and counting daily, had serial blood sampling to study pharmacokinetics, human antimouse antibody (HAMA), and circulating antigen, and had a biopsy of accessible lymphoma to determine delivery of isotope to tumors and assess the effect of tumor antigen expression on mAb delivery. Bone marrow biopsies were also done in the majority of patients. There was no toxicity. Serum clearance showed a median early phase half-life of 1.9 hours and a later phase half-life of 21.7 hours. Median total body clearance half-life was 22 hours. Pharmacokinetics were not dose-related. HAMA was detected in five patients. Circulating blocking antigen was detected in the serum of four patients, but at levels that were of pharmacologic consequence only in one. Biopsied tumor tissue from five patients did not express OKB7 antigen. No significant uptake of antibody was seen in these tumor sites. Mean total uptake of isotope into lymphoma measured in biopsies correlated linearly over the 400-fold increase in injected mAb dose. However, the percent of injected dose found per gram of tumor was unrelated to dose, but correlated inversely with tumor burden. In two patients with minimal tumor burden, 1.0 mg and 5.0 mg doses of OKB7 resulted in tumor to body radioisotope dose ratios of 22 and 7, which would theoretically permit tolerable delivery of 4,400 and 1,400 rads to these tumors, respectively, if OKB7 were conjugated with higher doses of 131I.

Phase I dose-escalation trial of iodine 131-labeled monoclonal antibody OKB7 in patients with non-Hodgkin's lymphoma.

PURPOSE Eighteen patients with recurrent or refractory CD21-positive, non-Hodgkins lymphoma (NHL) were treated in a phase IA dose-escalation therapeutic trial of iodine 131 labeled to a fixed dose of OKB7. METHODS Individual doses of 30 to 50 mCi of 131I on 25 mg OKB7 were administered 2 to 3 days apart to achieve four total 131I-OKB7 dose levels of 90, 120, 160, and 200 mCi. Pharmacology, dosimetry, therapeutic effects, toxicity, human anti-mouse antibody (HAMA) response, and maximum-tolerated dose (MTD) were determined. Patients were evaluated by imaging studies (including whole-body gamma camera or single-photon emission computed tomography [SPECT] scans), flow cytometric analysis, bone marrow biopsy, and serial blood sampling. RESULTS Median plasma and whole-body half-lives (T1/2) were 16 hours and 14 hours, respectively. Plasma and whole-body radiation doses were 0.0081 Gy/mCi and 0.0022 Gy/mCi, respectively. Specific tumor visualization was noted in eight of 18 patients. HAMA was detected in 12 of 16 patients. Nonhematologic toxicity was limited to asymptomatic elevations of thyroid-stimulating hormone (TSH) in five of 15 patients. Hematologic toxicity was observed in six of 18 patients, but was severe in only two patients. MTD in patients with diffuse lymphomatous bone marrow involvement was determined to be 200 mCi in four divided doses of 50 mCi 131I/25 mg OKB7. Antitumor activity was observed in 13 of 18 patients (one partial response [PR] and 12 mixed responses) and was dependent on the 131I-OKB7 dose administered. In general, palpable peripheral lymphadenopathy, enlarged spleens, skin lesions, and circulating OKB7-positive peripheral lymphocytes responded most readily to treatment. 131I-OKB7 was safely administered to a patient in leukemic phase of NHL with prompt subsequent loss of approximately 1 kg of tumor cells from the peripheral blood without associated tumor lysis syndrome. CONCLUSION Because antitumor activity with tolerable toxicity was observed in the majority of this group of heavily pretreated patients, phase II investigation of mAb OKB7 radioconjugates in the therapy of NHL is warranted.

Development of a method to measure kinetics of radiolabelled monoclonal antibody in human tumour with applications to microdosimetry: positron emission tomography studies of iodine-124 labelled 3F8 monoclonal antibody in glioma

We present a method to assess quantitatively the immunological characteristics of tumours using radiolabelled monoclonal antibody and positron emission tomography (PET) to improve dosimetry for radioimunotherapy. This method is illustrated with a glioma patient who was injected with 96.2 MBq of iodine-124 labelled 3F8, a murine antibody (IgG3) specific against the ganglioside GD2. Serial PET scans and plasma samples were taken over 11 days. A three-compartment model was used to estimate the plasma to tumour transfer constant (K1), the tumour to plasma transfer constant k2, the association and dissociation constants (k3, k4) of antibody binding, and the binding potential. Tumour radioactivity peaked at 18 h at 0.0045% ID/g. The kinetic parameters were estimated to be: K1 = 0.048 ml h−1 g−1, k2 = 0.16 h−1, k3 = 0.03 h−1, k4 = 0.015 h−1 and BP = 2.25. Based on these kinetic parameters, the amount of tumour-bound radiolabelled monoclonal antibody was calculated. This method permits estimates of both macrodosimetry and microdosimetry at the cellular level based on in vivo non-invasive measurement.

A 64 MHz half-birdcage resonator for clinical imaging

Abstract A radiofrequency resonator whose normal modes correspond to those of a ladder network of finite length is described. When formed into a semicylindrical geometry, the lowest frequency mode of the resulting “half-birdcage” resonator yields a B 1 distribution which can be exploited for imaging.

Clinical applications of fusion imaging in oncology

Recent developments in tumor imaging, made possible by advances in instrumentation and radiopharmaceuticals, has led to an increasing need for accurate anatomic correlation of single photon emission computed tomography (SPECT) and positron emission tomography (PET) images. Fusion imaging permits the functional strengths of SPECT and PET to be combined with the anatomic resolution of computed tomography (CT) and magnetic resonance imaging (MRI). Clinical applications of fusion imaging include the evaluation of brain tumors, lymphoma, hepatic lesions and monoclonal antibody studies. The continued development of these techniques will eventually allow fusion imaging to become a routine part of nuclear medicine practice.

Current status of radioimmunotherapy

Radioimmunotherapy with radiolabeled monoclonal antibodies is increasingly effective for hematopoietic tumors, with a number of investigators reporting persistent major responses. Radioimmunotherapy for solid tumors has been more difficult and only an occasional major response has been reported and these have so far not been persistent. Toxicity is predominantly hematopoietic, with platelets being most sensitive to the effects of radiation. Even at ultra-high doses (up to 28 mCi/kg of 131I), second organ toxicity has not been reached. Rational approaches to dose planning are becoming possible with improvements in dosimetry, based on quantitative SPECT and PET imaging. Current therapeutic indices for tumor/marrow, the most radiosensitive organ, are in the range of 5-10 to 1. This is probably still too low for curative treatment of solid tumors, and further refinements, perhaps based on novel antibody formulations, are needed.

Spatial mapping of the percentage cellularity in human bone marrow using magnetic resonance imaging

A noninvasive assay for the spatial distribution of the percentage cellularity in human bone marrow is presented. Twelve individuals were studied using two magnetic resonance imaging techniques: (1) fast spin echo imaging with frequency selective presaturation, and (2) three-point chemical shift imaging. The data were compared to results obtained using a previously validated stimulated echo spectroscopic method. The results of this study demonstrate that a measure of the percentage cellularity in bone marrow is possible using magnetic resonance imaging techniques provided that high-quality water or lipid suppression is achieved across the region of interest. Since the method is applicable to bone marrow at any anatomic location, it may prove useful in dosimetric calculations during and after a course of internal or external beam radiotherapy.

Doubly tuned solenoidal resonators for small animal imaging and spectroscopy at 1.5 Tesla.

The design and construction of solenoidal resonators for use with small animals in a 1.5-Tesla clinical imaging system are described. The coils have been designed to exploit the B1 distributions of two resonant modes of a four-turn solenoid whose windings are in parallel. Both singly and doubly tuned versions have been constructed. 1H images of normal and pathologic anatomy in mice and rats as well as a 31P spectrum of a Walker 256 rat sarcoma are presented. A primary advantage of this design is that the coils are easy to build and implement while providing the necessary sensitivity to allow high quality images to be obtained with no changes to the hardware or software of the clinical unit.