Repeatability of SUV measurements in serial PET.

PURPOSE: The standardized uptake value (SUV) is a quantitative measure of FDG tumor uptake frequently used as a tool to monitor therapeutic response. This study aims to (i) assess the reproducibility and uncertainty of SUV max and SUV mean, due to purely statistical, i.e., nonbiological, effects and (ii) to establish the minimum uncertainty below which changes in SUV cannot be expected to be an indicator of physiological changes. METHODS: Three sets of measurements were made using a GE Discovery STE PET/CT Scanner in 3D mode: (1) A uniform 68Ge 20 cm diameter cylindrical phantom was imaged. Thirty serial frames were acquired for durations of 3, 6, 10, 15, and 30 min. (2) Esser flangeless phantom (Data Spectrum, approximately 6.1 L) with fillable thin-walled cylinders inserts (diameters: 8, 12, 16, and 25 mm; height: approximately 3.8 mm) was scanned for five consecutive 3 min runs. The cylinders were filled with 18FDG with a 37 kBq/cc concentration, and with a target-to-background ratio (T/BKG) of 3/1. (3) Eight cancer patients with healthy livers were scanned approximately 1.5 h post injection. Three sequential 3 min scans were performed for one bed position covering the liver, with the patient and bed remaining at the same position for the entire length of the scan. Volumes of interest were drawn on all images using the corresponding CT and then transferred to the PET images. For each study (1-3), the average percent change in SUV mean and SUV max were determined for each run pair. Moreover, the repeatability coefficient was calculated for both the SUV mean and SUV max for each pair of runs. Finally, the overall ROI repeatability coefficient was determined for each pair of runs. RESULTS: For the 68Ge phantom the average percent change in SUV max and SUV mean decrease as a function of increasing acquisition time from 4.7 +/- 3.1 to 1.1 +/- 0.6%, and from 0.14 +/- 0.09 to 0.04 +/- 0.03%, respectively. Similarly, the coefficients of repeatability also decrease between the 3 and 30 min acquisition scans, in the range of 10.9 +/- 3.9% - 2.6 +/- 0.9%, and 0.3 +/- 0.1% - 0.10 +/- 0.04%, for the SUV max and SUV mean, respectively. The overall ROI repeatability decreased from 18.9 +/- 0.2 to 6.0 +/- 0.1% between the 3 and 30 min acquisition scans. For the l8FDG phantom, the average percent change in SUV max and SUV mean decreases with target diameter from 3.6 +/- 2.0 to 1.5 +/- 0.8% and 1.5 +/- 1.3 to 0.26 +/- 0.15%, respectively, for targets from 8-25 mm in diameter and for a region in the background (BKG). The coefficients of repeatability for SUV max and SUV mean also decrease as a function of target diameter from 7.1 +/- 2.5 to 2.4 +/- 0.9 and 4.2 +/- 1.5 to 0.6 +/- 0.2, respectively, for targets from 8 mm to BKG in diameter. Finally, overall ROI repeatability decreased from 12.0 +/- 4.1 to 13.4 +/- 0.5 targets from 8 mm to BKG in diameter. Finally, for the measurements in healthy livers the average percent change in SUVmax and SUV mean were in the range of 0.5 +/- 0.2% - 6.2 +/- 3.9% and 0.4 +/- 0.1 and 1.6 +/- 1%, respectively. The coefficients of repeatability for SUV max and SUV men are in the range of 0.6 +/- 0.7% - 9.5 +/- 12% and 0.6 +/- 0.7% - 2.9 +/- 3.6%, respectively. The overall target repeatability varied between 27.9 +/- 0.5% and 41.1 +/- 1.0%. CONCLUSIONS: The statistical fluctuations of the SUV mean are half as large as those of the SUV max in the absence of biological or physiological effects. In addition, for clinically applicable scan durations (i.e., approximately 3 min) and FDG concentrations, the SUV max and SUV mean have similar amounts of statistical fluctuation for small regions. However, the statistical fluctuations of the SUVmean rapidly decrease with respect tothe SUVmax as the statistical power of the data grows either due to longer scanning times or as the target regions encompass a larger volume.

A novel respiratory tracking system for smart-gated PET acquisition.

PURPOSE: In this study, the authors validated a novel respiratory tracking device, the multidimensional respiratory tracking (MDRT) system, that was designed to assist in correcting for respiratory motion in PET/CT images. The authors also investigated a novel PET acquisition technique, smart gating (SG), that enables to acquire motion-free PET data prospectively, with minimum user interference and with no additional postprocessing of the PET data. METHODS: MDRT uses visual tracking techniques to track simultaneously the two-dimensional (in the vertical plane) motion of multiple fiducial markers using a standard video camera. A threshold window is set at the breathing amplitude of interest using the MDRT GUI. A trigger is generated at a rate of 250 Hz as long as the breathing signal is within the threshold window. The triggers are fed into the PET scanner to initialize one single bin of a gated acquisition every 4 ms. No triggers are delivered as the breathing signal drifts outside the threshold window. Consequently, PET data are acquired only whenever the breathing signal is confined within the amplitude threshold window, thus resulting into a motion-free image set. The accuracy of MDRT in tracking the breathing signal was assessed (1) by comparing the period of an oscillating phantom, as measured by MDRT, to that measured with a photogate timer and (2) by comparing the MDRT output to that of the real-time position management (RPM) in ten patients. The SG PET/CT acquisition was validated in phantoms and in two stereotactic body radiosurgery (SBRS) lung DIBH-PET/CT patients. RESULTS: MDRT was in agreement with the photogate timer in determining the period of motion to less than 2%. The percent errors between MDRT and RPM in the positions of the peaks and troughs of the ten patients' breathing signals were within 10%. In phantoms, SG technique enables to correct for motion-induced artifacts in the PET images and improve the accuracy of PET quantitation. For the SBRS application, in one patient, the patient's CT lesion was not detected in the corresponding clinical PET images, while it exhibited an SUV of 1.8 in the DIBH image set. In the second patient, DIBH-PET images showed an improved PET-to-CT spatial matching and a 52% increase in the lesion SUV. CONCLUSIONS: MDRT has been shown to be accurate in tracking breathing motion and assisted in implementing a smart-gating PET acquisition technique that allowed to acquire prospectively motion-free PET images.

Positron emission tomography imaging for herpes virus infection: Implications for oncolytic viral treatments of cancer.

Molecular therapy using viruses would benefit greatly from a non-invasive modality for assessing dissemination of viruses. Here we investigated whether positron emission tomography (PET) scanning using [(124)I]-5-iodo-2'-fluoro-1-beta-d-arabinofuranosyl-uracil (FIAU) could image cells infected with herpes simplex viruses (HSV). Using replication-competent HSV-1 oncolytic viruses with thymidine kinase (TK) under control of different promoters, we demonstrate that viral infection, proliferation and promoter characteristics all interact to influence FIAU accumulation and imaging. In vivo, as few as 1 x 107 viral particles injected into a 0.5-cm human colorectal tumor can be detected by [(124)I]FIAU PET imaging. PET signal intensity is significantly greater at 48 hours compared with that at 8 hours after viral injection, demonstrating that PET scanning can detect changes in TK activity resulting from local viral proliferation. We also show the ability of FIAU-PET scanning to detect differences in viral infectivity at 0.5 log increments. Non-invasive imaging might be useful in assessing biologically relevant distribution of virus in therapies using replication-competent HSV.

A new satellite of saturn?

Analysis of all available observations of faint objects near Saturn during the 1966 passage of the earth through the plane of Saturn's rings suggests the existence of at least one previously undiscovered satellite of Saturn. The data support the previously published orbit for Janus. These satellites may be major members of an extended ring.

Scintigraphy of normal mouse ovaries with monoclonal antibodies to ZP-2, the major zona pellucida protein.

The zona pellucida is an extracellular glycocalyx, made of three sulfated glycoproteins, that surrounds mammalian oocytes. Parenterally administered monoclonal antibodies specific for ZP-2, the most abundant zona protein, localize in the zona pellucida. When labeled with iodine-125, these monoclonal antibodies demonstrate a remarkably high target-to-nontarget tissue ratio and provide clear external radioimaging of ovarian tissue.

The Hubble Space Telescope (HST) observing campaign on comet Shoemaker-Levy 9.

The Hubble Space Telescope made systematic observations of the split comet P/Shoemaker-Levy 9 (SL9) (P designates a periodic comet) starting in July 1993 and continuing through mid-July 1994 when the fragments plunged into Jupiter's atmosphere. Deconvolutions of Wide Field Planetary Camera images indicate that the diameters of some fragments may have been as large as approximately 2 to 4 kilometers, assuming a geometric albedo of 4 percent, but significantly smaller values (that is, < 1 kilometer) cannot be ruled out. Most of the fragments (or nuclei) were embedded in circularly symmetric inner comae from July 1993 until late June 1994, implying that there was continuous, but weak, cometary activity. At least a few nuclei fragmented into separate, condensed objects well after the breakup of the SL9 parent body, which argues against the hypothesis that the SL9 fragments were swarms of debris with no dominant, central bodies. Spectroscopic observations taken on 14 July 1994 showed an outburst in magnesium ion emission that was followed closely by a threefold increase in continuum emission, which may have been caused by the electrostatic charging and subsequent explosion of dust as the comet passed from interplanetary space into the jovian magnetosphere. No OH emission was detected, but the derived upper limit on the H2O production rate of approximately 10(27) molecules per second does not necessarily imply that the object was water-poor.

Hubble space telescope observations of comet p/shoemaker-levy 9 (1993e).

The Hubble Space Telescope observed the fragmented comet P/Shoemaker-Levy 9 (1993e) (P indicates that it is a periodic comet) on 1 July 1993. Approximately 20 individual nuclei and their comae were observed in images taken with the Planetary Camera. After subtraction of the comae light, the 11 brightest nuclei have magnitudes between approximately 23.7 and 24.8. Assuming that the geometric albedo is 0.04, these magnitudes imply that the nuclear diameters are in the range approximately 2.5 to 4.3 kilometers. If the density of each nucleus is 1 gram per cubic centimeter, the total energy deposited by the impact of these 11 nuclei into Jupiter's atmosphere next July will be approximately 4 x 10(30) ergs ( approximately 10(8) megatons of TNT). This latter number should be regarded as an upper limit because the nuclear magnitudes probably contain a small residual coma contribution. The Faint Object Spectrograph was used to search for fluorescence from OH, which is usually an excellent indicator of cometary activity. No OH emission was detected, and this can be translated into an upper limit on the water production rate of approximately 2 x 10(27) molecules per second.

An iterative technique to segment PET lesions using a Monte Carlo based mathematical model.

PURPOSE: The need for an accurate lesion segmentation tool in 18FDG PET is a prerequisite for the estimation of lesion response to therapy, for radionuclide dosimetry, and for the application of 18FDG PET to radiotherapy planning. In this work, the authors have developed an iterative method based on a mathematical fit deduced from Monte Carlo simulations to estimate tumor segmentation thresholds. METHODS: The GATE software, a GEANT4 based Monte Carlo tool, was used to model the GE Advance PET scanner geometry. Spheres ranging between 1 and 6 cm in diameters were simulated in a 10 cm high and 11 cm in diameter cylinder. The spheres were filled with water-equivalent density and simulated in both water and lung equivalent background. The simulations were performed with an infinite, 8/1, and 4/1 target-to-background ratio (T/B). A mathematical fit describing the correlation between the lesion volume and the corresponding optimum threshold value was then deduced through analysis of the reconstructed images. An iterative method, based on this mathematical fit, was developed to determine the optimum threshold value. The effects of the lesion volume and T/B on the threshold value were investigated. This method was evaluated experimentally using the NEMA NU2-2001 IEC phantom, the ACNP cardiac phantom, a randomly deformed aluminum can, and a spheroidal shape phantom implemented artificially in the lung, liver, and brain of patient PET images. Clinically, the algorithm was evaluated in six lesions from five patients. Clinical results were compared to CT volumes. RESULTS: This mathematical fit predicts an existing relationship between the PET lesion size and the percent of maximum activity concentration within the target volume (or threshold). It also showed a dependence of the threshold value on the T/B, which could be eliminated by background subtraction. In the phantom studies, the volumes of the segmented PET targets in the PET images were within 10% of the nominal ones. Clinically, the PET target volumes were also within 10% of those measured from CT images. CONCLUSIONS: This iterative algorithm enabled accurately segment PET lesions, independently of their contrast value.

Localization of 131I-labeled p97-specific Fab fragments in human melanoma as a basis for radiotherapy.

33 patients with advanced malignant melanoma were studied after intravenous administration of 131I-labeled Fab fragments specific for p97, an oncofetal glycoprotein of human melanoma. In all, 47 gamma camera imaging studies were performed for the purpose of localization of metastatic deposits. In addition to tumor, 131I-Fab uptake was also seen in liver and kidney. 20 of these studies included simultaneous administration of both an 131I-labeled Fab specific for p97, and an 125I-labeled Fab not specific for p97. Blood clearance of p97-specific Fab was significantly more rapid than for nonspecific Fab. Eight of these patients had biopsies of subcutaneous nodules at 48 and 72 h postinjection in order to assess whether localization of radioactivity was antigen specific. Antigen-specific localization was observed with average ratios of specific/nonspecific uptake of 3.7 (48 h) and 3.4 (72 h); uptake was strongly correlated with tumor p97 concentration (r = 0.81, P less than 0.01). Also, imaging studies of the bio-distribution of 131I-labeled anti-p97 Fab in patients selected for high p97 tumor concentration showed avid tumor uptake and more prolonged retention of labeled Fab in tumor than in normal tissues. Based on these studies, we estimated that total 131I doses of 500 mCi could be safely given to patients before dose-limiting toxicity would be observed. Accordingly, in seven selected patients, phase I radiotherapeutic trials were begun. For improved radiation safety, we developed automated methods to label Fab fragments with up to 200 mCi of 131I. So far, a total of 12 individual therapeutic doses, ranging from 34 to 197 mCi of 131I-labeled to 5 to 10 mg of Fab, have been administered with excellent tumor localization and without major target organ toxicity. Cumulative doses ranged from 132 to 529 mCi 131I. Side effects attributable to the radiation were mild, with a transient drop slightly greater than 50% in platelet and absolute neutrophil counts being observed in the two patients who received cumulative doses greater than 500 mCi. In the combined series of 47 diagnostic and 12 therapeutic studies, four acute reactions were observed: one episode each of transient chills and fever; flushing and hypotension; and two skin rashes. All of these reactions responded promptly to symptomatic therapy. After multiple administrations of 131I-(anti-p97) Fab (IgG1), isotype-specific immunity was observed in three patients. In two of these patients it was possible to successfully reinfuse after immunity had developed with 131I-(anti-p97) Fab of a different isotype (IgG2a). Dosimetry estimates were performed based on the biodistribution of (131)I-Fab in these patients,and for every 100 mCi of (131)I-Fab given, tumor receives 1,040 rads; liver. 325 rads; and bone marrow, 30 rads. Marrow would be expected to be the critical organ, if doses >500 mCi (131)I-Fab are given. These studies demonstrated that, with proper precautions, large doses (of an (131)I-labeled murine Fab fragments immunologically specific for a human melanoma-associated antigen) could be safely given to humans by using repetitive intravenous injections.

Phase and amplitude binning for 4D-CT imaging.

We compare the consistency and accuracy of two image binning approaches used in 4D-CT imaging. One approach, phase binning (PB), assigns each breathing cycle 2pi rad, within which the images are grouped. In amplitude binning (AB), the images are assigned bins according to the breathing signal's full amplitude. To quantitate both approaches we used a NEMA NU2-2001 IEC phantom oscillating in the axial direction and at random frequencies and amplitudes, approximately simulating a patient's breathing. 4D-CT images were obtained using a four-slice GE Lightspeed CT scanner operating in cine mode. We define consistency error as a measure of ability to correctly bin over repeated cycles in the same field of view. Average consistency error mue+/-sigmae in PB ranged from 18%+/-20% to 30%+/-35%, while in AB the error ranged from 11%+/-14% to 20%+/-24%. In PB nearly all bins contained sphere slices. AB was more accurate, revealing empty bins where no sphere slices existed. As a proof of principle, we present examples of two non-small cell lung carcinoma patients' 4D-CT lung images binned by both approaches. While AB can lead to gaps in the coronal images, depending on the patient's breathing pattern, PB exhibits no gaps but suffers visible artifacts due to misbinning, yielding images that cover a relatively large amplitude range. AB was more consistent, though often resulted in gaps when no data existed due to patients' breathing pattern. We conclude AB is more accurate than PB. This has important consequences to treatment planning and diagnosis.

Molecular imaging of EGFR kinase activity in tumors with 124I-labeled small molecular tracer and positron emission tomography.

Positron emission tomography (PET) with epidermal growth factor receptor (EGFR) kinase-specific radiolabeled tracers could provide the means for noninvasive and repetitive imaging of heterogeneity of EGFR expression and signaling activity in tumors in individual patients before and during therapy with EGFR signaling inhibitors. We developed the synthesis and (124)I-radiolabeling of the (E)-But-2-enedioic acid [4-(3-[(124)I]iodoanilino)-quinazolin-6-yl]-amide-(3-morpholin-4-yl-propyl)-amide (morpholino-[(124)I]-IPQA), which selectively, irreversibly, and covalently binds the adenosine-triphosphate-binding site to the activated (phosphorylated) EGFR kinase, but not to the inactive EGFR kinase. The latter was demonstrated using in silico modeling with crystal structures of the wild type and different gain-of-function mutants of EGFR kinases. Also, this was demonstrated by selective radiolabeling of the EGFR kinase domain with morpholino-[(131)I]-IPQA in A431 human epidermoid carcinoma cells and Western blot autoradiography. In vitro radiotracer accumulation and washout studies demonstrated a rapid accumulation and progressive retention postwashout of morpholino-[(131)I]-IPQA in A431 epidermoid carcinoma and in U87 human glioma cells genetically modified to express the EGFRvIII mutant receptor, but not in the wild-type U87MG glioma cells under serum-starved conditions. Using morpholino-[(124)I]-IPQA, we obtained noninvasive PET images of EGFR activity in A431 subcutaneous tumor xenografts, but not in subcutaneous tumor xenografts grown from K562 human chronic myeloid leukemia cells in immunocompromised rats and mice. Based on these observations, we suggest that PET imaging with morpholino-[(124)I]-IPQA should allow for identification of tumors with high EGFR kinase signaling activity, including brain tumors expressing EGFRvIII mutants and nonsmall-cell lung cancer expressing gain-of-function EGFR kinase mutants. Because of significant hepatobiliary clearance and intestinal reuptake of the morpholino-[(124)I]-IPQA, additional [(124)I]-IPQA derivatives with improved water solubility may be required to optimize the pharmacokinetics of this class of molecular imaging agents.

Phase I and imaging trial of indium 111-labeled anti-epidermal growth factor receptor monoclonal antibody 225 in patients with squamous cell lung carcinoma.

Murine monoclonal antibody (MAb) 225 (IgG1) against the epidermal growth factor (EGF) receptor competitively blocks EGF binding and inhibits EGF-induced activation of receptor tyrosine kinase and cell proliferation. The effect of MAb 225 was studied in a phase I trial in patients with inoperable squamous cell carcinoma of the lung, which invariably expresses high levels of EGF receptors. Groups of three patients received total doses of MAb 225 ranging from 1 mg to 300 mg. Except at the lowest dose, each infusion included 4 mg of indium 111 (111In)-labeled MAb 225. No toxicity was observed. Tumors were imaged in all patients who received doses of 20 mg or greater. Presumed metastases greater than or equal to 1 cm in diameter were imaged with doses of 40 mg or greater. Single-photon-emission-computed tomography could be carried out at the 120-mg and 300-mg doses and significantly improved tumor visualization. All patients produced anti-murine antibodies. We conclude that treatment with an MAb that inhibits EGF receptor function is safe at the doses and schedule studied. 111In-labeled MAb images squamous cell lung carcinoma; tumor uptake of the labeled MAb is dose dependent. Further studies are warranted to explore the potential therapeutic efficacy of anti-EGF receptor MAbs and other agents that act in a comparable manner.

Common pathway for tumor cell uptake of gallium-67 and iron-59 via a transferrin receptor.

We studied the tumor uptake of [67Ga]citrate, [59Fe]citrate, and 125I-labeled transferrin (TF) by the in vitro growth form of EMT-6, a sarcoma-like mammary tumor of BALB/c mice. In analyzing the binding experiments, we developed a new mathematical model based on a formulation originally used to express the interaction of hormones with specific tissue receptors. The uptake of both carrier-free 67Ga and 59Fe by tumor cells was mediated by kinetically identical TF receptors. We also studied teric acid extracts of the stroma of EMT-6 tumors grown both in vivo and in vitro. Chromatography of these extracts on Sephacryl S-200 SF demonstrated that the cellular stroma contained specific TF-binding macromolecules. On the basis of these findings, we proposed the "transferrin receptor hypothesis" for the mechanism of 67Ga uptake by tumors. According to this view, a tumor-associated TF receptor is the functional unit responsible for the affinity of gallium for certain neoplasms. This receptor was also active in the uptake of iron by tumors.

Clinical radioimmunodetection, 1978-1988: overview and suggestions for standardization of clinical trials.

In the last decade of radioimmunodetection studies the radiolabeled antibody preparations used have gradually changed from polyclonal antibodies labeled predominantly with 131I to monoclonal antibodies labeled with diverse radionuclides including 131I, 111In, 123I, and 99mTc. Over this period progressive improvement in tumor imaging has been observed when one compares the best examples of early studies, performed with 131I labeled heterosera, to the best of modern images, obtained with 123I, 99mTc, or 111In labeled monoclonal antibodies. Important findings in 61 clinical studies reviewed include the reports from several centers which demonstrate occult disease in patients with carcinoma of colon, melanoma, and lymphoma, and the improved sensitivity and specificity of radioimmunodetection in comparison to transmission computerized tomography in the lymph nodes and abdomen, in lymphoma and colon cancer, and ovarian cancer. Evaluation of the liver remains a difficult problem with this technique and standard approaches are superior in most reports. The general principle of targeting radioactivity to tumor with radiolabeled antitumor antibody and the feasibility of developing practical clinical methodology which will add new diagnostic information have clearly been established. Toxicity, particularly for index studies, is reassuringly limited. In all the studies with surgical confirmation after i.v. injection, uptake in tumor is in the range of 0.005% injected dose/g tumor, and this low tumor uptake remains the single greatest limitation of the method. A second important problem is the prompt development of human anti-mouse antibody, which reduces the usefulness of follow-up studies. A serious criticism of the information currently available on radioimmunodetection is that the clinical studies reported to date vary greatly in approach and results. The vast majority of studies are early Phase I clinical trials, from which toxicity information and biodistribution data can be derived but which give limited information about impact on clinical management. Standardization in the study design is needed in order to establish the efficacy of radioimmunodetection in adequate and well controlled clinical trials.

Improving the balance between treatment and diagnosis: a role for radioimmunodetection.

Despite major advances in diagnostic testing, including the introduction and widespread availability of high-resolution computed tomography (CT) and magnetic resonance imaging, inadequate diagnostic information still interferes with proper management of many patients with cancers. This is particularly true for recurrent colorectal cancer, for example. In the course of this symposium, significant advances have been reported which are likely to improve management of this clinical situation. 111In, oncoscint for colorectal and ovarian cancer imaging, has been approved for single use only, and is a product licensed by the Food and Drug Administration. It has been shown to be significantly more effective than CT for detecting the presence of disease that is confined to the abdomen outside the liver. This agent is very useful in a limited role. A larger opportunity awaits other preparations reported at this conference, especially 99mTc-labeled Immu-4 carcinoembryonic antigen, which is significantly better than CT for determining resectability of recurrent cancer (T. Behr et al., Cancer Res. 55 (Suppl.): 5777S-5785S, 1995). The 99mTc-labeled compound preparations offer the advantages of low immunogenicity, excellent imaging energies of 99mTc, and "same-day" imaging. Even the most effective cancer treatment such as surgical resection, if applied to a patient who basically does not need it, can be a needless expense and a trauma to the patient. To date, our emphasis in oncology research has been heavily weighted toward developing new therapies. The success of radioimmunodetection is one indication of why it is time for a paradigm shift, during which we can move toward a more balanced program that emphasizes both diagnosis and therapy. To achieve this we must urge research institutions such as the National Cancer Institute and American Cancer Society to make major investments in the diagnostic aspects of cancer care. With the knowledge base that we have now, we can make improvements in patient care by emphasizing development of improved diagnostic methods and support for cost-effectiveness studies for developed methods, in order that currently available treatments can be more intelligently applied.

Prolonged binding of a radiolabeled monoclonal antibody (B72.3) used for the in situ radioimmunodetection of human colon carcinoma xenografts.

Monoclonal antibody B72.3 binds to a glycoprotein complex with a molecular weight of 220,000 to 400,000. B72.3 reacts with approximately 50% of human mammary carcinomas and to 80% of the colon carcinomas tested but does not react appreciably with normal mammary tissue, with normal colon, or to a variety of normal adult human tissues tested using immunohistochemical techniques. B72.3 immunoglobulin G was purified and radiolabeled with 125I without significant loss in its reactivity to tumor extracts. The radiolabeled B72.3 immunoglobulin G was shown to efficiently localize human colon carcinoma xenografts in athymic mice. Tumor:tissue ratios of the localized antibody rose over the 7-day period studied, with tumor:liver, tumor:spleen, or tumor:kidney ratios of approximately 18:1 at Day 7 and a tumor:blood ratio of approximately 5:1 at Day 7. Tumor:muscle or tumor:brain ratios rose to over 100:1. The amount of radioactivity in the tumor increased for the first 2 days postinoculation of antibody and stayed constant over a 19-day period of study. Thus, there was no appreciable loss of radioiodine from the tumor over the study interval. No localization was seen in mice bearing a B72.3 antigen-negative human melanoma xenograft or with an isotype-identical control immunoglobulin G in mice bearing colon tumor xenografts. Gamma camera imaging with a pinhole collimator confirmed the ability of the radiolabeled antibody to detect the presence of colon carcinoma xenografts less than 0.5 cm in diameter over a 19-day period. The potential use of this system as a model for radioimmunotherapy will be discussed.

Innovations that influence the pharmacology of monoclonal antibody guided tumor targeting.

Tumor targeting by monoclonal antibodies (MAbs) can be enhanced by (a) increasing the percentage of injected dose taken up by the tumor and/or (b) increasing the tumor:nontumor ratios. Several groups have demonstrated that one can increase tumor to nontumor ratios by the use of antibody fragments or the administration of second antibodies. Several other modalities are also possible: (a) the use of recombinant interferons to up-regulate the expression of specific tumor associated antigens such as carcinoembryonic antigen or TAG-72 on the surface of carcinoma cells and thus increase MAb tumor binding has proved successful in both in vitro and in vivo studies; (b) the intracavitary administration of MAbs. Recent studies have demonstrated that when radiolabeled B72.3 is administered i.p. to patients with carcinoma of the peritoneal cavity, it localizes tumor masses with greater efficiency than does concurrent i.v. administered antibody. Studies involving the comparative pharmacology of intracavitary administration of radiolabeled MAb in patients and several animal models will be discussed; (c) it has been reported that prior exposure of hepatoma to external beam radiation will increase radiolabeled MAb tumor targeting. We and others have not been able to duplicate this phenomenon with a human colon cancer xenograft model and radiolabeled MAbs to two different colon carcinoma associated antigens. The possible reasons for these differences will be discussed; (d) the cloning and expression of recombinant MAbs with human constant regions and subsequent size modification constructs will also undoubtedly alter the pharmacology of MAb tumor binding in both diagnostic and therapeutic applications.

Complementation of intracavitary and intravenous administration of a monoclonal antibody (B72.3) in patients with carcinoma.

Monoclonal antibody (MAb) B72.3 has been shown to have selective reactivity for a wide range of carcinomas (colorectal, ovarian, breast, lung, gastric, and endometrial) versus normal adult tissues. 131I-Labeled B72.3 IgG has recently been shown to selectively bind carcinoma lesions when administered i.v. in patients with metastatic colorectal cancer. We report here the first direct comparison of i.p. administered [131I]B72.3 IgG to specifically localize metastatic carcinoma. Three of 10 patients studied were negative for tumor detection by both CAT scan and X-ray but were positive for tumor localization via gamma scanning i.p. administered 131I-labeled MAb B72.3 IgG. Direct analyses of biopsy specimens of carcinoma and normal tissues demonstrated ratios of greater than 70:1 (based on percentage of injected dose/mg) for tumor MAb localization versus normal tissues. Specificity of [131I]B72.3 tumor targeting was demonstrated by the concomitant administration of an equal dose of an 125I-labeled isotype identical (IgG1) control MAb. Simultaneous i.p. administration of [131I]B72.3, and i.v. administration of [125I]B72.3 in individual patients demonstrated: peritoneal implants are targeted more efficiently via i.p. MAb administration, and hematogenously spread and lymph node metastases as well as local recurrences are targeted more efficiently by i.v. administered MAb. No antibody toxicity was observed in any patients. Pharmacokinetics of MAb clearance demonstrated that only 10 to 30% of the i.p. administered MAb was found in plasma. These studies thus demonstrate the efficacy of intracavitary MAb administration as well as the advantage of the concomitant use of intracavitary and i.v. administered MAbs for tumor targeting and for potential MAb guided therapy of metastatic carcinoma.

Quantitative analyses of selective radiolabeled monoclonal antibody localization in metastatic lesions of colorectal cancer patients.

We have previously demonstrated, using in vitro assays, a high degree of selective binding of monoclonal antibody (MAb) B72.3 for carcinomas of the colon, ovary, and breast versus normal adult tissues using in vitro assays. We report here a demonstration of selective tumor localization in colorectal cancer patients of i.v. administered 131I-labeled MAb B72.3 immunoglobulin G prior to surgery. Radiolocalization indices (RI) were obtained by direct analyses of biopsy materials (i.e., cpm of 131I-labeled MAb per g of tumor versus cpm per g of normal tissues). Using as a "positive" localization, RI of 3 times greater than normal tissue (i.e., RI greater than 3.0), tumor lesions in various sites from 17 of 20 patients scored positive. In eight of these patients, all tumor lesions demonstrated RIs of greater than 3, while in five patients RIs of some lesions were greater than 10 and as high as 30 to 46. Seventy % (99 of 142) of tumor lesions showed RIs of greater than 3, while only 12 of 210 histologically confirmed normal tissues examined showed RIs of greater than 3. These tissues, moreover, were either adjacent to tumor or draining tumor masses, or, as in the case of two patients, apparently due to high levels of circulating immune complexes that were deposited in the spleen. Positive gamma scans (confirmed at surgery) were observed in 14 of 27 patients. An isotype-identical control immunoglobulin G was coinjected and showed RIs considerably lower than that of B72.3. No toxicity or adverse reaction was observed with either MAb. These studies are among the most comprehensive to date concerning the definition of the actual delivery of radiolabeled MAb to carcinoma lesions versus a wide range of adjacent and distal normal tissues and lead the way for other diagnostic and potential therapeutic applications of this antibody either alone, or in combinations with other monoclonal antibodies.