Higher dose and dose-rate in smaller tumors result in improved tumor control.

Small tumors are more sensitive to radioimmunotherapy (RIT) than larger ones. A greater proportion of viable radiosensitive areas in small tumors, higher antibody uptake, and radiation dose may be responsible. Six groups of mice with small (median tumor size 0.06 cm3) or large LoVo xenografts (median tumor size 0.38 cm3) received either RIT using a 131I-labeled anti-CEA antibody A5B7, 5-fluorouracil (5-FU) modulated with folinic acid (FA), or no treatment. The % injected activity/gram, antibody distribution in viable and necrotic areas, and dose distribution were determined. High-power microscopy images of the original section were reconstructed to estimate the proportion of viable areas. Mice with small and large tumors grew significantly less rapidly when treated with RIT compared to the control group (p < 0.0004 and p < 0.003, respectively), while 5-FU was ineffective. Small tumors treated with RIT grew less than large tumors (p < 0.02). A higher amount of % injected activity/gram of tumor (median 26.6% vs. 8.1%, p = 0.0007) and a higher dose-rate were found in small tumors at 24 hours post injection (viable areas: 56.2 +/- 23.7 vs. 13.3 +/- 7 cGy/h, necrosis 19.2 +/- 16.3 vs. 4.9 +/- 4.7 cGy/h, p = 0.0007). It appears that as viable tumor masses grow the access to them decreases and this has a fourfold effect on dose delivered for RIT in this example. These data support the consideration of use of RIT for adjuvant treatment in colon cancer.

Spatial accuracy of 3D reconstructed radioluminographs of serial tissue sections and resultant absorbed dose estimates.

Many agents using tumour-associated characteristics are deposited heterogeneously within tumour tissue. Consequently, tumour heterogeneity should be addressed when obtaining information on tumour biology or relating absorbed radiation dose to biological effect. We present a technique that enables radioluminographs of serial tumour sections to be reconstructed using automated computerized techniques, resulting in a three-dimensional map of the dose-rate distribution of a radiolabelled antibody. The purpose of this study is to assess the reconstruction accuracy. Furthermore, we estimate the potential error resulting from registration misalignment, for a range of beta-emitting radionuclides. We compare the actual dose-rate distribution with that obtained from the same activity distribution but with manually defined translational and rotational shifts. As expected, the error produced with the short-range 14C is much larger than that for the longer range 90Y; similarly values for the medium range 131I are between the two. Thus, the impact of registration inaccuracies is greater for short-range sources.

Antibody and radionuclide characteristics and the enhancement of the effectiveness of radioimmunotherapy by selective dose delivery to radiosensitive areas of tumour.

PURPOSE: Estimating the absorbed dose to tumour relative to normal tissues has often been used in the assessment of the therapeutic efficacy of radiolabelled antibodies for radioimmunotherapy. Typically, the calculations assume a uniform dose deposition and response throughout the tumour. However, the heterogeneity of the dose delivery and response within tumours can lead to a radiobiological effect inconsistent with dose estimates. The aim was to assess the influence of antibody and radionuclide characteristics on the heterogeneity of dose deposition. MATERIALS AND METHODS: Quantitative images of the temporal and spatial heterogeneity of a range of antibodies in tumour were acquired using radioluminography. Subsequent registration with images of tumour morphology then allowed the delineation of viable and necrotic areas of tumour and the measurement of the antibody concentration in each area. A tumour dosimetry model then estimated the absorbed dose from 131I and 90Y in each area. RESULTS: Tumour-specific antibodies initially localized in the viable radiosensitive areas of tumour and then penetrated further into tumour with continued tumour accretion. Multivalent antibodies were retained longer and at higher concentrations in viable areas, while monovalent antibodies had greater mobility. In contrast, non-specific antibodies penetrated into necrotic regions regardless of their size. As a result, multivalent, specific antibodies delivered a significantly larger dose to viable cells compared with monovalent antibodies, while non-specific antibodies deposited most of the dose in necrotic areas. There was a significant difference in dose estimates when assuming a uniform dose deposition and accounting for heterogeneity. The dose to the viable and necrotic areas also depended on the properties of the radionuclide where antibodies labelled with 131I generally delivered a higher dose throughout the tumour even though the instantaneous dose-rate distribution for 90Y was more uniform. CONCLUSIONS: The extent of heterogeneity of dose deposition in tumour is highly dependent on the antibody characteristics and radionuclide properties, and can enhance therapeutic efficacy through the selective dose delivery to the radiosensitive areas of tumour.

Relationship between tumour morphology, antigen and antibody distribution measured by fusion of digital phosphor and photographic images.

Antibody-directed cancer therapy has achieved encouraging responses despite poor localisation in tumour. This discrepancy may be attributed to heterogeneity of antibody delivery within tumours: preferential localisation in the better perfused and more radio- and chemosensitive areas provides a therapeutic advantage. Antibody distribution depends upon the interactions of many complex mechanisms. We have started to investigate this by studying the single and combined influence of two tumour-associated parameters, morphology and antigen, on antibody distribution. Tumours were taken from mice at 24 and 48 h after 125I-labeled anti-CEA antibody injection. Images of antibody distribution, antigen distribution and tumour morphology were acquired by radioluminography, radioimmunoluminography and digitisation of morphology, respectively. Image registration allowed correlation of pixel values of antibody distribution with corresponding values of antigen distribution and morphology. At 24 h there was little correlation between antibody and antigen distribution, but strong positive correlation between antibody distribution and morphology, with preferential localisation in viable tumour areas. Correlation between antibody distribution and morphology fell significantly between 24 and 48 h, while that between antibody and antigen distribution remained low. However, the combination of morphology and antigen distribution showed the largest influence on antibody distribution. This novel technique demonstrates potential for combining multi-factor information in order to provide a greater understanding of antibody distribution in tumours, facilitating the optimisation of clinical treatments.

A mouse model for calculating the absorbed beta-particle dose from (131)I- and (90)Y-labeled immunoconjugates, including a method for dealing with heterogeneity in kidney and tumor.

Flynn, A. A., Green, A. J., Pedley, R. B., Boxer, G. M., Boden, R. and Begent, R. H. J. A Mouse Model for Calculating the Absorbed Beta-Particle Dose from (131)I- and (90)Y-Labeled Immunoconjugates, Including a Method for Dealing with Heterogeneity in Kidney and Tumor. Radiat. Res. 156, 28-35 (2001). Conventional internal radiation dosimetry methods assume that the beta-particle energy is absorbed uniformly and completely in the source organ and that the radioactivity is distributed uniformly in the source. However, in mice, a considerable proportion of the beta-particle energy can escape the source organ, resulting in large cross-organ doses. Furthermore, the distribution of radioactivity is generally heterogeneous in kidney and tumor. Therefore, a model was developed to account for cross-organ doses and for the effects of heterogeneity in kidney and tumor in mice for two of the most important radionuclides used in therapy, (131)I and (90)Y. Most mouse organs were modeled as single-compartment ellipsoids or cylinders, while heterogeneity in kidney and in tumor was addressed by using two compartments to represent the cortex and the medulla and viable and necrotic cells, respectively. The dimensions of these models were taken from previous studies, with the exception of kidney and tumor, which were defined using radioluminography and mosaics of high-power microscopy images. The absorbed fractions in each compartment were calculated using beta-particle point dose kernels. The self-organ dose was significantly higher for (131)I compared to (90)Y in all compartments, but a considerable amount of beta-particle energy was shown to escape the source organ for both radionuclides, with as much as 85% and 36% escaping the marrow for (90)Y and (131)I, respectively. The cortex was found to occupy a greater proportion of the total kidney volume than the medulla, and consequently the self-dose was higher in the cortex. In addition, the thickness of the viable shell in the tumor increased with tumor size, as did the self-dose fractions in both necrotic and viable areas. This dosimetry model improves dose estimates in mice and gives a conceptual basis for considering dosimetry in humans.

Eradication of colorectal xenografts by combined radioimmunotherapy and combretastatin a-4 3-O-phosphate.

Solid tumors have a heterogeneous pathophysiology, which has a major impact on therapy. Using SW1222 colorectal xenografts grown in nude mice, we have shown that antibody-targeted radioimmunotherapy (RIT) effectively treated the well-perfused tumor rim, producing regressions for approximately 35 days, but was less effective at the more hypoxic center. By 72 h after RIT, the number of apoptotic cells rose from an overall value of 1% in untreated tumors to 35% at the tumor periphery and 10% at the center. The antivascular agent disodium combretastatin A-4 3-O-phosphate (CA4-P) rapidly reduced tumor blood flow to 62% of control values by 1 h, 23% by 3 h, and between 32-36% from 6 to 24 h after administration. This created central hemorrhagic necrosis, but a peripheral rim of cells continued to grow, and survival was unaffected. Changes in the pattern of perfusion across the tumor over time were zonal. Untreated mice showed perfusion throughout the tumor, with greatest activity at the rim. There was an overall reduction at 1 h, and total cessation of central perfusion from 3 h onward. A narrow peripheral rim of perfusion was always present, which increased in intensity and extent between 6 and 24 h, either through reperfusion or new vessel growth. Combining these two complementary therapies (7.4 MBq (131)I-labeled anti-carcinoembryonic antigen IgG i.v. plus a single 200 mg/kg dose of CA4-P i.p.) produced complete cures in five of six mice for >9 months. Allowing maximal tumor localization of antibody (48 h) before blood flow inhibition by CA4-P increased tumor retention by two to three times control levels by 96 h without altering normal tissue levels, as confirmed by gamma counting and phosphor image analysis. The success of this combined, synergistic therapy was probably the result of several factors: (a) the killing of tumor cells in the outer, radiosensitive region by targeted radiotherapy; (b) enhancement of RIT by entrapment of additional radioantibody after combretastatin-induced vessel collapse; and (c) destruction of the central, more hypoxic and radioresistant region by CA4-P. This work demonstrates the need to consider cancer treatment in a biologically heterogeneous setting, if results are to be effectively translated to the clinic.

Effectiveness of radiolabelled antibodies for radio-immunotherapy in a colorectal xenograft model: a comparative study using the linear--quadratic formulation.

PURPOSE: To develop a model that relates the pattern of dose delivery during radio-immunotherapy to biological effect. This model was used to assess the efficacy of a range of antibodies labelled with 131I, 186Re and 90Y. MATERIALS AND METHODS: Pharmacokinetic data were obtained by injecting tumour-bearing nude mice with radiolabelled antibody. The dose-rate in bone marrow and tumour was then given by a two-compartment model description of the pharmacokinetics combined with the radionuclide properties. Response characteristics of tumour and marrow were defined in terms of radiosensitivity, repair capacity and proliferation, and the biological effect was assessed using the linear quadratic formulation. RESULTS: Tumour-specific antibodies with intermediate molecular weight and clearance from the circulation delivered the most effective doses to tumour due to their rapid uptake and prolonged retention in tumour coupled with efficient clearance from blood. Matching the radionuclide with antibody pharmacokinetics and tumour type further increased this effect. CONCLUSIONS: The model improves conceptual understanding of the relationship of parameters affecting therapy and makes it possible to optimize radio-immunotherapy by selecting the most effective antibody and radionuclide according to tumour biology.

Optimizing radioimmunotherapy by matching dose distribution with tumor structure using 3D reconstructions of serial images.

The biological effect of radioimmunotherapy (RIT) is most commonly assessed in terms of the absorbed radiation dose. In tumor, conventional dosimetry methods assume a uniform radionuclide and calculate a mean dose throughout the tumor. However, the vasculature of solid tumors tends to be highly irregular and the systemic delivery of antibodies is therefore heterogeneous. Tumor-specific antibodies preferentially localize in the viable, radiosensitive parts of the tumor whereas non-specific antibodies can penetrate into the necrosis where the dose is wasted. As a result, the observed biological effect can be very different to the predicted effect from conventional dose estimates. The purpose of this study is to assess the potential for optimizing the biological effect of RIT by matching the dose-distribution with tumor structure through the selection of appropriate antibodies and radionuclides. Storage phosphor plate technology was used to acquire images of the antibody distribution in serial tumor sections. Images of the distributions of a trivalent (TFM), bivalent (A5B7-IgG), monovalent (MFE-23) and a non-specific antibody (MOPC) were obtained. These images were registered with corresponding images showing tumor morphology. Serial images were reconstructed to form 3D maps of the antibody distribution and tumor structure. Convolution of the image of antibody distribution with beta dose point kernals generated dose-rate distributions for 14C, 131I and 90Y. These were statistically compared with the tumor structure. The highest correlation was obtained for the multivalent antibodies combined with 131I, due to specific retention in viable areas of tumor coupled with the fact that much of the dose was deposted locally. With decreasing avidity the correlation also decreased and with the non-specific antibody this correlation was negative, indicating higher concentrations in the necrotic regions. In conclusion, the dose distribution can be optimized in tumor by selecting the appropriate antibodies and radionuclides. This has the potential to lead to a considerable enhancement of the efficacy of RIT in the clinic.

Recombinant anti-carcinoembryonic antigen antibodies for targeting cancer.

Antibodies can be used to target cancer therapies to malignant tissue; the approach is attractive because conventional treatments such as chemo- and radiotherapy are dose limited due to toxicity in normal tissues. Effective targeting relies on appropriate pharmacokinetics of antibody-based therapeutics, ideally showing maximum uptake and retention in tumor and rapid clearance from normal tissue. We have studied the factors influencing these dynamics for antibodies against carcinoembryonic antigen (CEA). Protein engineering of anti-CEA antibodies, in vivo biodistribution models, and mathematical models have been employed to improve understanding of targeting parameters, define optimal characteristics for the antibody-based molecules employed, and develop new therapies for the clinic. Engineering antibodies to obtain the desired therapeutic characteristics is most readily achieved using recombinant antibody technology, and we have taken the approach of immunizing mice to provide high-affinity anti-CEA single-chain Fv antibodies (sFvs) from filamentous bacteriophage libraries. MFE-23, the most characterized of these sFvs, has been expressed in bacteria and purified in our laboratory for two clinical trials: a gamma camera imaging trial using 123I-MFE-23 and a radioimmunoguided surgery trial using 125I-MFE-23, where tumor deposits are detected by a hand-held probe during surgery. Both these trials showed that MFE-23 is safe and effective in localizing tumor deposits in patients with cancer. We are now developing fusion proteins that use the MFE-23 antibody to deliver a therapeutic moiety; MFE-23:: carboxypeptidase G2 (CPG2) targets the enzyme CPG2 for use in the antibody-directed enzyme prodrug therapy system and MFE::tumor necrosis factor alpha (TNFalpha) aims to reduce sequestration and increase tumor concentrations of systemically administered TNFalpha.

Radioimmunoguided surgery in colorectal cancer using a genetically engineered anti-CEA single-chain Fv antibody.

In radioimmunoguided surgery (RIGS), a radiolabeled antibody is given i.v. before surgery and a hand-held gamma-detecting probe is used to locate tumor in the operative field. The rapid blood clearance and good tumor penetration of single-chain Fv antibodies (scFv) offer potential advantages over larger antibody molecules used previously for RIGS. A Phase I clinical trial is reported on RIGS with scFv (MFE-23-his) to carcinoembryonic antigen (CEA). Thirty-four patients undergoing surgery for colorectal carcinoma (17 primary tumors, 16 liver metastases, and 1 anastomotic recurrence) and 1 patient with liver metastases of pancreatic carcinoma received 125I-labeled MFE-23-his scFv (125I-MFE-23-his) 24, 48, 72, or 96 h before operation. 125I-MFE-23-his showed biexponential blood clearance with alpha and beta half-lives of 0.32 and 10.95 h, respectively. The abdomen was scanned during surgery with a hand-held gamma detecting probe (Neoprobe Corp.). 125I-MFE-23-his showed good tumor localization; comparison with histology showed overall accuracy of 84%. Highest median ratios for tumor:normal tissue and tumor:blood were recorded 72 or 96 h after scFv injection for patients undergoing resection of liver metastases. High levels of radioactivity were found in the kidneys. Five patients had grade 1 fever, and three had a grade 1 rise in blood pressure according to the Common Toxicity Criteria. There was a significant correlation between these ratios and those measured in excised tissues using a laboratory gamma counter (P < 0.001). MFE-23-his scFv antibody localizes in CEA-producing carcinomas. The short interval between injection and operation, the lack of significant toxicity, and the relatively simple production in bacteria make MFE-23-his scFv suitable for RIGS.

Clinical applications of phage-derived sFvs and sFv fusion proteins.

Single chain Fv antibodies (sFvs) have been produced from filamentous bacteriophage libraries obtained from immunised mice. MFE-23, the most characterised of these sFvs, is reactive with carcinoembryonic antigen (CEA), a glycoprotein that is highly expressed in colorectal adenocarcinomas. MFE-23 has been expressed in bacteria and purified in our laboratory for two clinical trials; a gamma camera imaging trial using 123I-MFE-23 and a radioimmunoguided surgery trial using 125I-MFE-23, where tumour deposits are detected by a hand-held probe during surgery. Both these trials show MFE-23 is safe and effective in localising tumour deposits in patients with cancer. We are now developing fusion proteins which use MFE-23 to deliver a therapeutic moiety; MFE-23::CPG2 targets the enzyme carboxypeptidase G2 (CPG2) for use in the ADEPT (antibody directed enzyme prodrug therapy) system and MFE::TNF alpha aims to reduce sequestration and increase tumor concentrations of systemically administered TNF alpha.

A comparison of image registration techniques for the correlation of radiolabelled antibody distribution with tumour morphology.

Image registration is a powerful tool for correlating functional images with images of anatomical structure. This facilitates more accurate quantitation of regional radiopharmaceutical uptake. Similarly, registration of images of radiolabelled antibody distribution, in tissue sections, with the equivalent histological images allows the comparison and measurement of radiopharmaceutical distribution with morphological structure. The images used were obtained by storage phosphor plate technology, for the radiopharmaceutical distribution, and by digitization of the stained histological sections. Here we compare four fully automatic registration techniques and one manual technique in terms of their spatial accuracy. We have found that there was no difference in accuracy between cross-correlation, minimization of variance and mutual information. These techniques were more accurate than principal axes and the manual technique. However, minimization of variance and mutual information were more time-consuming than the other methods. Consequently, cross-correlation is the method of choice for automatic registration of large numbers of these image pairs.

A novel technique, using radioluminography, for the measurement of uniformity of radiolabelled antibody distribution in a colorectal cancer xenograft model.

PURPOSE: Radioimmunotherapy of cancer employs an antitumour antibody to carry a radionuclide selectively to deposits of cancer. Conventional dose estimates, based on the Medical Internal Radiation Dose (MIRD) formulation, assume uniform distribution of radiolabelled antitumour antibody within tissue source regions. This assumption has been tested by using a statistical model to predict the pixel value distribution obtained from the digitised radioluminographs of a known radioactive source. The model uses the statistical nature of the detection of radiation where any uniform source distribution can be expected to have a detected histogram of pixel counts that is normal or Gaussian. Therefore, any test for the degree of normality in the detected distribution is also a measure of the degree of uniformity in the source. METHODS AND MATERIALS: Three statistical techniques have been used to test the normality of the histogram of pixel values produced from the antibody distribution in a tissue section. Kurtosis, skew, and Lilliefor's are tests for normality and have statistically defined critical values for a normal distribution. After administration of 125I-labelled F(ab)2 antibody to nude mice bearing the LS174T colorectal cancer xenograft, the uniformity of antibody distribution in tumour and healthy tissues is measured using the radioluminographs of formalin-fixed paraffin sections. The test statistic for kurtosis, skew, and Lilliefor's is calculated for each tissue and is compared to critical values from statistical tables. RESULTS: The radiolabelled antibody is distributed uniformly in liver, spleen, muscle, lung, and colon and, therefore, conforms to conventional use of the MIRD formulation. The study showed that the kidney cortex and medulla should be considered separately in macroscopic absorbed-dose calculations, as should bone marrow and hard bone. Antibody heterogeneity in the tumour necessitates the incorporation of a microdosimetric tumour model into a macrodosimetry model for the accurate calculation of absorbed dose in all tissues.

Taking engineered anti-CEA antibodies to the clinic.

There is a need to improve on existing targeting technologies in order to develop effective cancer therapy. We have investigated this for colorectal cancer using antibodies directed against carcinoembryonic antigen (CEA). Chemical and molecular protein engineering has been used to produce antibody molecules which differ in molecular weight, affinity, valency and specificity. These have been characterised and tested in animal tumour models and clinical trials to test the parameters important for optimising tumour penetration, increasing residence time in viable areas of the tumour, accelerating clearance from normal tissues and improving therapeutic efficacy.

Ablation of colorectal xenografts with combined radioimmunotherapy and tumor blood flow-modifying agents.

Radioimmunotherapy (RIT) does not readily eradicate common solid tumors and therefore requires augmentation by complementary therapies that do not increase normal tissue damage. We have examined the efficacy of RIT combined with 5,6-dimethylxanthenone-4-acetic acid (DMXAA), a drug which induces immunomodulation and cytokine production and preferentially reduces tumor blood flow, using a colorectal xenograft model in nude mice. Although an optimal i.p. dose (27.5 mg/kg) of drug alone induced massive hemorrhagic necrosis of all but a thin peripheral rim of viable tumor cells, survival was unaffected. However, when combined with i.v. 18.5 MBq 131I-labeled anti-carcinoembryonic antigen IgG, DMXAA significantly potentiated the RIT without increased toxicity, with five of six mice showing complete cures. Scheduling was critical because the antibody must be allowed to reach maximum tumor accumulation before initiation of drug-induced blood flow inhibition. Subsequently, the antibody was retained preferentially in the tumor, reaching approximately twice control levels by 5 days after drug delivery. In combined studies, the drug had a narrow therapeutic window, 30 mg/kg being toxic to two of six mice, whereas 20 mg/kg were ineffective. However, the addition of a second vasoactive agent, serotonin, to RIT plus 20 mg/kg DMXAA enhanced therapy without increasing systemic toxicity. Tumor histology and phosphor image plate analysis reflected these results. When given without RIT, the two drugs combined, although not alone, also significantly inhibited tumor growth. Drug-induced tumor necrosis and tumor retention of radioantibody may both contribute to the enhanced RIT produced by this combined complementary therapy.