Boron neutron capture therapy (BNCT) is a bimodal form of radiation therapy for cancer. The first component of this treatment is the preferential localization of the stable isotope {sup 10}B in tumor cells by targeting with boronated compounds. The tumor and surrounding tissue is then irradiated with a neutron beam resulting in thermal neutron/{sup 10}B reactions ({sup 10}B(n,{alpha}){sup 7}Li) resulting in the production of localized high LET radiation from alpha and {sup 7}Li particles. These products of the neutron capture reaction are very damaging to cells, but of short range so that the majority of the ionizing energy released is microscopically confined to the vicinity of the boron-containing compound. In principal it should be possible with BNCT to selectively destroy small nests or even single cancer cells located within normal tissue. It follows that the major improvements in this form of radiation therapy are going to come largely from the development of boron compounds with greater tumor selectivity, although there will certainly be advances made in neutron beam quality as well as the possible development of alternative sources of neutron beams, particularly accelerator-based epithermal neutron beams

Chanana, A. D.

Coderre, J. A.

Joel, D. D.

UNT Digital Library

.-- = 'I BORON NEUTRON CAPTURE THERAPY OF MALIGNANT BRAIN TUMORS AT THE BROOKHAVEN MEDICAL RESEARCH REACTOR D.D. Joel, J.A. Coderre and A.D. Chanana Medical Department Brookhaven National Laboratory Upton, NY 1 1973 INTRODUCI'ION Boron neutron capture therapy (BNCT) is a bimodal form of radiation therapy for cancer. The first component of this treatment is the preferential localization of the stable isotope '93 in tumor cells by targeting with boronated compounds. The tumor and surrounding tissue is then irradiated with a neutron beam resulting in thermal neutron/'% reactions ('%(~,CY)~L~) resulting in the production of localized high LET radiation from alpha and 7Li particle:. These products of the neutron capture reaction are very damaging to cells, but of short range (each less than 10 pm) so that the majority of the ionizing energy released is microscopically confined to the vicinity of the boron-containing compound. In principal it should be possible with BNCT to selectively destroy small nests or even single cancer cells located within normal tissue. It follows that the major improvements in this form of radiation therapy are going to come largely from the development of boron compounds with greater tumor selectivity, although there will certaidy be advances made in neutron beam quality as well as the possible development of alternative sources of neutron beams, particularly accelerator-based epithermal neutron beams. i I_- , -  ~ "~ DISCLAIMER This report was prepared as a n  account of work spornored by a n  agency of the United States Government. Neither the United States Government nor any agency thereof, nor any of their employees, make any warranty, express or implied, or assumes any legal liabili- ty or respomibility for the accuracy, completeness, or usefulness of any information, appa- ratus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, o r  service by trade name, trademark, manufacturer, or otherwise does not necessarily comlitute or imply its endorsement, recommendation, or favoring by the United States Government or any agency thereof. The views and opinions of authors expressed herein do not necesSar- ily state or reflect those of the United States Government or  any agency thereof. Portions of this document may be illegible in electronic image products. Images are produced from the best avdable origind document. Clinical trials of BNCT in the treatment of brain tumors were conducted at the Brookhaven Graphite Research Reactor between 1951 and 1959 (28 patients) and subsequently at the specially designed Brookhaven Medical Research Reactor (BMRR) between 1959 and 1961 (see review by Slatkin'). These early clinical trials were considered largely unsuccessful in that; there was no evidence of life extension; nonhealing ulceration of the skin developed in some patients; and in an effort to increase the radiation dose to deep seated tumors, four patients died as a result of the therapy . It is generally believed that two major deficiencies led to the disappointing results of the first clinical trials. (1) The use of low-energy thermal neutron beams resulted in the peak neutron flux at the surface of the head, followed by an exponential decline so that the neutron flux at tumor depth was insufficient. (2) The compounds employed at that time did not provide the required selective accumulation of boron in the tumor. In this context, two important developments have occurred since 1961. First, through the use of appropriate filters and modulators the mean energy of the neutron beam at the BMRR was made slightly higheI.2~~~ concurrent with the suppression of the thermal neutron flux. This modified beam, referred to as an epithermal neutron beam, results in a lower incident thermal neutron flux at the surface of the head, with increased thermal neutron fluxes at depth in the brain. A second major advance has been the development of boron compounds which yield greater concentrations of 'OB in the tumor as compared to those in surrounding normal brain tissues. Although several classes of boron delivery agents are in various stages of development (see review by Barth, et alp), including boronated porphyrins, nucleosides, amino acids, polyamines, monoclonal and bispecific antibodies, liposomes, and growth factors, only two boron compounds currently are being used clinically, sodium borocaptate (BSH) and p-boronophenylalanine (BPA). BPA was originally synthesized in 1957 for potential use in BNCT of rapidly growing neoplasms5. It is an analog of the amino acid tyrosine, a precursor for melanin synthesis, and has been employed by the Japanese in the BNCT treatment of melanomas6. The use of BPA as a boron carrier for BNCT of malignant brain tumors was largely developed at Brookhaven using animal tumor models, particularly a transplantable malignant brain tumor in rats referred to as the 9L gliosarc~rna~-~. BPA-Based BNCI' Preclinical Investigation BPA is a non-toxic, metabolic compound that is actively transported across the blood-brain-barrier (BBB) and therefore has the potential for accumulation in islets or streamers of tumor cells that are otherwise protected by the BBB. It is thought that these islets of tumor cells lying outside the main body of the tumor are the sites of the majority of recurrences following conventional radiation and/or chemotherapy. Because of its insolubility in aqeous solutions, BPA was first given orally. Later methods were developed, first by the Japanese'O and then modified by scientists at Idaho State University" and Brookhaveng, to solubilize BPA by complexing it with fructose. Currently, the BPA-fructose complex (BPA-F) is administered systemically to both animals and humans. When rats bearing intracerebral gliosarcomas are injected with BPA-F. tumo; boron concentrations greater than 50 pg/g are readily achieved with tumor-to-bloor: and tumor-to-brain ratios of about 4 to 1. The biochemical mechanism(s) responsible for the selective uptake of BPA in cells of primary brain tumors is not fully understood but may, in part, be related to their high metabolic activity. BPA, is an animo acid analog, and is actively transported across the tumor cell membrane by the neutral amino acid transport system. When the heads of tumor-bearing, BPA-F injected rats are exposed at the optimal post-injection time to neutron irradiation (BNCT), long-term survivals (cures) were obtained in the absence of demonstrable damage to normal brain, i.e., selective ablation of the malignant brain tumor**. The fraction of rats "cured' by BNCT (as high as 90%) was radiation-dose dependent, with a steep response seen between 22.5 Gy and 60 Gy-Eq (see Figure 1). , Clinical Investigations After extensive studies in animals on the efficacy and toxicity of BPA-F, an FDA-sanctioned protocol to study the biodistribution of BPA-F in human patients scheduled to undergo surgical debulking of their malignant brain tumor was initiated in January, 1994. These studies were done in collaboration with the Beth Israel Medical Center in New York City. Patients were infused intravenously with BPA-F Figure 1. Survival of rats bearing intracerebral 9L gtiosarcomas as a function of time after tumor implantation. The median survival of untreated controls (n = 18) was 22 days. All irradiations were performed on day 14 after tumor implantation. Rats treated with 22.5 Gy of 250 kVp X rays (n = 55) had a median survival of 35 days with 20% long-term survivors. Rats treated with 75 MW-min of reactor irradiation following oral administration of BPA (BPA + 7 5  MW-min, n = l2) showed 50% long-term survivors. Rats treated with PPA-F and either 4.2 (n = 14) or 7.8 (n = 14) MW-min of reactor irradiation showed 85% and 93% long-term survivors. IGy-Eq is equal to the physical absorbed dose (Gy) times an experimentally determined biological effectiveness factor for each dose component”, including boron capture [’OB(n,a)’Li], fast neutrons [‘H(n,n’)p], nitrogen capture [“N(II,~)’~CJ and gamma rays. over the 2-hour period just prior to the beginning of surgery. Samples of tumor removed by the neurosurgeon were analyzed for boron content and sections of these specimens were taken for histopathology. In the first group of subjects studied, it was observed that boron concentration in tumor samples vaned considerably among patients and even within multiple samples from individual patients. Histologic sections prepared from specimens analyzed for boron suggested there was a correlation between the degree of tumor cellularity and boron ~oncentration’~. This correlation was quantified in a total of 14 patients, receiving varying doses of BPA and the results suggested that the ‘08 uptake in the active part of malignant brain tumors was quite consistent from patient to patient”. From these data we calculated that following the intravenous infusion of 250 mg BPA/kg (the dose currently used to treat patients), the '9 concentration in the most cellular regions of malignant brain tumors in humans is about 50p/g, with tumor-to-blood and tumor-to- brain concentration ratios of -4 to 1. These ratios are similar to those found in rats. The first patient with glioblastoma rnultiforme was treated with BNCT in September, 1994 i.e., 33 years after the termination of the early clinical trials (Figure 2). After a four-month period of observation to veri9 the safety of the procedure, particularly with regard to the potential for early-delayed neurological problems, a multipatient protocol was initiated in February 199516. The objectives of the first protocols (a slightly modified protocol was started in 1995) were: (1) to determine ;L Figure 2. BNCT treatment room at the Brookhaven Medical Research Reactor. (A) Epithermal neutron beam port and collimator; (B) Patient gurney; (C) Laser beams for patient alignment; (D) Video monitoring; (E) Voice communication; (F) Observation window. safe starting dose for BNCT; (2) to evaluate any adverse effects of BNCT and; (3) to evaluate the effectiveness of BNCT at a safe starting dose in patients with glioblastoma multiforme. These protocols were terminated in February, 1995, after 15 patients had been treated with BPA-based BNCT at the BMRR. The major conclusions drawn from these 15 patients were: (1) BNCT, as administered to these patients, was safe. There were no adverse effects associated with the infusion of BPA-fructose at a dose of 250 mg BPA/kg body weight. There was no damage to the scalp other than focal alopecia and no damage to normal brain or other critical organs was observed; (2) tumor palliation was achieved with a median life span at least equaI to that observed with conventional therapies; (3) almost all patients had local progresion of the disease. Based on this experience a follow-up protocol was activated in June, 1996. Under the new protocol, radiation doses to tumor and the surrounding target volume (2 cm envelop around the tumor) have been increased. To date, January 14, 1997, thirteen patients have been treated, however, it is too early to determine whether or not the increased radiation doses will result in increased life span. This study remains in progress. Acknowledgments This research was supported in part by the U.S. Department of Energy under Contract DE-AC02-76CH00016. REFERENCES 1. 2 D.N. Slatkin, A history of boron neutron capture therapy of brain tumors: postulation of a brain radiation dose tolerance limit, Brain. 114:1609 (1991). R.G. Fairchild, Development and dosimetry of an "epithermal" neutron beam for possible use in neutron capture therapy. I. 'Epithermal" neutron beam development, Phys. Md. BioZ. 10~491 (1965). H.B. Liu, R.M. Brugger, and D.C. Rorer, Enhancement of the epithermal neutron beam at the Brookhaven Medical Research Reactor, b: Advances in Neuron Capture nerapy, A.H. Soloway, et al., e&, Plenum Press, N.Y. (1993). R.F. Bartb, A.H. Soloway, and R.M. Brugger, Boron neutron capture therapy of brain tumors; past 3. 4. history, current status, and future potential, C h  Sci. Rev. 14534 (1996). H.R. Snyder, AJ. Rcedy, and WJ. Lennary, Synthesis of aromatic boronic acids. Oldehydo boronic acids and a boronic acid analog of tyrosine, J. Am. Chem. SOC. 80:835 (1958). Y. Mishima, C. Honda, M. Ichihashi, H. Obara, J. Hiratsuka, H. Fukuda, H. Karashima, T. Kobayasbi, K. Kanda, and K. Yoshino, Treatment of malignant melanoma by single thermal neutron capture therapy with melanoma-seeking ‘OB compound, Lancet 2388-389 (1989). JA. Coderre, J. Glass, R.G. Fairchild, P.L. Mica, I. Fand, and D.D. Joel, Selective delivery of boron by the melanin prccursor analogp-boronophenyldanine to tumors other than melanoma, Cancer Res. 50938 (1990). JA. Coderre, D.D, Joel, P.L. Micca, M.M. Nawrocky, and D.N. Slatkin, Control of intracerebral gliosarcomas in rats by boron neutron capture therapy with p-boronophenylalanine, Rdiat .  Res. 129:290 (1992). JA. Coderre, T.M. Button, P.L. Mica, C.D. Fisher, M.M. Nawrocky, and H.B. Liu, Neutron capture therapy of the 9L rat gliosarcoma using thep-boronophenylalanine-fructose complex, Int. J .  Rad. Oncol. Biol. Phys. 30:643 (1994). 10. K. Yoshino, A. Suzuki, Y. Mori, H. Kanihana, C. Honda, Y. Mishima, T. Kobayashi, and K. Kanda, Improvement of solubility ofp-boronophenylalanine by complex formation with monosaccharides, Strahletatheropie 165127 (1989). 11. T.R. Lahann, C. Sills, G. Hematillake, T. Dymock, and G. Daniell, Cardiovascular toxicities associated with intravenous administration of p-boronophenylalanine formulations, in: Advances in Neutron Capture Iherupy, A. Soloway, R. Barth, D. Carpenter eds, Plenum Press, New York (1993). 12. JA. Coderre, P. Rubin, A. Freedman, J. Hansen, T. Wooding, D. Joel, and D. Gash, Selective ablation of rat brain tumors by boron neutron-capture therapy, Int. J. Radiar. Oncol. Bid.  Phys. 289067 (1994). 13. JA. Coderre, M. Makar, P.L. Micca, M.M. Nawrocky, H.B. Liu, D.D. Joel, DN. Slatkin, and H.I. Amok, Derivations of relative biological effectiveness for the high-LET radiations produced during boron neutron capture irradiations of the 9L rat gliosarcoma in vitro and in viw, Inr. J.  Radiar. Oncol. Bid. Phys. 271121 (1993). 14. R.Bergland, E. Elowitz, J. Coderre, D. Joel, and M. Chadha, A phase 1 trial of intravenous boronophenylalanine-fructose complex in patients with glioblastoma multiforme, in: Proceeding of the Sixth International Symposium on Neutron Capture l7terapy pp. 739-745, New York Plenum Press, 1996. 15. D.D. Joel, M. Chadha, A.D. Chanana, JA. Coderre, E.H. ElOwi4 J-0. Gebbers, H.B. Liu, PL. Micca, MM. Nawrocky, and DN. Slatkin, Uptake of BPA into gliobIastoma multiforme correlates with tumor cellularity, in: Sevenrh Intentational Symposium on Neutron Capture llerapy, Elsevier Science (ii press). 16. A.D. Chanana, JA. Coderre, D.D. Joel, and D.N. Slatkin, Protocols for BNCT of glioblastoma multifonne at Brookhaven: Practical considerations, in: Proceedings of the Seventh International Symposium on Neutron Capture Ihmapy, Elsevier Sdence (m press). 5. 6. 7. 8. 9. 

Boron neutron capture therapy of malignant brain tumors at the Brookhaven Medical Research Reactor

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Boron neutron capture therapy of malignant brain tumors at the Brookhaven Medical Research Reactor

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