A. D. Chanana

Boron Neutron Capture Therapy for Glioblastoma Multiforme: Interim Results from the Phase I/II Dose-Escalation Studies

OBJECTIVE: The primary objective of these Phase I/II dose-escalation studies is to evaluate the safety of boronophenylalanine (BPA)-fructose-mediated boron neutron capture therapy (BNCT) for patients with glioblastoma multiforme (GBM). A secondary purpose is to assess the palliation of GBM by BNCT, if possible. METHODS: Thirty-eight patients with GBM have been treated. Subtotal or gross total resection of GBM was performed for 38 patients (median age, 56 yr) before BNCT. BPA-fructose (250 or 290 mg BPA/kg body weight) was infused intravenously, in 2 hours, approximately 3 to 5 weeks after surgery. Neutron irradiation was begun between 34 and 82 minutes after the end of the BPA infusion and lasted 38 to 65 minutes. RESULTS: Toxicity related to BPA-fructose was not observed. The maximal radiation dose to normal brain varied from 8.9 to 14.8 Gy-Eq. The volume-weighted average radiation dose to normal brain tissues ranged from 1.9 to 6.0 Gy-Eq. No BNCT-related Grade 3 or 4 toxicity was observed, although milder toxicities were seen. Twenty-five of 37 assessable patients are dead, all as a result of progressive GBM. No radiation-induced damage to normal brain tissue was observed in postmortem examinations of seven brains. The minimal tumor volume doses ranged from 18 to 55 Gy-Eq. The median time to tumor progression and the median survival time from diagnosis (from Kaplan-Meier curves) were 31.6 weeks and 13.0 months, respectively. CONCLUSION: The BNCT procedure used has been safe for all patients treated to date. Our limited clinical evaluation suggests that the palliation offered by a single session of BNCT is comparable to that provided by fractionated photon therapy. Additional studies with further escalation of radiation doses are in progress.

Biodistribution of boronophenylalanine in patients with glioblastoma multiforme: boron concentration correlates with tumor cellularity.

Boron-10 (10B) concentrations were measured in 107 surgical samples from 15 patients with glioblastoma multiforme who were infused with 95 atom% 10B-enriched p-boronophenylalanine (BPA) intravenously for 2 h just prior to surgery at doses ranging from 98 to 290 mg BPA/kg body weight. The blood 10B concentration reached a maximum at the end of the infusion (ranging from 9.3 to 26.0 microg 10B/g) and was proportional to the amount of BPA infused. The boron concentrations in excised tumor samples ranged from 2.7 to 41.3 microg 10B/g over the range of administered BPA doses and varied considerably among multiple samples from individual patients and among patients at the same BPA dose. A morphometric index of the density of viable-appearing tumor cells in histological sections obtained from samples adjacent to, and macroscopically similar to, the tumor samples used for boron analysis correlated linearly with the boron concentrations. From that correlation it is estimated that 10B concentrations in glioblastoma tumor cells were over four times greater than concurrent blood 10B concentrations. Thus, in the dose range of 98 to 290 mg BPA/kg, the accumulation of boron in tumor cells is a linear function of BPA dose and the variations observed in boron concentrations of tumor specimens obtained surgically are largely due to differences in the proportion of nontumor tissue (i.e. necrotic tissue, normal brain) present in the samples submitted for boron analysis. The tumor:blood 10B concentration ratio derived from this analysis provides a rationale for estimating the fraction of the radiation dose to viable tumor cells resulting from the boron neutron capture reaction based on measured boron concentrations in the blood at the time of BNCT without the need for analysis of tumor samples from individual patients.

Boron neutron capture therapy for glioblastoma multiforme using p-boronophenylalanine and epithermal neutrons: trial design and early clinical results.

A Phase I/II clinical trial of boron neutroncapture therapy (BNCT) for glioblastoma multiforme is underwayusing the amino acid analog p-boronophenylalanine (BPA) andthe epithermal neutron beam at the Brookhaven MedicalResearch Reactor. Biodistribution studies were carried out in18 patients at the time of craniotomy usingan i.v. infusion of BPA, solubilized as afructose complex (BPA-F). There were no toxic effectsrelated to the BPA-F administration at doses of130, 170, 210, or 250 mg BPA/kg bodyweight. The tumor/blood, brain/blood and scalp/blood boron concentrationratios were approximately 3.5:1, 1:1 and 1.5:1, respectively.Ten patients have received BNCT following 2-hr infusionsof 250 mg BPA/kg body weight. The averageboron concentration in the blood during the irradiationwas 13.0 ± 1.5 μg 10B/g. The prescribedmaximum dose to normal brain (1 cm3 volume)was 10.5 photon-equivalent Gy (Gy-Eq). Estimated maximum andminimum doses (mean ± sd, n=10)to the tumor volume were 52.6 ± 4.9Gy-Eq (range: 64.4–47.6) and 25.2 ± 4.2 Gy-Eq(range: 32.3–20.0), respectively). The estimated minimum dose tothe target volume (tumor + 2 cm margin)was 12.3 ± 2.7 Gy-Eq (range: 16.2–7.8). Therewere no adverse effects on normal brain. Thescalp showed mild erythema, followed by epilation inthe 8 cm diameter field. Four patients developedrecurrent tumor, apparently in the lower dose (deeper)regions of the target volume, at post-BNCT intervalsof 7, 5, 3.5 and 3 months, respectively.The remaining patients have had less than 4months of post-BNCT follow-up. BNCT, at this startingdose level, appears safe. Plans are underway tobegin the dose escalation phase of this protocol.

Boron Neutron-Capture Therapy (BNCT) for Glioblastoma Multiforme (GBM) Using the Epithermal Neutron Beam at the Brookhaven National Laboratory

OBJECTIVE Boron neutron-capture therapy (BNCT) is a binary form of radiation therapy based on the nuclear reactions that occur when boron (10B) is exposed to thermal neutrons. Preclinical studies have demonstrated the therapeutic efficacy of p-boronophenylalanine (BPA)-based BNCT. The objectives of the Phase I/II trial were to study the feasibility and safety of single-fraction BNCT in patients with GBM. MATERIALS AND METHODS The trial design required (a) a BPA biodistribution study performed at the time of craniotomy; and (b) BNCT within approximately 4 weeks of the biodistribution study. From September 1994 to July 1995, 10 patients were treated. For biodistribution, patients received a 2-hour intravenous (i.v.) infusion of BPA-fructose complex (BPA-F). Blood samples, taken during and after infusion, and multiple tissue samples collected during surgical debulking were analyzed for 10B concentration. For BNCT, all patients received a dose of 250 mg BPA/kg administered by a 2-hour i.v. infusion of BPA-F, followed by neutron beam irradiation at the Brookhaven Medical Research Reactor (BMRR). The average blood 10B concentrations measured before and during treatment were used to calculate the time of reactor irradiation that would deliver the prescribed dose. RESULTS 10B concentrations in specimens of scalp and tumor were higher than in blood by factors of approximately 1.5 and approximately 3.5, respectively. The 10B concentration in the normal brain was < or = that in the blood; however, for purposes of estimating radiation doses to normal brain endothelium, it was always assumed to be equal to blood. BNCT doses are expressed as gray-equivalent (Gy-Eq), which is the sum of the various physical dose components multiplied to appropriate biologic effectiveness factors. The dose to a 1-cm3 volume where the thermal flux reached a maximum was 10.6 +/- 0.3 Gy-Eq in 9 patients and 13.8 Gy-Eq in 1 patient. The minimum dose in tumor ranged from 20 to 32.3 Gy-Eq. The minimum dose in the target volume (tumor plus 2 cm margin) ranged from 7.8 to 16.2 Gy-Eq. Dose to scalp ranged from 10 to 16 Gy-Eq. All patients experienced in-field alopecia. No CNS toxicity attributed to BNCT was observed. The median time to local disease progression following BNCT was 6 months (range 2.7 to 9.0). The median time to local disease progression was longer in patients who received a higher tumor dose. The median survival time from diagnosis was 13.5 months. CONCLUSION It is feasible to safely deliver a single fraction of BPA-based BNCT. At the dose prescribed, the patients did not experience any morbidity. To further evaluate the therapeutic efficacy of BNCT, a dose-escalation study delivering a minimum target volume dose of 17 Gy-Eq is in progress.

Boron neutron capture therapy for malignant gliomas

Boron neutron capture therapy (BNCT) represents a promising modality for a relatively selective radiation dose delivery to the tumour tissue. Boron-10 nuclei capture slow ‘thermal’ neutrons preferentially and, upon capture, promptly undergo 10B(n,α)7Li reaction. The ionization tracks of energetic and heavy lithium and helium ions resulting from this reaction are only about one cell diameter in length (∼ 14 μm). Because of their high linear energy transfer (LET) these ions have a high relative biological effectiveness (RBE) for controlling tumour growth. The key to effective BNCT of tumours, such as glioblastoma multiforme (GBM), is the preferential accumulation of boron-10 in the tumour, including the infiltrating GBM cells, as compared with that in the vital structures of the normal brain. Provided that a sufficiently high tumour boron-10 concentration (∼109 boron-10 atoms/cell) and an adequate thermal neutron fluence (∼ 1012 neutrons/ cm2) are achieved, it is the ratio of the boron-10 concentration in tumour cells to that in the normal brain cells that will largely determine the therapeutic gain of BNCT.

EXTRACORPOREAL IRRADIATION OF BLOOD IN MAN: RADIATION RESISTANCE OF CIRCULATING PLATELETS.

Circulating platelets, unlike megakaryocytes, are highly radioresistant. The platelets from five leukemic patients receiving extracorporeal irradiation of the blood were labeled with51 Cr. No effec...

Studies on lymphocytes. XV. Analysis of the in vivo division cycle of large lymphoid cells in calf thoracic duct using combined microspectrophotometry and autoradiography.

Abstract From previously reported labeled mitosis curves, the majority of proliferating large lymphoid cells in the thoracic duct of the calf have a T G of about 5 h. The division cycle in vivo of these elements was further investigated by combining microspectrophotometry and autoradiography of a sample taken 20 min following i. v. injection of 3 H-thymidine. Compared with small lymphocytes, unlabeled large lymphoid cells with a DNA content near the 2 c mode showed approx. 4% higher mean, and a greater coefficient of variation of, Feulgen absorbance values per nucleus. In contrast to small lymphocytes, they exhibited a frequency distribution with regard to DNA content which diverged from normality with skewness to the right. Large lymphoid cells with a relative DNA content of 1.9–2.3 c showed a significantly smaller mean nuclear surface area in smears than elements with a relative DNA content of 3.7-3.1 c although there was a considerable overlap between the two groups of cells with regard to size. The sum of labeled and unlabeled large lymphoid cells per standard class of DNA content ( x ± 0.2 c ) was greatest in a class around the 2 c mode, and smallest in classes of from 3.0 to 3.8 c DNA content. All large blasts with a relative DNA content of between 2.5 and 3.8 c were labeled indicating that throughout the major part of S phase there was no appreciable interruption in nuclear DNA synthesis. The median grain count per labeled large lymphoid blast was lowest in cells with a DNA content near the 2 c and 4 c modes, respectively, and highest in elements with a DNA content approximating 3.6 c . The inverse relative number of large lymphoid cells per class of DNA content paralleled satisfactorily the median grain count per labeled cell in the same class. These results are interpreted as indicating that in this particular cell system in vivo (1) unlabeled blasts with a DNA content near the 2 c mode are comprised of both elements in G 1 and some in early S phase; (2) nuclear size increases as cells develop from G 1 to G 2 phase although the nuclear surface area of an individual lymphoid cell in smears does not permit classification with regard to subphases of the division cycle; (3) throughout the major part of S phase overall nuclear DNA synthesis rate is rather adequately reflected by incorporation of 3 H-thymidine suggesting that for the latter, possible changes during S phase of endogenous precursor pool sizes and/or activities of enzymes instrumental in incorporation of 3 H-thymidine into DNA are of minor importance; (4) integrated nuclear DNA synthesis rate is highest in the second half and most probably lowest at both extremes of the S period.

Boron Neutron Capture Therapy of Glioblastoma Multiforme Using the p-Boronophenylalanine-Fructose Complex and Epithermal Neutrons

The amino acid analogue p-boronophenylalanine (BPA) is under investigation as a neutron capture agent for BNCT of glioblastoma multiforme. A series of patients undergoing surgical removal of tumor received BPA orally as the free amino acid. Favorable tumor/blood boron concentration ratios were obtained but the absolute amount of boron in the tumor would have been insufficient for BNCT. BPA can be solubilized at neutral pH by complexation with fructose (BPA-F). Studies with rats suggest that intraperitoneal injection of BPA-F complex produces a much higher tumor boron concentration to rat intracerebral 9L gliosarcoma that were possible with oral BPA. Higher boron concentrations have allowed higher tumor radiation doses to be delivered while maintaining the dose to the normal brain vascular endothelium below the threshold of tolerance. The experience to date of the administration of BPA-F to one patient is provided in this report.

STUDIES ON LYMPHOCYTES

Tritiated thymidine was administered to calves continually for 2 to 8 days via the thymic artery in an attempt to label intensively thymic lymphocytes. Heavily labeled cells which had migrated from the thymus were observed in the spleen, lymph nodes and Peyers patches. Cell maps were made for the various lymphoid tissues and in all cases the majority of labeled thymic cells were found in the ‘thymus dependent areas’of the spleen and lymph nodes. The number of labeled thymic cells per thousand lymphocytes was highest in the ‘thymus dependent areas’. A few labeled thymic cells were seen in or near the post capillary venules. The labeling pattern in the Peyers patches was different from that in the spleen and lymph nodes. Labeled thymic cells were not observed in the bone marrow.

Studies on Lymphopoiesis. VII. Size Distribution of Bovine Thoracic Duct Lymphocytes.

Summary Size distribution studies based upon cell volumes of pure thoracic duct lymphocytes of normal young calves indicate the existence of two populations of cells and delineate the size and range of each.