Darrel D. Joel

Neuropathology of ablation of rat gliosarcomas and contiguous brain tissues using a microplanar beam of synchrotron-wiggler-generated X rays

Adult‐rat‐brain tissues display an unusually high resistance to necrosis when serially irradiated with parallel, thin slices of a microplanar (i.e., microscopically thin and macroscopically broad) beam of synchrotron‐wiggler‐generated, approx. 35–120 keV (median approx. 50 keV) Gd‐filtered X rays at skin‐entrance absorbed doses of 312 to 5000 Gy per slice. Such microplanar beams were used to irradiate young adult rats bearing right frontocerebral 9L gliosarcomas (approx. 4 mm diameter), through a volume of tissue containing the tumor and contiguous brain tissue, either in a single array or in 2 orthogonally crossed arrays of tissue slices. Each array included 101 parallel microplanar slices, 100 μm center‐to‐center distance, each slice being approx. 25 μm wide and 12 mm high, with skin‐entrance absorbed doses of 312.5 Gy or 625 Gy per slice. Compared with unirradiated controls with a median survival time of 20 days after tumor initiation, the median survival time was extended in irradiated rats by 139 days (625 Gy, crossed arrays), 96 days (312.Gy, crossed arrays) or 24 days (625 Gy, single array). The tumors disappeared in 22 of the 36 irradiated rats, 4/ 11 even after unidirectional microbeam irradiation. The extent and severity of radiation damage to the normal brain in rats with or without tumor was graded histopathologically. Correlation of those grades with radiation doses shows that loss of tissue structure was confined to beam‐crossing regions and that only minor damage was done to zones of the brain irradiated unidirectionally. Int. J. Cancer 78:654–660, 1998.

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 of brain tumors: enhanced survival and cure following blood–brain barrier disruption and intracarotid injection of sodium borocaptate and boronophenylalanine

PURPOSE Boronophenylalanine (BPA) and sodium borocaptate (Na(2)B(12)H(11)SH or BSH) have been used clinically for boron neutron capture therapy (BNCT) of high-grade gliomas. These drugs appear to concentrate in tumors by different mechanisms and may target different subpopulations of glioma cells. The purpose of the present study was to determine if the efficacy of BNCT could be further improved in F98-glioma-bearing rats by administering both boron compounds together and by improving their delivery by means of intracarotid (i.c.) injection with or without blood-brain barrier disruption (BBB-D). METHODS AND MATERIALS For biodistribution studies, 10(5) F98 glioma cells were implanted stereotactically into the brains of syngeneic Fischer rats. Eleven to 13 days later animals were injected intravenously (i.v.) with BPA at doses of either 250 or 500 mg/kg body weight (b.w.) in combination with BSH at doses of either 30 or 60 mg/kg b.w. or i.c. with or without BBB-D, which was accomplished by i.c. infusion of a hyperosmotic (25%) solution of mannitol. For BNCT studies, 10(3) F98 glioma cells were implanted intracerebrally, and 14 days later animals were transported to the Brookhaven National Laboratory (BNL). They received BPA (250 mg/kg b.w.) in combination with BSH (30 mg/kg b.w. ) by i.v. or i.c. injection with or without BBB-D, and 2.5 hours later they were irradiated with a collimated beam of thermal neutrons at the BNL Medical Research Reactor. RESULTS The mean tumor boron concentration +/- standard deviation (SD) at 2.5 hours after i. c. injection of BPA (250 mg/kg b.w.) and BSH (30 mg/kg b.w.) was 56. 3 +/- 37.8 microgram/g with BBB-D compared to 20.8 +/- 3.9 microgram/g without BBB-D and 11.2 +/- 1.8 microgram/g after i.v. injection. Doubling the dose of BPA and BSH produced a twofold increase in tumor boron concentrations, but also concomitant increases in normal brain and blood levels, which could have adverse effects. For this reason, the lower boron dose was selected for BNCT studies. The median survival time was 25 days for untreated control rats, 29 days for irradiated controls, 42 days for rats that received BPA and BSH i.v., 53 days following i.c. injection, and 72 days following i.c. injection + BBB-D with subsets of long-term survivors and/or cured animals in the latter two groups. No histopathologic evidence of residual tumor was seen in the brains of cured animals. CONCLUSIONS The combination of BPA and BSH, administered i.c. with BBB-D, yielded a 25% cure rate for the heretofore incurable F98 rat glioma with minimal late radiation-induced brain damage. These results demonstrate that using a combination of boron agents and optimizing their delivery can dramatically improve the efficacy of BNCT in glioma-bearing rats.

Accumulation of latex in Peyer's patches and its subsequent appearance in villi and mesenteric lymph nodes.

Summary Latex particles (2 μm in diameter) accumulated in intestinal Peyers patches and mesenteric lymph nodes of mice given latex suspensions as drinking fluid. After a 61-day period of latex feeding, the particles were also present in villi adjacent to Peyers patches; they were not seen, however, after only 3 days of latex feeding. The amount of latex in Peyers patches 74 days after the termination of latex feeding was much less than the amount present 14 days after the termination of feeding. It is suggested that migratory macrophages take up latex particles within Peyers patches and subsequently move out of the patch to mesenteric nodes and villi. Some free particles may also be transported out of Peyers patches to mesenteric nodes and villi through open lymphatic channels. The observations support the contention that Peyers patches “sample” intestinal contents and they suggest a mechanism for the elimination of accumulated inert particulate matter from these lymphoid structures.

Control of Intracerebral Gliosarcomas in Rats by Boron Neutron Capture Therapy with p-Boronophenylalanine

Boron neutron capture therapy (BNCT) of transplanted intracerebral GS-9L rat gliosarcomas was effected by irradiation at a nuclear reactor, primarily with thermal neutrons, after two intragastric doses of p-boronophenylalanine (BPA). At the time of BNCT, tumor 10B levels were approximately 40 micrograms 10B/g with tumor:blood and tumor:brain 10B concentration ratios of about 3.3:1 and 3.9:1, respectively. This resulted in calculated doses to tumor that were approximately 2.3-fold greater than those to normal brain parenchyma and brain vascular endothelium within the treatment volume. Approximately 75% of the tumor dose resulted from the 10B(n,alpha)7Li nuclear reaction. The median survival of untreated rats (n = 20) was 20 days after initiation of tumors. Reactor irradiation only (no BPA) increased the median survival to 25 days (n = 25). None of the rats in the untreated or irradiation-only groups survived longer than 34 days after initiation of tumors. Two BNCT dose levels were used: 8.9 Gy (19.3 Gy x relative biological effectiveness, or Gy-eq) and 13.4 Gy (29.0 Gy-eq). The median post-BNCT survivals of BPA-treated rats in the 8.9-Gy (n = 16) and 13.4-Gy (n = 12) groups were 60 and 120 days, respectively, including seven long-term (greater than 12 months) survivors at 8.9 Gy and six long-term (greater than 5 months) survivors at 13.4 Gy. Survival times following BPA-based BNCT (either 8.9 or 13.4 Gy) were significantly longer than those following 250-kVp X-ray doses of 15 Gy (n = 24), 22.5 Gy (n = 32) or 30 Gy (n = 26).

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.

Accumulation of 2-μm latex particles in mouse Peyer's patches during chronic latex feeding

2-μm latex particles accumulated in macrophages in intestinal Peyers patches of mice given latex suspensions as drinking fluid for 2 months. The number of particles accumulating was a direct (but nonlinear) function of the number ingested. Some of the latex particles were still present in Peyers patches 6 weeks after the cessation of latex feeding.

Intestinal Uptake of Fluorescent Microspheres in Young and Aged Mice

Abstract Rhodamine B-labeled synthetic latex particles (microspheres), 1.8 μm in diameter, were administered by gavage 5 days per week to young (24 days) and aged (18 months) mice. After 25 days (19 gavages), the particles were assayed in solubilized tissues by depositing them on filters and counting under fluorescence microscopy. Aged mice exhibited significantly more fluorescent particle accumulation in Peyers patches but significantly less in lungs than young mice. Mesenteric lymph nodes and Peyers patch–free intestinal segments contained measurable latex, but differences between young and aged animals were not significant. Liver contained only trace amounts of latex, and spleen and kidney were latex free in both young and aged animals. Nonquantitative observations on KOH-glycerol-cleared whole Peyers patches and slices of liver, lung, and mesenteric lymph node were similar.