David E. Linstadt

Radiotherapy of primary intracranial germinomas: The case against routine craniospinal irradiation

A retrospective study was performed on all patients with biopsy-proven intracranial germinomas and unbiopsied suprasellar or pineal region tumors treated during the past 30 years in the Department of Radiation Oncology, University of California, San Francisco. A total of 33 patients were treated: 13 with biopsy-proven germinomas, and 20 others who were unbiopsied. All patients were treated with megavoltage equipment; total dose varied between 40-55 Gy. Only two patients were treated with prophylactic spinal irradiation. No patient received initial or adjuvant chemotherapy. Follow-up times for biopsy-proven patients ranged from 0.5 to 16.7 years with a median 5.3 years. No biopsy-proven patient had a recurrence of the tumor or died; thus, actuarial relapse-free and determinate survivals at 5 years were 100%. Although only one patient in this group received prophylactic spinal irradiation, no patient failed in the spinal axis. The 20 unbiopsied patients had follow-up times ranging from 0.1 to 27.5 years with a median of 5.5 years. Six unbiopsied patients died: two from recurrent disease at the primary site, one from distant peritoneal metastases, two from complications of treatment, and one from intercurrent disease. For this group, actuarial relapse-free survival at 5 years was 72%; the corresponding determinate survival was 73%. Nineteen unbiopsied patients were treated without craniospinal irradiation. Only one developed spinal metastases. The results from this and other series indicate that the risk of spinal metastases from intracranial germinoma is too low to warrant routine prophylactic spinal irradiation. However, patients with gross tumor spill causing contamination of the CSF, malignant CSF cytology, or documented subependymal or subarachnoid metastases presumably are at higher risk for leptomeningeal failure. Craniospinal irradiation is recommended for these patients.

Postoperative radiotherapy of primary spinal cord tumors

During the 30 year period from 1957 to 1986, 42 patients with primary tumors arising from the spinal cord or cauda equina received postoperative irradiation at the University of California, San Francisco. Twenty-one patients had ependymomas: 18 were localized to one site, and 3 diffusely involved the cord. There were 12 patients with low grade astrocytomas and 3 with highly anaplastic astrocytoma or glioblastoma multiforme. All astrocytomas were localized at presentation. In 6 cases tissue was insufficient to permit a histologic diagnosis. Thirty-nine patients (93%) received total radiation doses ranging between 45.0-54.7 Gy using standard fractionation. The 10-year actuarial disease-specific survival rate for patients with localized ependymoma was 93%; 33% of these tumors recurred locally. The corresponding rate for diffuse ependymomas was 50%; the spinal disease was controlled in all 3 patients, but one developed a cerebral metastasis despite prophylactic cranial irradiation. Low-grade astrocytoma patients had a 10-year actuarial disease-specific survival rate of 91%, with 33% of these tumors recurring locally. No patient with highly anaplastic astrocytoma or glioblastoma multiforme survived longer than 8 months; all of these tumors recurred locally, and two of the three also developed diffuse craniospinal axis metastases. Local recurrence for ependymoma was delayed as long as 12 years following treatment, while all but one astrocytoma failure occurred within 3 years of treatment. No significant dose-response relationship with respect to local control was noted for either localized ependymomas or low grade astrocytomas. One patient developed radiation myelitis after receiving 50.4 Gy with standard fractionation. These results indicate that patients who undergo postoperative irradiation for low grade spinal astrocytomas and localized spinal ependymomas achieve excellent survival. However, despite treatment with total radiation doses taken to the practical limit of spinal cord tolerance, local failure remains common.

Neon ion radiotherapy: Results of the phase I/II clinical trial

Neon ion radiotherapy possesses biologic and physical advantages over megavoltage X rays. Biologically, the neon beam reduces the oxygen enhancement ratio and increases relative biological effectiveness. Cells irradiated by neon ions show less variation in cell-cycle related radiosensitivity and decreased repair of radiation injury. The physical behavior of heavy charged particles allows precise delivery of high radiation doses to tumors while minimizing irradiation of normal tissues. In 1979 a Phase I-II clinical trial was started at Lawrence Berkeley Laboratory using neon ions to irradiate patients for whom conventional treatment modalities were ineffective. By the end of 1988 a total of 239 patients had received a minimum neon physical dose of 1000 cGy (median follow-up for survivors 32 months). Compared with historical results, the 5-year actuarial disease-specific survival (DSS5) and local control (LC5) rates suggest that neon treatment improves outcome for several types of tumors: a) advanced or recurrent macroscopic salivary gland carcinomas (DSS5 59%; LC5 61%); b) paranasal sinus tumors (DSS5 69%; LC5 69% for macroscopic disease); c) advanced soft tissue sarcomas (DSS5 56%, LC5 56% for macroscopic disease); d) macroscopic sarcomas of bone (DSS5 45%; LC5 59%); e) locally advanced prostate carcinomas (DSS5 90%; LC5 75%); and f) biliary tract carcinomas (DSS5 28%; LC5 44%). Treatment of malignant gliomas, pancreatic, gastric, esophageal, lung, and advanced or recurrent head and neck cancer has been less successful; results for these tumors appear no better than those achieved with conventional x-ray therapy. These findings suggest that Phase III trials using the neon beam should be implemented for selected malignancies.

Long-term results of helium ion irradiation of uveal melanoma

Between 1978 and 1988, 307 patients with uveal melanoma were irradiated using helium ions at Lawrence Berkeley Laboratory. The length of follow-up ranged from 1-115 months (median 42 months). The 5-year actuarial treatment results were: local control rate, 96.8%, determinate survival rate, 81%, freedom from distant metastases, 76%, eye retention rate, 83%, and risk of developing neovascular glaucoma, 36%. Long-term vision outcome was analyzed in 81 patients with a minimum follow-up of 5 years. Forty-seven percent of patients retained vision of 20/200 or better. The median change in vision was a loss of four lines on the standard eye chart. Thirty-eight percent of patients had visual acuity either improve or remain within two lines of their pretreatment vision. A multivariate analysis identified tumor size as the only independently significant risk factor affecting survival, development of neovascular glaucoma, or the risk of enucleation; no risk factor correlated with local recurrence. Tumor size, tumor-fovea distance, and pretreatment visual acuity were independently significant risk factors influencing vision outcome. These results confirm that helium ion irradiation is an effective treatment for uveal melanoma which combines high rates of local control, survival, and eye retention with a substantial likelihood of long-term vision preservation.

Charged particle radiotherapy of paraspinal tumors.

Between 1976 and 1987, 52 patients with tumors adjacent to and/or involving the cervical, thoracic, or lumbar spinal cord were treated with charged particles at the University of California Lawrence Berkeley Laboratory. The histologies included chordoma and chondrosarcoma (24 pts), other bone and soft tissue sarcoma (14 pts), and metastatic or unusual histology tumors (14 pts). Radiation doses ranged from 29 to 80 Gray-equivalent (GyE), with a median dose of 70 GyE. Twenty-one patients received a portion of their treatment with photons. Median followup was 28 months. For 36 previously untreated patients, local control was achieved in 21/36 patients and the 3-year actuarial survival was 61%. Of 16 patients treated for recurrent disease, 7/16 were locally controlled and the 3-year actuarial survival was 51%. For patients treated for chordoma and chondrosarcoma, probability of local control was influenced by tumor volume (less than 100 cc or greater than 150 cc) and whether disease was recurrent or previously untreated. Complications occurred in 6/52 patients, including one spinal cord injury, one cauda equina and one brachial plexus injury, and three instances of skin or subcutaneous fibrosis. Charged particle radiotherapy can safely deliver high tumor doses to paraspinal tumors with good local control.

Hyperfractionated irradiation for adults with brainstem gliomas

Hyperfractionated irradiation appears to have improved survival for pediatric patients with brainstem gliomas. However, the efficacy and safety of this technique are less well established for adults with brainstem tumors. In 1984 the UCSF Department of Radiation Oncology began treating adults with brainstem gliomas using 100 cGy fractions given twice daily to total doses ranging between 6600-7800 cGy (median dose 7200 cGy). By the end of 1989, a total of 14 patients had been irradiated with follow-up times for surviving patients ranging between 4-69 months (median follow-up 33 months). Tumor histologies included five moderately anaplastic astrocytomas, one highly anaplastic astrocytoma, and eight which were unbiopsied. At the time of this analysis, six patients had failed locally, with five dying as a result of recurrent tumor. There were no deaths caused by complications or intercurrent illness. The 3-year actuarial survival rate was 59%, with a corresponding 3-year actuarial local control rate of 48%. The projected median survival was in excess of 5 years, whereas the actuarial median time to progression was 31 months (134 weeks). The treatments were well tolerated: the mean pretreatment Karnofsky Performance Status was 74% (range 60-90%); at the end of treatment the mean KPS was 78% (range 60-100%). In terms of neurologic status, six patients improved by the end of treatment, seven were stable, and one experienced only minor deterioration without change in KPS. There were no significant long-term complications (specifically, no instances of either radiation brain necrosis or myelitis). Seven patients required prolonged steroid administration after completing radiotherapy; six of these eventually recurred locally. These results appear to be substantially better than those achieved using conventional radiotherapy regimens, and suggest that this technique merits further investigation.

Charged particle radiotherapy for lesions encircling the brain stem or spinal cord

Since 1981, a specialized technique has been under development at the University of California Lawrence Berkeley Laboratory for charged particle irradiation of tumors partially or completely encircling the brain stem or spinal cord. By dividing the target volume into two or more portions and using a combination of beams, a reasonably homogeneous irradiation of the target volume can be obtained which protects critical CNS structures from over-irradiation. This technique requires knowledge of the physical and biological effects of charged particles, precise, reproducible patient immobilization, careful treatment planning based upon Metrizamide contrast CT and/or MRI scanning, compensation for tissue inhomogeneities, and accurate, verifiable radiation delivery. Uncertainties in the dose distribution must be taken into account when prescribing treatment. We have used this technique in 47 patients with a variety of tumors abutting the brain stem and spinal cord, including chordoma, chondrosarcoma, meningioma, osteosarcoma and metastatic tumors. The results have shown a significant local control rate (62%) and the incidence of serious complications has been acceptable (13%). The median follow-up is 20 months with a range of 6-90 months. We conclude that charged particles can be safely and effectively used to irradiate lesions encircling the brain stem or spinal cord to doses higher than can be achieved with low-LET irradiation.

CILIARY BODY MELANOMA TREATED WITH HELIUM PARTICLE IRRADIATION

Melanoma involving the ciliary body is a rare tumor which carries a poor prognosis when compared to all uveal melanoma. We have treated 54 patients with ciliary body melanoma using helium ions from 1978 to 1985. Because of the high rate of metastatic disease, the 5-year disease specific survival rate is only 59% despite a 5-year local control rate of 98%. The greatest diameter of the tumor was predictive of loss of vision and enucleation (p = .05, p = .04, respectively). Multivariate analysis showed that the greatest diameter of the tumor was the most important predictor of death from metastases. The incidence of neovascular glaucoma at 5 years is 43%. The 5-year actuarial rate of enucleation is 26%. Enucleation was done for pain and/or neovascular glaucoma. Univariate analysis showed treatment volume to be a statistically significant predictor for the development of neovascular glaucoma (p = .0017) and enucleation (p = .0078). Seventy percent of neovascular glaucoma occurred in patients with treatment volume greater than 5.5 cc. Seventy-four percent occurred in patients with an initial ultrasound height greater than 9.2 mm. Using this information, patients at high risk for neovascular glaucoma could be considered for prophylactic treatment with panretinal photocoagulation.

Radiosensitization produced by iododeoxyuridine with high linear energy transfer heavy ion beams

Little is known about radiosensitization produced by iododeoxyuridine (IUDR) with high linear energy transfer radiation. Likewise, the effect of IUDR on repair of sublethal or potentially lethal damage is unclear. A series of in vitro experiments was performed examining these aspects of IUDR radiosensitization. Human T1 cells were grown in the presence of 3.0 micromolar IUDR for 72 hours (approximately three doubling times), an exposure which resulted in minimal cytotoxicity to unirradiated cells. As the cells entered plateau phase they were exposed to X rays and a variety of heavy ion beams. Sensitization was found to decrease as linear energy transfer (LET) increased. No sensitization took place in an extremely high LET Lanthanum ion beam (1000 keV/micrometer). However, IUDR produced significant sensitization in the Neon ion beam currently used to treat cancer patients at Lawrence Berkeley Laboratory. Sensitization enhancement ratios at the 40% cell survival level were found to be 1.8 for X rays, 1.5 for the proximal Bragg peak of the clinical Neon beam, and 1.3 for the distal peak of the clinical Neon beam. Cell survival curves fitted to the linear-quadratic model showed IUDR significantly increased the value of the linear component (alpha) in beams with LETs below 40 keV/micron. The value of the quadratic component (beta) was unaffected by IUDR, regardless of LET. Split-dose experiments with both X rays and proximal peak Neon ions revealed IUDR did not affect sublethal damage repair. Similarly, delayed-plating experiments showed IUDR did not affect repair of potentially lethal damage. In contrast to cells unexposed to IUDR, IUDR-treated cells showed near-equal levels of cell killing throughout the extended Bragg peak of the clinical Neon beam. These findings suggest that the addition of IUDR to Neon ion radiotherapy could enhance the therapeutic ratio of the clinical Neon beam.

Salvage whole-abdominal irradiation following chemotherapy failure in epithelial ovarian carcinoma

During the period 1977 to 1985, 12 patients with FIGO stage II and III epithelial ovarian carcinoma failed to achieve a pathologic complete response with chemotherapy and underwent salvage whole-abdominal irradiation (WAXRT). Six of these patients had gross residual disease present at the time of irradiation, and three (50%) were unable to complete the planned radiotherapy. All eventually failed in the treatment field; their 5-year actuarial survival and local control rates were zero. The other six were irradiated without residual macroscopic disease. Five of the six (83%) were able to complete WAXRT as planned without prolonged delays. The 5-year actuarial survival and local control rates for this group were 21 and 25%, respectively. The actuarial laparotomy rate to relieve bowel obstruction following WAXRT was 40% at 2 years. The results from this and other series indicate that salvage WAXRT is not effective for patients irradiated with macroscopic tumor. However, WAXRT appears to be potentially curative for a small but significant percentage of patients irradiated without gross disease, although the risk of significant complications is high.