Dose perturbations by two carbon fiber treatment couches and the ability of a commercial treatment planning system to predict these effects.

PURPOSE: To measure the effect of the treatment couch on dose distributions and to investigate the ability of a modern planning system to accurately model these effects. METHODS: This work measured the dose perturbation at depth and in the dose buildup region when one of two treatment couches, CIVCO (formerly MED-TEC) or Medical Intelligence, was placed between a photon beam source (6, 10, and 18 MV) and the phantom. Beam attenuation was measured in the center of a cylindrical acrylic phantom with a Farmer type ion chamber at multiple gantry angles. Dose buildup was measured in Solid Water with plane parallel ion chambers (NACP-02 and PTW Markus) with the beam normal to both the phantom and couch surfaces. The effective point of measurement method as described [M. R. McEwen et al. "The effective point of measurement of ionization chambers and the build-up anomaly in MV x-ray beams," Med. Phys. 35(3), 950-958 (2008)] was employed to calculate dose in the buildup region. Both experiments were modeled in XiO. Images of the treatment couches were merged with images of the phantoms such that they were included as part of the "patient" image. Dose distributions calculated with superposition and fast superposition algorithms were compared to measurement. RESULTS: The two treatment couches have different radiological signatures and dissimilar water equivalent thicknesses (4.2 vs 6.3 mm.) Maximum attenuation was 7%. Both couches caused significant loss of skin sparing, the worst case showing an increase in surface dose from 17% (no couch) to 88% (with couch). The TPS accurately predicted the surface dose (+/-3%) and the attenuation at depth when the phantom was in contact with the couch. For the open beam the TPS was less successful in the buildup region. CONCLUSIONS: The treatment couch is not radio-transparent. Its presence between the patient and beam source significantly alters dose in the patient. For the most part, a modern treatment planning system can adequately predict the altered dose distribution.

Total scalp radiation using image-guided IMRT for progressive cutaneous T cell lymphoma.

Modern radiotherapy has advanced dramatically over the past decade and it is now possible to focus radiotherapy with extreme precision. This allows the radiation dose to be targeted to the area(s) of tumour while sparing adjacent normal tissues even in seemingly complicated and difficult parts of the body. The case report presented here will illustrate how it is possible to irradiate the entire scalp for extensive cutaneous T cell lymphoma while minimising radiotherapy to the underlying brain, orbits and other critical structures.

Changes in muscle blood flow distribution during hyperthermia.

Blood flow is a critical parameter for obtaining satisfactory temperature distributions during clinical hyperthermia. This study examines the changes in blood flow distribution in normal porcine skeletal muscle before, during and after a period of regional microwave hyperthermia. The baseline blood flow distribution during general anaesthesia and after the insertion of the thermal probes was established independently in order to isolate the changes due to hyperthermia. General anaesthesia alone and thermocouple insertion during anesthesia had no significant effect on the muscle blood flow distribution. Regional microwave heating generated a non-uniform blood flow distribution which was a function of the tissue temperature distribution. Blood flow was greater in those tissues samples in which higher temperatures were recorded and less in those sampled further from the applicators peak SAR (Specific Absorption Rate). The increase in blood flow appears to be primarily a local phenomenon. Although muscle blood flow may be considered to be uniform prior to heating, this does not hold during hyperthermia treatment. Therefore, the non-uniform nature of the blood distribution during heating should be incorporated into any practical bioheat transfer model.

Tissue preparation technique for microsphere assays of blood flow.

A simple method for preparing standardized tissue samples for microsphere assay of tissue blood flow is described. By reduction of tissue samples into a liquid state and centrifugation of the microspheres to the bottom of conical-shaped counting vials, the microspheres within all tissue and blood reference samples attain the same counting geometry. The validity and reproducibility of this technique has been established for planar-configured gamma-ray detectors in an in-situ porcine kidney model. A positive correlation coefficient of r = 0.99 was observed between the total kidney blood flow, as measured by a calibrated Transonic flow probe, and the microsphere reference sample technique.

Lateral electron equilibrium and electron contamination in measurements of head-scatter factors using miniphantoms and brass caps.

The head-scatter factor (Sh) can be measured with a narrow miniphantom or a metal cap provided it is completely covered by the photon beam and its lateral size is thick enough to prevent electron contamination contributions. The effects of lateral electron equilibrium (LEE) and electron contamination on the Sh values were studied. The EGS4 Monte Carlo technique was used to calculate the minimum beam radii (rLEE) required to achieve complete LEE for photon beams ranging from 60Co to 24 MV. The measurement shows that the error introduced to the Sh value due to lateral electron disequilibrium is negligible. The radii of the miniphantoms or the sidewall thicknesses of the caps can be reduced below rLEE provided they are thick enough to prevent the effect of electron contamination.

A translating-bed technique for total-body irradiation.

Total-body irradiation (TBI) is a therapy modality that is being used with increasing frequency, in conjunction with chemotherapy, for patients undergoing bone-marrow transplantation. At the Ottawa Regional Cancer Centre a technique has been developed for the delivery of TBI to patients prior to bone-marrow transplantation. In this technique patients are treated on a mobile couch at approximately 195 cm SSD with a field size of 66.5 cm wide by 57 cm long. A computer-controlled stepping motor drives the patient couch at a user-selectable speed. The total dose delivered to the patient is a function of couch velocity, field size and patient separation. Treatment times are of the order of 10 min for each of the anterior and posterior fields for a 400 cGy fraction. It has been found that the conventional central axis tissue maximum ratio (TMR) and percentage depth dose (PDD) functions are not appropriate for describing dose delivered during dynamic treatment. To this end we have developed dynamic TMR and PDD functions. Extensive measurements have been performed in an anthropomorphic water phantom to determine the dose distributions in three dimensions and the efficacy of polymethyl methacrylate (PMMA) beam spoilers as a replacement for anterior and lateral bolus. It has been found that 2.4 cm PMMA spoilers do provide full skin dose and negate the requirement for lateral bolus. This TBI procedure is simple, rapid and appears to be well tolerated by the patients. 55 patients have been treated since the introduction of this technique in 1991.

On the spatial resolution of clinical thermometers.

In this work the spatial resolution of type T (copper-Constantan) and type K (Chromel-Alumel) multipoint thermocouple thermometers was investigated. For clinical use, thermocouples are usually inserted within catheters to provide easy access, reproducibility, and a sterile environment. The effect of several types of catheter on the ability of these thermometers to accurately resolve thermal gradients was studied. The influence of the number of wire pairs within the multipoint thermometer was also investigated. A mathematical model has been developed to determine the spatial resolving power of these thermometers. Results indicate that type K thermocouples are generally superior to type T and the use of catheters plays a significant role in spatial resolution. Moreover, the use of mineral oil as a thermal coupling agent between the catheter and the thermometer was also found to have some effect.

The clinical use of thermocouple thermometry.

The development of a clinical thermometry system entails solving both clinical and technical problems. A thermometry system will, in general, be comprised of a temperature transducing element, a mechanism for interrogating the transducer temperature, and a means of interpreting, reporting and recording the measured temperature. Thermocouples are thermometers which report their own temperature, while the parameter of interest is the temperature of the medium. The two key questions which arise are then: (1) is the thermometer correctly reporting its own temperature, and (2) what is the relationship between the medium temperature and the thermometer temperature? In this work some of the important parameters influencing the temperature of the thermometer and the thermal relationship between the thermometer and the medium are investigated.

Hyperthermia enhancement of radiation response and inhibition of recovery from radiation damage in human glioma cells.

Three human glioma cell lines were tested for the effectiveness of hyperthermia and thermal radiosensitization. Thermal sensitization was evaluated from the perspective of increased radiosensitivity as well as inhibition of recovery from radiation damage. The three glioma cell lines tested showed large shoulders on the radiation survival curve and a large capacity for recovery of potentially lethal radiation damage. Hyperthermia caused radiosensitization in all three cell lines, which was primarily characterized by the reduction of the survival curve shoulder with moderate decreases in the survival curve slope. The radiosensitization was dependent on the time and temperature of the hyperthermia treatment. At 45 degree C for 60 min the shoulder of the radiation survival curve could be completely eliminated and the degree of enhanced cell killing at the 2 Gy level ranged from factors of 10 to 20 under the various conditions. When hyperthermia was given to cells which were irradiated and then plated immediately, or delayed for 8 h before plating to allow recovery, hyperthermia was found to cause radiosensitization under both conditions. In addition, when the hyperthermia dose was increased the difference between the immediate plating and the delayed plating survival curve decreased and for 45 degrees C for 60 min this difference was completely eliminated, concomitantly with the elimination of the survival curve shoulder. These data indicate that hyperthermia may play a role in radiosensitization for the treatment of human glioma.

A comparison of heat and radiation sensitivity of three human glioma cell lines.

Three human glioma cell lines were tested for radiation and hyperthermia sensitivity and compared to the responses of a normal human fibroblast cell line. The radiation response of the glioma cell lines exhibited a large shoulder on the radiation survival curve indicating radioresistance when compared to the more radiosensitive fibroblast cell line. The hyperthermia response for the glioma cell lines was qualitatively similar to responses reported for other cell lines. When compared to normal human fibroblasts the glioma cells were found to be more sensitive to hyperthermia than the normal fibroblasts indicating hyperthermia may be a promising method or adjunct to radiotherapy in the treatment of resistant glioma cells or tumors. The results also show that both the radiation and thermal response is influenced by cell culture conditions and growth status. Two of the cell lines grown to confluency and treated in confluency showed an increased radiation resistance at low doses and the cell lines showed decreased resistance at high doses compared to cells plated to confluency (see Methods and Materials). An increased thermal resistance, especially at the lower heating temperatures, was also observed for cells grown to confluency. Measurements of residual glucose in the culture medium at the time of irradiation was about the same for the two culture methods (55%-65%). Cell cycle analysis showed that the differences were not related to changes in cell cycle distribution.

Impact of local radiation in the management of salivary gland carcinomas.

Seventy patients with salivary gland carcinoma (63% major gland and 37% minor gland) are reviewed. Histologies included adenoid cystic (54%), mucoepidermoid (16%), and adenocarcinoma (14%). Patients were analyzed according to extent of surgery and whether or not adjuvant postoperative radiotherapy was given. There is no difference in survival in patients who had complete excision of gross tumor with or without adjuvant radiotherapy. Patients who did not undergo radiotherapy had a 62% actuarial risk of locoregional failure at 5 years, with a 20% risk in the adjuvantly irradiated group (P less than 0.001). A failure analysis demonstrates that among the 44% of patients with recurrence 71% (22/31) failed locoregionally and 69% (21/31) had distant metastases. Twenty-seven percent (19/70) died of disease, with 31% (6/19) dying of locoregional disease and 26% (5/19) of distant disease. Implications for management are discussed.

Multivolumetric analysis of CT scans on patients with glioma.

Brain tumor volumes in patients having multimodal therapy for cerebral gliomas were calculated using graphic methods and Simpsonian integration. Volume assessment calculations differed from the clinical assessment of the patient significantly in some cases. These calculations may be useful in on-going tumor therapy and should be used as a true scientific end point in brain tumor treatment protocols.