A real-time image-guided intraoperative high-dose-rate brachytherapy system

The optimization of dose delivery for intraoperative high-dose-rate radiation therapy using curved HAM applicators

BACKGROUND AND PURPOSE

To determine the effect of the curvature of Harrison-Anderson-Mick applicators on the dose distribution in high-dose-rate intraoperative radiation therapy (HDR-IORT).

MATERIAL AND METHODS

Treatment planning was performed with flat applicators using (192)Ir as the radioactive source, and dwell times were optimized using dose-point optimization techniques. These optimized dwell times were then used for the curved applicators, and the dose distributions that would actually be delivered to patients were determined.

RESULTS

The dose directly below the central catheter was strongly dependent on the curvature of the applicator. Steep parabolic curves caused underdoses of as much as 19% at a point 1cm from the convex side of the applicator. The rate of dose reduction with increasing distance from the applicator surface was also a function of the curvature of the applicator.

CONCLUSIONS

The curvature of the applicator profoundly affects dosimetry and can be exploited to optimize coverage of the target during HDR-IORT procedures. To ensure accurate dose delivery, these dose perturbations must be accounted for in the planning process. We recommend maintaining a dosimetry atlas of various applicator sizes and curvatures in addition to one for flat applicators.

High dose rate brachytherapy: its clinical applications and treatment guidelines

Brachytherapy has the advantage of delivering a high dose to the tumor while sparing the surrounding normal tissues. With proper case selection and delivery technique, high-dose-rate (HDR) brachytherapy has great promise, because it eliminates radiation exposure, allows short treatment times, and can be performed on an outpatient basis. Additionally, use of a single-stepping source, allows optimization of dose distribution by varying the dwell time at each dwell position. However, when HDR brachytherapy is used, the treatments must be executed carefully, because the short treatment times do not allow any time for correction of errors, and mistakes can result in harm to patients. Hence, it is very important that all personnel involved in HDR brachytherapy be well trained and be constantly alert. It is expected that the use of HDR brachytherapy will greatly expand over the next decade and that refinements will occur primarily in the integration of imaging (computed tomography, magnetic resonance imaging, intraoperative ultrasonography) and optimization of dose distribution. It is anticipated that better tumor localization and normal tissue definition will help to optimize dose distribution to the tumor and reduce normal tissue exposure. The development of well-controlled randomized trials addressing issues of efficacy, toxicity, quality of life, and costs-versus-benefits will ultimately define the role of HDR brachytherapy in the therapeutic armamentarium.

Intraoperative high-dose-rate brachytherapy

Although several modalities have been discussed, a comprehensive intraoperative program should have IOERT, IOHDR, and perioperative brachytherapy facilities available to treat all sites. Interstitial brachytherapy is preferable for the treatment of gross residual tumor; IORT (IOERT for accessible sites and IOHDR for poorly accessible sites) is added to irradiate intraoperatively the surrounding margins after gross resection; and fractionated EBRT could be used in moderate doses post-operatively to irradiate the entire area of potential microscopic disease. Depending on the volume and location of the tumor, and the available expertise and equipment, IOERT, IOHDR, or perioperative brachytherapy could be used along with EBRT and surgery for the optimal management of malignancies. Finally, the best results of IOHDR are obtained when used as a conformal boost to the tumor bed after resection in conjunction with supplementary EBRT.