William Cavanagh

10-year biochemical (prostate-specific antigen) control of prostate cancer with 125I brachytherapy

PURPOSE To report 10-year biochemical (prostate-specific antigen [PSA]) outcomes for patients treated with 125I brachytherapy as monotherapy for early-stage prostate cancer. METHODS AND MATERIALS One hundred and twenty-five consecutively treated patients, with clinical Stage T1-T2b prostate cancer were treated with 125I brachytherapy as monotherapy, and followed with PSA determinations. Kaplan-Meier estimates of PSA progression-free survival (PFS), on the basis of a two consecutive elevations of PSA, were calculated. Aggregate PSA response by time interval was assessed. Comparisons were made to an earlier-treated cohort. RESULTS The overall PSA PFS rate achieved at 10 years was 87% for low-risk patients (PSA < 10, Gleason Sum 2-6, T1-T2b). Of 59 patients (47%) followed beyond 7 years, 51 (86%) had serum PSAs less than 0.5 ng/mL; 48 (81%) had serum PSAs less than 0.2 ng/mL. Failures were local, 3.0%; distant, 3.0%. No patients have died of prostate carcinoma. The proportion of patients with a PSA < or =0.2 ng/mL continued to increase until at least 7-8 years posttherapy. A plot of PSA PFS against the proportion of patients achieving serum PSA of less than 0.2 ng/mL suggests a convergence of these two endpoints at 10 years. Patients treated in the era of this study (1988-1990) experienced a statistically improved PFS compared with an earlier era (1986-1987). This difference appears independent of patient selection, suggesting that the maturation of the technique resulted in improved biochemical control. CONCLUSION With modern technique, monotherapy with 125I achieves a high rate (87%) of biochemical and clinical control in patients with low-risk disease at 10 years. The decline of PSA following brachytherapy with low-dose-rate isotopes can be protracted. Absolute PSA and PFS curves merge, and are comparable at 10 years.

PALLADIUM-103 BRACHYTHERAPY FOR PROSTATE CARCINOMA

PURPOSE A report of biochemical outcomes for patients treated with palladium-103 (Pd-103) brachytherapy over a fixed time interval. METHODS AND MATERIALS Two hundred thirty patients with clinical stage T1-T2 prostate cancer were treated with Pd-103 brachytherapy and followed with prostate-specific antigen (PSA) determinations. Kaplan-Meier estimates of biochemical failure on the basis of two consecutive elevations of PSA were utilized. Multivariate risk groups were constructed. Aggregate PSA response by time interval was assessed. RESULTS The overall biochemical control rate achieved at 9 years was 83.5%. Failures were local 3.0%; distant 6.1%; PSA progression only 4.3%. Significant risk factors contributing to failure were serum PSA greater than 10 ng/ml and Gleason sum of 7 or greater. Five-year biochemical control for those exhibiting neither risk factor was 94%; one risk factor, 82%; both risk factors, 65%. When all 1354 PSA determinations obtained for this cohort were considered, the patients with a proportion of PSAs < or = 0.5 ng/ml continued to increase until at least 48 months post-therapy. These data conformed to a median PSA half-life of 96.2 days. CONCLUSIONS Prostate brachytherapy with Pd-103 achieves a high rate of biochemical and clinical control in patients with clinically organ-confined disease. PSA response following brachytherapy with low-dose-rate isotopes is protracted.

Pretreatment nomogram for predicting freedom from recurrence after permanent prostate brachytherapy in prostate cancer

OBJECTIVES To develop a prognostic nomogram to predict the freedom from recurrence for patients treated with permanent prostate brachytherapy for localized prostate cancer. METHODS We performed a retrospective analysis of 920 patients treated with permanent prostate brachytherapy between 1992 and 2000. The clinical parameters included clinical stage, biopsy Gleason sum, pretreatment prostate-specific antigen (PSA) value, and administration of external beam radiation. Patients who received neoadjuvant androgen deprivation therapy were excluded. Failure was defined as any post-treatment administration of androgen deprivation, clinical relapse, or biochemical failure, defined as three PSA rises. Patients with fewer than three PSA rises were censored at the time of the first PSA rise. Data from two outside institutions served as validation. RESULTS A nomogram that predicts the probability of remaining free from biochemical recurrence for 5 years after brachytherapy without adjuvant hormonal therapy was developed using Cox proportional hazards regression analysis. External validation revealed a concordance index of 0.61 to 0.64, and calibration of the nomogram suggested confidence limits of +5% to -30%. CONCLUSIONS The pretreatment nomogram we developed may be useful to physicians and patients in estimating the probability of successful treatment 5 years after brachytherapy for clinically localized prostate cancer.

The role of external beam radiotherapy with I-125/Pd-103 brachytherapy for prostate carcinoma

BACKGROUND AND PURPOSE To compare the biochemical outcomes of patients treated with Pd-103/I-125 brachytherapy alone vs. brachytherapy combined with external beam radiotherapy for early stage prostate carcinoma. METHODS Brachytherapy monotherapy was used in 403 patients. Brachytherapy was combined with 45 Gy of external beam radiotherapy in 231 patients. Median follow-up was 58 months. To compare the biochemical outcomes of these two treatment approaches, patients were stratified into three relative risk groups: low risk, T(1)-T(2), Gleason 2-6/10, PSA< or =10.0; intermediate risk, T(3), Gleason 7-10/10, PSA>10.0 (one factor); high risk, T(3), Gleason 7-10/10, PSA>10.0 (two factors). RESULTS The actuarial biochemical progression-free rate (bNED) for the entire 634 patients was 85% at 10 years. The bNED outcomes by risk group for monotherapy vs. combined therapy respectively were: low risk, 94 vs. 87%; intermediate risk, 84 vs. 85%; high risk, 54 vs. 62%. These differences did not reach statistical significance for any risk group. Rectal morbidity was slightly greater in the combined treatment patients. CONCLUSION Although the addition of external beam irradiation to brachytherapy is conceptually appealing for patients with higher risk prostate carcinoma, we were unable to demonstrate a benefit. Whether this is because of patient selection biases within the risk groupings, an artefact of retrospective review, or because external radiotherapy does not offer additional benefit is uncertain.

RISK FACTORS FOR ACUTE URINARY RETENTION REQUIRING TEMPORARY INTERMITTENT CATHETERIZATION AFTER PROSTATE BRACHYTHERAPY: A PROSPECTIVE STUDY

PURPOSE We prospectively investigated prognostic factors for men undergoing transperineal radioactive seed implantation for prostate cancer at the University of Washington. METHODS AND MATERIALS Between February and April, 1998, 62 consecutive unselected patients were prospectively followed after brachytherapy for early-stage prostate adenocarcinoma. Pretreatment variables included age, American Urological Association (AUA) score, uroflowimetry, and prostate volume by ultrasound. Nonrandomized variables included hormonal therapy, seed type, and use of pelvic radiotherapy. Patients were contacted by phone at one week postoperatively and at one-month intervals thereafter. Follow-up continued until all patients provided the date of last catheterization. RESULTS Urinary retention rate at one week was 34% (21 of 63 patients). At one month, 29%; at three months, 18%; and at six months, 10%. Preoperative flow rate and post-void residual did not predict for retention (p =.48 and p =.58). Use of alpha blockers, hormonal therapy, type of seed (103Pd or 1251), or external beam radiotherapy had no impact on risk of retention at any followup point. Preimplant volume and AUA score predicted for retention on univariate analysis, but on multivariate analysis only postimplant volume remained significant (p =.02) for predicting retention risk and duration. CONCLUSION Patients with large prostate size (>36 g) and higher AUA score (>10) appear to be at greater risk of risk of retention as well as duration of retention as defined in our study. Further investigation will be needed to clarify the risk of urinary retention for men undergoing brachytherapy.

SHOULD BRACHYTHERAPY BE CONSIDERED A THERAPEUTIC OPTION IN LOCALIZED PROSTATE CANCER

Contemporary prostate brachytherapy incorporates advances in computer analysis, imaging technology, and delivery apparatus, allowing exacting and reproducible results compared with historical approaches. The advances permit brachytherapy to be performed on a cost-effective, outpatient basis with low morbidity in the appropriately selected patient. Although unsettled questions remain regarding dosimetric issues, long-term outcomes, and morbidity, the weight of evidence to date appears to support the use of brachytherapy in selected patients. Brachytherapy may be considered a therapeutic option: as monotherapy for early-stage disease and also a boost following moderate doses of external beam irradiation for locally advanced disease.

125I versus 103Pd for low-risk prostate cancer: preliminary PSA outcomes from a prospective randomized multicenter trial ☆

PURPOSE To compare prostate cancer control rates in patients who received (125)I vs. (103)Pd. MATERIALS AND METHODS Of a planned total of 600 patients with 1997 American Joint Committee on Cancer clinical Stage T1c-T2a prostate carcinoma (Gleason score 5-6, prostate-specific antigen [PSA] 4-10 ng/mL), 126 were randomized to implantation with (125)I (144 Gy) vs. (103)Pd (125 Gy). The prostate biopsies were reviewed for Gleason score by one of us (L.T.). A single manufacturer of (125)I sources (Model 6711, Amersham, Chicago, IL) and (103)Pd sources (Theraseed, Theragenics, Buford, Georgia) was used. Isotope implantation was performed with standard techniques, using a modified peripheral loading pattern. Of a total of 126 patients randomized, 11 were excluded, leaving 115 randomized patients for this analysis. Twenty patients received a short course of preimplant hormonal therapy, none of whom continued hormonal therapy after their implant procedure. Postimplant CT was obtained 2-4 hours after implantation. The dosimetric parameters analyzed included the percentage of the postimplant prostate or rectal volume covered by the prescription dose (V(100)) and the dose that covered 90% of the postimplant prostate volume (D(90)). Freedom from biochemical failure was defined as a serum PSA level < or =0.5 ng/mL at last follow-up. Patients were censored at last follow-up if their serum PSA level was still decreasing. Patients whose serum PSA had reached a nadir at a value >0.5 ng/mL were scored as having failure at the time at which their PSA had reached a nadir. The follow-up period for patients without failure ranged from 2.0 to 4.9 years (median 2.9). Freedom-from-failure curves were calculated by the Kaplan-Meier method. Differences between groups were determined by the log-rank method. RESULTS The actuarial biochemical freedom-from-failure rate at 3 years was 89% for (125)I patients vs. 91% for (103)Pd patients (p = 0.76). The 3-year biochemical freedom-from-failure rate for patients with a D(90) <100% of the prescription dose was 82% vs. 97% for patients with a D(90) > or =100% of the prescription dose (p = 0.01). Similarly, the 3-year biochemical freedom-from-failure rate for patients with a V(100) <90% of the prescription dose was 87% vs. 97% for patients with a V(100) > or =90% of the prescription dose (p = 0.01). The effect of the dosimetric parameters on biochemical control was most pronounced for (125)I, but also apparent for (103)Pd. CONCLUSIONS The 3-year actuarial biochemical control rates for low early-stage prostate cancer are similar after (125)I and (103)Pd.

Brachytherapy for clinically localized prostate cancer: results at 7- and 8-year follow-up.

In recent years, there has been a resurgence of interest in interstitial radiation as a cost-effective and efficient method of treating organ-confined prostate cancer. We describe our 7- and 8-year results with transperineal Iodine-125 and Palladium-103 implantation. A total of 551 consecutive patients were treated. Of these, 320/551 (58%) received implant alone (Group I), and 231/551 (42%)--considered higher risk patients--were also treated with a modest dose (45 Gy) of external beam irradiation (Group II). The median follow-up for Group I was 55 months, and for Group II, 60 months. At 7 years, the actuarial freedom from biochemical failure (prostate-specific antigen (PSA) < or = 1.0 ng/mL) was 80% in Group I patients, and, at 8 years, 65% in Group II patients. Morbidity was minimal if patients had not undergone prior transurethral prostate resections. The results indicate that interstitial radiation is a valid treatment for clinically localized prostate cancer.

Posttreatment biopsy results following interstitial brachytherapy in early-stage prostate cancer☆

PURPOSE To assess pathologic control rates for prostatic carcinoma as determined by postimplant prostate biopsy in a large series of consecutive patients who have received permanent interstitial brachytherapy using a contemporary transrectal ultrasound-directed, transperineal, computer generated, volume technique. METHODS AND MATERIALS Four hundred and two patients received permanent 125I or 103Pd interstitial brachytherapy as primary treatment for early stage prostatic carcinoma at the Northwest Tumor Institute between January 1988 and January 1994. Of these, 201 have consented to biopsy 12 or more months postimplant with a median follow-up of 40 months (range: 12-83 months). None had received hormonal manipulation. A total of 361 biopsies was performed on 201 patients with a range of one to six annual biopsies per patient (91 received multiple, serial biopsies). Of the 161 patients more than 12 months postimplant who have not been biopsied, most have been unwilling or unable to submit to biopsy. Only six patients with biochemical progression have not been biopsied. There was no difference in the presenting characteristics or implant parameters between those patients biopsied and those that were not. One hundred and forty-three received 125I (71%) prescribed to a MPD of 160 Gy with a median activity of 35.5 mCi, and 58 (29%) received 103Pd prescribed to a MPD of 115 Gy with a median activity of 123 mCi. Multiple biopsies were performed under transrectal ultrasound guidance, and all specimens were classified as either negative, indeterminate, or positive. RESULTS At the time of last biopsy, 161 (80%) have achieved negative pathology, 34 (17%) remain indeterminate, and 6 (3%) have been positive. Only 2 of the 186 patients with a PSA < 4.0 ng/ml at the time of biopsy were positive. Among those 33 indeterminate patients with a subsequent biopsy, 28 have converted to negative, 2 to positive, and 3 remain unchanged to date. CONCLUSIONS These data demonstrate at least an 80% pathologically confirmed local control rate following permanent interstitial brachytherapy for early stage prostate cancer. A higher local control rate is expected with further follow-up as the majority of indeterminate biopsies convert to negative over time. The indeterminate category of postirradiation biopsy described here includes specimens that have probably been interpreted as positive in other series, but correlate clinically and biochemically with negative biopsies. These results support the use of modern interstitial brachytherapy techniques for selected patients with early stage adenocarcinoma of the prostate.

Comparability of CT-based and trus-based prostate volumes

PURPOSE To compare the prostate volumes defined by transrectal ultrasound (TRUS) versus computed tomographic (CT) scans used for brachytherapy planning. METHODS AND MATERIALS Ten unselected patients underwent evaluation for prostate brachytherapy with TRUS and CT imaging. Axial prostate contours were obtained at 5-mm intervals in both studies. The CT images were photographed, scanned into a commercial software program, and reprinted from a laser printer at 600 dots per inch to provide individual images that were interpreted independently by the three physician authors (BK, KW, and JB). An effort was made to exclude pelvic floor muscles from the defined prostate contour. Volumes were calculated in cubic centimeters. The prostate volume and maximum dimension in each plane were compared for each imaging modality. RESULTS The CT-based prostate volumes ranged from 31.1 cc to 48.1 cc. The TRUS-based volumes ranged from 26.6 cc to 46.4 cc. There was close agreement between imaging modalities (r = 0.9). The anterior-posterior, lateral, and craniocaudal prostatic dimensions were similar between modalities. To test for consistency between observers, the CT volumes were drawn independently by KB, KW, and JB. The prostatic measurements were consistent in all dimensions between observers. CONCLUSION CT scan volumes and measurements correlate well with those obtained by TRUS, and are appropriate for pre- or postimplant dosimetry.