Patient Characteristics
Of the 85 total patients, 61 received prescription doses of 40 Gy in 5 fractions,
10 received prescription doses of 37.5 Gy in 5 fractions, and 14 received combination therapy of low dose rate brachytherapy in addition to 5-fraction SBRT to prescription doses of 25 Gy. The mean age was 69.7 years old (range: 51-85 years), with tumor stages ranging from T1-3N0M0 (n=79) to T1-4N0-1M0-1 (n=6). The median follow-up was 2.85 years.
Reproducibility of Organ Delineation
Comparisons of the initial pelvic organ delineation in 10 randomly chosen CBCTs and the repeat delineations by a single reviewer showed excellent reproducibility in COM displacement as well as organ volume (ICC coefficient range: 0.93-1.00).
Bladder and Rectum Volume
The mean bladder volume at the time of the baseline Sim-CT was 291.2±157.3 mL. Bladder volumes in the subsequent CBCTs were as follows: 263.4±147.1 mL at fraction #1, 236.6±145.0 mL at #2, 234.3±128.1 mL at #3, 220.0±127.6 mL at #4, and 204.3±106.9 mL at #5 (Figure 1). The average bladder volume reduction per patient from Sim-CT to fraction #5 (V5-SimBladder) significantly decreased by 86.9 mL or 19.0% (Wilcoxon signed-rank test: P<0.01). In 10 patients, exact bladder volume could not be delineated due to limitations in field of view in CBCTs compared to full pelvic simulation CTs. After accounting for these limitations and excluding patients with sub-optimal CBCTs, V5-SimBladder significantly decreased by 90.2 mL or 20.6% (Wilcoxon signed-rank test: P<0.01). Sim-CT bladder volume was inversely correlated with V5-SimBladder (ρ=-0.69; P<0.01); thus, larger bladder volume at simulation was predictive of larger bladder volume loss toward fraction #5 (Figure 2a). However, pre-treatment IPSS score, a metric for urinary dysfunction, was not predictive of relative bladder volume reduction through treatment (ρ=-0.07; P=0.5). Sim-CT bladder volume was not a significant predictor of variance in intra-patient bladder volume change (r2) (Spearman's correlation=0.18; P=0.09) (Figure 2b).
Baseline Sim-CT rectum volume was 56.1±19.6 mL, with subsequent rectum volumes measuring 54.4±23.6 mL at fraction #1, 54.1±21.7 mL at #2, 52.7±21.5 mL at #3, 53.1±24.2 mL at #4, and 49.6±20.7 mL at #5 (Figure 3). Rectum volume significantly decreased by 6.4 mL or 8.7% from Sim-CT to fraction #5 (V5-SimRectum) (Wilcoxon signed-rank test: P<0.01). A weak but significant association between the Sim-CT rectum volume and the V5-SimRectum was observed (Spearman's correlation=-0.51; P<0.01); however, Sim-CT rectum volume was not a predictor of rectum r2 (Spearman's correlation=0.08; P=0.48 (Figures 4a, 4b).
Pelvic Organ Displacement
Patients were positioned for treatment based on intraprostatic fiducial marker matching, therefore the prostate CTV COM had minimal inter-fractional displacements and typically remained within our PTV margins (lateral: -0.11±0.82 mm; anterior/posterior: +0.64±1.75 mm; superior/inferior: +0.07±1.37 mm). However, OAR displacements were more pronounced (Table 1). Increased inferior bladder (all fractions: -2.82± 8.98 mm, fraction 5: -3.40±8.84 mm), anterior bladder trigone (all fractions: +2.64±6.25 mm; fraction 5: +4.02±6.59 mm), and superior rectum (all fractions: +3.19±5.84 mm; fraction 5: +2.38±5.74 mm) displacements were observed during all fractions compared to the initial COM at Sim-CT. Further, the percentages of inter-fractional displacements surpassing 3 mm were considerable in the inferior bladder (all fractions: 75% >3mm; fraction 5: 82% >3mm), anterior bladder trigone (all fractions: 53% >3mm; fraction 5: 52% >3mm), and superior rectum displacements (all fractions: 62% >3mm; fraction 5: 65% >3mm).
Table 1. Displacement of pelvic organ center of mass compared to simulation CT (in mm). Note: Positive values denote superior, anterior, or leftward displacement of organ center of mass.
|
|
All Fractions
|
|
Fraction 5
|
|
|
Mean
|
|
SD
|
|
>3mma
|
|
Mean
|
|
SD
|
|
>3mma
|
CTVb
|
|
|
|
|
|
|
|
|
|
|
|
|
Lateral
|
-0.11
|
±
|
0.82
|
|
1%
|
|
-0.07
|
±
|
0.87
|
|
1%
|
|
Anterior/Posterior
|
0.64
|
±
|
1.75
|
|
10%
|
|
0.66
|
±
|
1.73
|
|
12%
|
|
Superior/Inferior
|
0.07
|
±
|
1.37
|
|
3%
|
|
0.37
|
±
|
1.44
|
|
6%
|
Bladder
|
|
|
|
|
|
|
|
|
|
|
|
|
Lateral
|
-0.03
|
±
|
2.84
|
|
26%
|
|
0.02
|
±
|
2.91
|
|
27%
|
|
Anterior/Posterior
|
-0.70
|
±
|
6.45
|
|
60%
|
|
-0.86
|
±
|
6.24
|
|
62%
|
|
Superior/Inferior
|
-2.82
|
±
|
8.98
|
|
75%
|
|
-3.40
|
±
|
8.84
|
|
82%
|
Bladder Trigone
|
|
|
|
|
|
|
|
|
|
|
|
|
Lateral
|
-0.19
|
±
|
1.64
|
|
8%
|
|
-0.14
|
±
|
1.90
|
|
12%
|
|
Anterior/Posterior
|
2.64
|
±
|
6.25
|
|
53%
|
|
4.02
|
±
|
6.59
|
|
52%
|
|
Superior/Inferior
|
-0.50
|
±
|
3.43
|
|
8%
|
|
-0.55
|
±
|
3.29
|
|
6%
|
Rectum
|
|
|
|
|
|
|
|
|
|
|
|
|
Lateral
|
-0.13
|
±
|
1.86
|
|
9%
|
|
-0.12
|
±
|
1.87
|
|
8%
|
|
Anterior/Posterior
|
-0.21
|
±
|
3.28
|
|
26%
|
|
0.05
|
±
|
3.14
|
|
24%
|
|
Superior/Inferior
|
3.19
|
±
|
5.84
|
|
62%
|
|
2.38
|
±
|
5.74
|
|
65%
|
a>3mm refers to percentage of >3mm displacements relative to center of mass at simulation CT
bCTV denotes prostate and seminal vesicles
Pelvic Organ Dosimetry
Over the course of SBRT, there was a significant but small increase in bladder mean dose (all fractions: +3.7±13.6%; fraction 5: +4.5±12.8%; P<0.01), a decrease in bladder trigone mean dose (all fractions: -2.1±11.0%; fraction 5: -3.6±9.6%, P<0.01), and an increase in rectum mean dose (all fractions: +8.4±14.3%; fraction 5: +7.0±12.9%, P<0.01) compared to baseline Sim-CT (Table 2). Evaluating for maximum dose exposure to OARs, there was no significant change in bladder D2cc dose (all fractions: +0.4±2.7%; fraction 5: +0.8±4.0%; p=0.28), a small but significant decrease in bladder trigone D2cc dose (all fractions: -3.0±23.9%; fraction 5: -6.2±15.6%; P<0.01), and a small but significant decrease in rectum D2cc dose (all fractions: -1.0±10.0%; fraction 5: -2.2±10.1%; P=0.04) from simulation D2cc.
Table 2. Trends in mean dose from simulation CT to fraction #5. ΔDose denotes percentage or absolute mean dose change from simulation CT to fraction #5. Fraction #1-5 mean doses were significantly different from simulation dose in all OARs (all P<0.01).
|
Prostate
|
|
Bladder
|
|
Bladder Trigone
|
|
Rectum
|
|
Mean
|
|
SD
|
|
Mean
|
|
SD
|
|
Mean
|
|
SD
|
|
Mean
|
|
SD
|
Simulation
|
102.80%
|
±
|
1.00%
|
|
42.10%
|
±
|
18.30%
|
|
93.50%
|
±
|
9.20%
|
|
43.90%
|
±
|
6.40%
|
Fraction 1
|
102.50%
|
±
|
1.00%
|
|
44.50%
|
±
|
18.80%
|
|
92.50%
|
±
|
9.90%
|
|
47.90%
|
±
|
8.70%
|
Fraction 2
|
103.40%
|
±
|
8.10%
|
|
46.80%
|
±
|
20.80%
|
|
92.10%
|
±
|
9.60%
|
|
47.50%
|
±
|
7.70%
|
Fraction 3
|
102.50%
|
±
|
1.00%
|
|
44.80%
|
±
|
19.80%
|
|
90.90%
|
±
|
10.80%
|
|
47.20%
|
±
|
8.30%
|
Fraction 4
|
102.50%
|
±
|
1.00%
|
|
46.40%
|
±
|
20.50%
|
|
90.20%
|
±
|
10.10%
|
|
47.10%
|
±
|
7.30%
|
Fraction 5
|
102.10%
|
±
|
3.20%
|
|
46.70%
|
±
|
19.90%
|
|
89.80%
|
±
|
10.50%
|
|
46.60%
|
±
|
7.10%
|
Δdose (%)
|
-0.60%
|
±
|
2.90%
|
|
4.50%
|
±
|
12.80%
|
|
-3.60%
|
±
|
9.60%
|
|
7.00%
|
±
|
12.90%
|
Δdose (Gy)
|
-0.2
|
±
|
1.1
|
|
1.8
|
±
|
4.8
|
|
-1.5
|
±
|
3.3
|
|
0.96
|
±
|
1.87
|
Volume as a Predictor of Displacement and Dose
A significant correlation was found between V5-SimBladder (bladder volume reduction over the course of treatment) and anterior displacement of the bladder trigone (ρ=-0.50; P<0.001). Anterior bladder trigone displacement was also significantly associated with Sim-CT bladder volume (ρ=0.30; P=0.005) and r2 (ρ=0.31; P=0.004). Despite these findings, bladder trigone dosimetry was not significantly associated with V5-SimBladder (P=0.12), VSim-CTBladder (P=0.35), or r2 (P=0.94). V5-SimRectum (rectal volume reduction over the course of treatment) was associated with superior rectal displacement (ρ=0.27; P=0.01) and mean rectal dose change (ρ=0.27; P=0.01). Rectal volume variation and volume at Sim-CT were not significantly associated with rectal displacement (P=0.89; P=0.92, respectively) or dosimetry (P=0.61; P=0.98, respectively).
Organ Volume and Position as Predictors of Treatment-Related Sequalae
In 71 patient who underwent single modality SBRT, clinically significant acute GU toxicity (≥grade 2) were observed in 12.7%, late ≥grade 2 GU toxicity in 35.2% of patients (Table 3). No clinically significant acute GI toxicity events were seen and only 4.3% of patients presented with late ≥grade 2 GI toxicity. No significant correlations were found between relative bladder volume changes, rectum volume changes, or anterior bladder trigone displacements with rate of GU/GI toxicities in 71 patients who underwent single modality SBRT alone. Relative bladder volume changes from simulation to fraction 5 were not predictive of acute GU toxicity events (P=0.47) or late GU toxicity events (P=0.28). Anterior bladder trigone displacement was also not significantly associated with an increase in acute GU toxicity (P=0.27) or late GU toxicity (P=0.39). Due to the lack of acute GI toxicity events (n=0) and insufficient late GI toxicity events (n=3; 4.3%), data were not sufficient for statistical analysis. Patients who received combination SBRT and brachytherapy (n=14) were excluded from toxicity analysis to account for the possible confounding effect of toxicities related to low dose rate seed placement.
Table 3. Acute and late genitourinary and gastrointestinal toxicity events in single modality prostate SBRT cases (N = 71).
|
Genitourinary Toxicities
|
|
Gastrointestinal Toxicities
|
|
< Grade 2 (%)
|
≥ Grade 2 (%)
|
|
< Grade 2 (%)
|
≥ Grade 2 (%)
|
Acute (<30 days)
|
12 (16.9)
|
9 (12.7)
|
|
2 (2.8)
|
0 (0.0)
|
Late (≥30 days)
|
16 (22.5)
|
25 (35.2)
|
|
11 (15.5)
|
3 (4.3)
|