A comparison of liver protection among 3-D conformal radiotherapy, intensity-modulated radiotherapy and RapidArc for hepatocellular carcinoma

Patients who underwent RT for primary HCC were registered and the database was retrospectively reviewed from January 2010 to March 2013 at Shandong Cancer Hospital. Eligibility criteria were as follows: (1) All patients underwent alpha-fetoprotein examination, contrast-enhanced computed to tomography, and ultrasonography to confirm the diagnosis. (2) No one had cirrhosis or portal vein thrombosis; (3) All patients had centrally located lesions on the right liver lobe; (4) Computed tomography scanning included whole liver, and bilateral kidney with a 3-mm slice thickness. (5) The patients experienced transarterial chemoembolization (TACE) or not. Informed consent was obtained from all patients, and the local Ethical Board approved the study protocol (Shandong tumor prevention and control institute ethics committee).

The patients were fixed using vacuum casts in a supine position with both arms raised above their heads. There was no respiratory control training or other means to decrease degree of excursion of the liver. We defined the gross tumor volume (GTV) as the volume of primary tumor evident on contrast-enhanced CT images. The clinical target volume (CTV) was delineated on the basis of the GTV expanded by 5 mm. The planning target volume (PTV) was defined as the CTV with a 5-mm radial expansion and a 10-mm craniocaudal expansion to account for errors caused by the daily setup process and internal organ motion [13]. The OARs considered were healthy liver (whole liver minus PTV), kidneys, spinal cord and stomach. The target delineation was performed by the same experienced oncologist. Three sets of plans were all designed on the Varian Eclipse version 8.6.23 treatment planning system which was equipped with a Millennium multileaf collimator (MLC) (Varian) with 120 leaves. For 3DCRT and IMRT plans, all the gantry angles and radiation fields were confirmed according to the relationship of the PTVs and OARs to different situations, and the number of fields varied from 4 to 7. For RA, the plan was generated using two arcs rotating from 55° to 181° anticlockwise and from 181° to 55° clockwise with the dose rate varied between 0 MU/min and 600 MU/min (upper limit). A fixed DR of 300 MU/min was selected for IMRT and 3DCRT. All three sets of plans were designed by the same experienced physicist using 6- or 15-MV photon beams.

The total prescribe dose was 50 Gy/25f. The planning objectives were to cover at least 95% of the PTV with the 90% isodose, to have minimum dose > 90% and maximum dose <110%. All plans were normalized to the mean dose of PTV to avoid any bias. For OARs, the tolerated maximum dose of spinal cord was 40 Gy. The mean dose of liver was limited to 30 Gy and V₃₀ <50%. The mean dose of kidneys were 23 Gy (at least one side) and V20 <20%, the mean dose of stomach <20 Gy [13, 14]. For PTV, V_x% means the volume receiving ≥ x% of the prescribed dose. For example, the V_95% means the volume receiving at least 95% of the prescribed dose and V_110% is used to represent the hot spot in the PTV. The conformal index (CI) = V_t,ref/V_t × V_t,ref/V_ref,where V_t was the volume of PTV, V_ref was the volume enclosed by the prescription dose line, and V_t,ref is the volume of PTV within V_ref[15]. The target homogeneity was defined as: HI = D_5%/D_95% where D_5% and D_95% are the minimum doses delivered to 5% and 95% of the PTV [16, 17]. The value of HI and CI range from 0 to 1. The more approximate to 1, the better [18].

For OARs, the parameters included the mean dose, the maximum dose expressed as D_1% and a set of appropriate V_x, and D_y, where V_x means the volume of the OARs receiving the dose > x Gy. For example, V₅ of liver means the volume of normal liver receiving >5 Gy and presents low-dose exposure for the normal liver. D_1% of spinal cord presents the maximum dose spinal cord received.

What is more, the number of monitor units (MUs) per fraction and beam-on time were also analyzed to compare the efficiency of three sets of the plans. The treatment delivery time was defined as the time recorded between beam-on for the first field and beam-off for the last field.

The characteristics of patients are summarized in Table 1. There were 16 males and 4 females, and their median age was 60 years (range, 41–65 years). The PTV was 775.39 ± 361.98 (range, 107.53-3568.03 cm³). We divided our patients into two groups according to the median value (D = 8 cm) of the tumor diameter. There was no whole liver included into the PTVs. Table 2 showed the results with the mean value ± standard deviation for the considered parameters of OARs. Table 3 showed the parameters of dose-volume histograms (DVHs) with the mean value ± standard deviation for PTV, MU and delivery time. Table 4 showed the predictive parameters for RILD with the mean value ± standard deviation of three techniques for larger (D > 8 cm) and smaller (D ≤ 8 cm) tumors of our study. Figures 1 and 2 showed the dose distributions of two examples for axial, sagittal, and coronal views for smaller and larger tumors. Figures 3 and 4 showed DVHs of the PTVs and healthy liver compared among the three plans for the patients corresponding with Figures 1 and 2.

The coverage of PTVs of the three plans were evaluated by prescribed dose (V_100%), HI and CI. All 95% of prescribed dose could cover at least 99% of the PTV without any significant difference for three plans. The value of CI for 3DCRT (0.72 ± 0.03) was significantly lower than that of IMRT (0.83 ± 0.04) (p <0.001) or RA (0.84 ± 0.05) (p <0.001). The V_95% and V_100% values were 99.73 ± 0.28 and 80.57 ± 1.23 for 3DCRT, 99.25 ± 1.20 and 79.83 ± 4.01 for IMRT, 99.23 ± 1.21 and 78.56 ±3.50 for RA, respectively, and no significant difference was observed. HI for 3DCRT (1.16 ± 0.01) was higher than RA (1.09 ± 0.03) (p = 0.041). For the hot spot sparing, the mean V_110% of the PTV was significantly higher for 3DCRT (9.33 ± 8.58) than IMRT (3.31 ± 3.09) (p <0.001) or RA (2.12 ± 1.56) (p <0.001). In the typical examples in Figures 1 and 2, RA and IMRT achieved better conformity of the PTV compared with 3DCRT.

The mean dose of the normal liver for each plan was 20.57 ± 7.12 Gy for 3DCRT, 22.34 ± 7.33 Gy for IMRT, and 20.51 ± 7.12 Gy for RA. We could see a higher value of IMRT compared with 3DCRT (p = 0.045), but no difference was found between RA and 3DCRT. For the low-dose region, V₅ was significantly highest for RA (76.34 ± 19.12) and the lowest for 3DCRT (68.90 ± 19.23), and the difference between IMRT and 3DCRT, IMRT and RA, 3DCRT and RA were respectively 0.02, 0.015 and 0.007. For V₁₀, RA (64.71 ± 21.63) was higher than 3DCRT (60.37 ± 21.54, p = 0.004), IMRT (65.12 ± 21.62) was higher than RA (p = 0.031). No significant difference was observed between IMRT and 3DCRT (p = 0.274). For V₂₀, RA(43.94 ± 20.10) was lower than 3DCRT (48.34 ± 21.13) (p = 0.012). For V₃₀ and V₄₀, 3DCRT (22.27 ± 17.30 and 27.73 ± 18.73) was higher than IMRT (22.57 ± 15.73 and 17.94 ± 10.13) (p = 0.002 and p = 0.012, respectively) or RA (21.93 ± 14.30 and 17.93 ± 10.24) (p = 0.013 and p = 0.038, respectively). In the DVHs in Figures 3 and 4, Right figure revealed similar homogeneity of the PTV for 3 plans and 3DCRT obtained highest volume of hot spot. In Figure 3, left figure showed that RA obtained the highest low-dose distribution in the normal liver compared with 3DCRT and IMRT. 3DCRT obtained the highest high-dose distribution in the normal liver compared with IMRT and RA. In Figure 4, left figure showed that the low-dose distributions for three techniques were similar. For V₂₀ and V₃₀, the value of 3DCRT was higher than IMRT or RA, but no statistical significance was observed (Table 4). For D_mean of stomach, bilateral kidneys and the maximum dose spinal cord received (D_1%), there were no significant differences.

For smaller tumors (D ≤ 8 cm), no difference was observed among three techniques for D_mean,V₂₀, and V₃₀. For V₅ and V₁₀, RA (66.18 ± 20.74, 47.62 ± 11.55) was significantly higher than 3DCRT (58.30 ± 18.04 and 43.21 ± 10.09) (p = 0.019 and p = 0.017) or IMRT (60.20 ± 17.62 and 42.50 ± 8.26) (p = 0.084 and p = 0.08). For larger tumors (D > 8 cm), the D_mean of 3DCRT was lower (25.31 ± 2.73) than IMRT (27.49 ± 2.33) (p = 0.014) or RA (27.01 ± 2.18) (p = 0.026). For V₅, V₁₀, V₂₀, and V₃₀, no difference was observed among three techniques.

The values of MUs were 250.4 ± 16.20 for 3DCRT, 853.2 ± 299.28 for IMRT and 435.5 ± 134.8 for RA with a significantly higher MUs for IMRT compared with 3DCRT (p <0.001) or RA (p = 0.007). What is more, IMRT had a much longer delivery time (2.18 ± 1.10 min) compared with 3DCRT (0.92 ± 0.05 min) (p <0.001) or RA (0.75 ± 0.13 min) (p <0.001).