Comparison of postoperative CT- and preoperative MRI-based breast tumor bed contours in prone position for radiotherapy after breast-conserving surgery

We collected clinical records and imaging data (including pre-MRI and postoperative planning CT data) of patients with early-stage breast cancer between June 2016 and June 2018, who have undergone breast conservative surgery and were pathologically diagnosed with invasive ductal carcinoma (pathologically T1-2; N0-1; M0) with 3–9 titanium clips intraoperatively placed within the LCs and scheduled to adjuvant radiotherapy. Patients who received neoadjuvant chemotherapy or endocrinotherapy with oncoplastic surgery or harboring contraindication or intolerant for MRI were excluded. This study was approved by the institutional review board of Shandong Cancer Hospital and Institute, and all participants signed the informed consents.

The pre-MRI was performed with a mean of 2.3 days (range, 1–7) before the breast-conserving surgery at our institution, for a standard imaging protocol, which includes six sequences: T1W, T2W, T2W-SPAIR (T2-weighted spectral attenuated inversion recovery), DWI (diffusion-weighted imaging), dyn-eTHRIVE (dynamic-enhanced T1 high-resolution isotropic volume excitation), and sdyn-eTHRIVE (subtraction of dynamic-enhanced T1 high-resolution isotropic volume excitation). The images of sdyn-eTHRIVE, named by Philips, were subtracted with the original images prior to the administration of contrast agents from enhanced images, which could reduce the influence of non-tumor-enhanced tissue or normal gland tissue on the tumor mass judgment. The CT scan was acquired after the operation about 99 days at average (range: 26–204 days) in prone position by using a specific immobilization device (Supplementary Figure 1). This process was undertaken on a big-bore CT scanner (Brilliance, Philips, Neth.) and scanned from the cricothyroid membrane to the lower edge of the liver with 3-mm interslice thickness. The field of view (FOV) of CT is 450 mm, and the pixel value is 512 × 512. Consistent with pre-MRI for better registration, the slice thickness of post-CT was reconstructed to 4 mm. The surgical scars were labeled by metal wires to help determine the rough location of TB. The MRI images were obtained in routine position (prone) with the use of a 3.0-T MR scanner with a 60-cm bore (Achieva 3.0T, Philips Healthcare) with special double-acupoint 16-channel breast surface coil (Supplementary Figure 2). Among this, with no slice gap, the T1W, T2W, T2W-SPAIR, and DWI were collected with a slice thickness of 4 mm, but the slice thickness of dyn-eTHRIVE was 1 mm, so did the sdyn-eTHRIVE. The slice thickness of dyn-eTHRIVE and sdyn-eTHRIVE was reconstructed to 4 mm to maintain consistency among all sequences. The parameters of T1W, T2W, T2W-SPAIR, DWI, and dyn-eTHRIVE, such as echo time (TE), repetition time (TR), FOV, pixel values, and other corresponding parameters, are listed in Table 1. As well, with b-factors of 0 and 800 s/mm² in one scan of DWI, the images with b = 800 s/mm² were selected as representatives for DWI, which shows a clearer outline of the tumor lump on most patients, notwithstanding at the expense of some pixels. The dyn-eTHRIVE is characterized as eight sequences (1–8) obtained by a phase before the injection of the contrast-enhancing agent plus 7 consecutive repetition phases, that is, the continuous uninterrupted scanning performed 7 times after the injection of the contrast agent immediately. We used a 20-mL high-pressure syringe of bolus-injected gadopentetate dimeglumine (0.1 mmol/kg) at 3 mL/s followed by a 15-mL saline flush to get the enhancing images. Considered the characteristics of early enhancement of invasive ductal carcinoma [20], combined with the clinical recommendations of the MRI radiologists, we delineated the target volume on the image of 2, 3, 4, and 5 phases and select the 3 phase image as the representative image of the dyn-eTHRIVE sequence. Likewise, the phase before the injection of the contrast-enhancing agent subtracted from the 3 phases of dyn-eTHRIVE was chosen to delineate the sdyn-eTHRIVE.

The MRI images were transferred to Eclipses’ Treatment Planning Systems (TPSs) for registration and delineation. All MRI sequences were respectively conversed to head-first prone status to register with CT on the basis of rigid registration accompanied with manual alignment registration by application of titanium clips, the lump, and various anatomic features including the nipple, sternum, and vertebra, especially the mammary glands. Focus laid on the mammary gland concordance. Next, the concordance between the TB determined by the clips and the primary lump was also taken into account, equally, lying in accurate registration, which contributes to better comparison of consistency parameters.

The TB delineation of CT and all MRI sequences was entirely performed from only a single modality by an experienced radiation oncologist to avoid inter-observer variation. Meanwhile, it was verified by another oncologist according to the criterion of the Radiation Therapy Oncology Group (RTOG) [9]. The whole breast is outlined on the CT to calculate the volume. The clips, seroma, and surgical scars were applied to guide the CT-based contours for CTVs, while the tumor as visualized on MRI was defined as the standard gross target volume (GTV) for MRI-based delineations. The target volume contours (CTV-CT and GTV-T1, GTV-T2, GTV-T2-SPAIR, GTV-DWI, GTV-dyn-eTHRIVE, and GTV-sdyn-eTHRIVE) were performed on the axial slices; simultaneously, sagittally and coronally reconstructed images could be used to verify the delineations. The corresponding CTV-MRI was obtained respectively by extrapolating 1.0 cm of the GTV-MRI based on the MRI sequence according to the surgeon’s clinical experience and the expert consensus (Fig. 1). And various PTVs were defined as unified margins of 15 mm expanded based on the corresponding TBs, and trimmed 5 mm from the skin to the breast-chest wall interface (Fig. 2). Each MRI sequence was scheduled to register to CT, respectively. The consistence index (CI) and dice coefficient (DC) of CTVs and PTVs between CT and each MRI sequence were measured to quantify the extent of overlap of two volumes; the geographical miss index (GMI) and normal tissue index (NTI) were considered as non-conformity parameters between different imaging modalities. DC = 1 represents perfect overlap, while DC = 0 represents no overlap. The specific calculation of these parameters is shown in Fig. 3. The cavity visualization score (CVS) of CT was also evaluated. CVS = 1 means that the cavity was not visualized; CVS = 2 means that the cavity was visualized with indistinct margins; CVS = 3 means that the cavity was visualized with some distinct margins and heterogeneous appearance; CVS = 4 means that the cavity had distinct margins in the majority of LC with mild heterogeneity; and CVS = 5 means that the cavity has distinct margins in the entire LC with a homogeneous appearance [21].

In total, the pre-MRI and postoperative planning CT data of 81 patients were acquired and 22 of these (27.2%) were eligible for analysis. A total of 59 patients (72.8%) were excluded due to not fulfilling the specific inclusion criteria, incomplete clinical records, or unclear imaging data. The detailed data of the enrolled 22 patients are listed in Table 2. For the entire group, the mean ± SD values of the CTVs were 37.350 ± 13.699, 35.255 ± 14.429, 35.827 ± 15.607, 36.891 ± 14.739, 34.086 ± 13.290, 34.191 ± 12.171, and 34.032 ± 12.422 cm³ for CT, T1W, T2W, T2W-SPAIR, DWI, dyn-eTHRIVE, and sdyn-eTHRIVE, respectively. For PTVs, the mean ± SD values were 181.246 ± 42.576, 170.023 ± 42.827, 171.082 ± 44.788, 173.564 ± 42.888, 166.641 ± 40.205, 165.873 ± 37.476, and 164.014 ± 37.787 cm³ for CT and abovementioned MRI sequences, respectively. The CTVs and PTVs in MRI sequences were all smaller than those in CT. The differences of delineation volumes between all sequences (CT and MRI) were significant, both in the CTVs (F = 2.354, p = 0.035) and PTVs (F = 6.464, p < 0.01). Specifically, in CTVs, only the volume of delineation in sdyn-eTHRIVE was significantly different from that in CT (p = 0.047). As for PTV delineation, volume in each MRI sequence was significantly different (p < 0.05) from that in CT, except the T2W-SPAIR (p = 0.088). Therefore, when compared with other MRI sequences, the CTVs and PTVs of sdyn-eTHRIVE are effectively distinguished from the corresponding target volume of CT, as seen in Table 3.

The mean and SD of the consistent parameters between CT and each MRI sequence about CTV are listed in Table 4. With CI compared, there was a significant difference (p < 0.05) among different registrations (different MRI sequences registered to CT), as well can be seen in DC and GMI. Specifically, as for CI and DC, each MRI registration to CT was significantly different (all p < 0.05) from CT-sdyn-eTHRIVE, except the CT-dyn-eTHRIVE. And significant difference in the value of GMI could only be found between CT-T2W-SPAIR and CT-sdyn-eTHRIVE (p = 0.001). However, with the NTI compared, there was no significant difference (p > 0.05) among different registrations, meanwhile the values of the conformity parameters CI and DC of CT-sdyn-eTHRIVE were the largest among all MRI registrations to CT, and the non-conformity parameters GMI and NTI were the smallest, which indicated that the overlap between the two sequences is the most.

The consistent parameters between CT and each MRI sequence for PTVs are shown in Table 5. Only the differences of GMI between different MRI sequence registrations to CT were significant (p < 0.05), and CT-T1, CT-T2, and CT-T2W-SPAIR were significantly different from CT-sdyn-eTHRIVE (all p < 0.05), respectively. Similarly, the overlap of sdyn-eTHRIVE to CT is the most in comparison with other MRI sequences to CT.

We found that there is no obvious linear correlation (p > 0.05) between the CI derived from the registration of CT and sdyn-eTHRIVE of CTV with the breast volume, the CVS of CT, the time interval from surgery to CT simulation, the maximum diameter of the intraoperative mass, and the number of titanium clips, respectively (Fig. 4).