Oncological safety of autologous breast reconstruction after mastectomy for invasive breast cancer

This retrospective study was approved by the Medical Ethical Committee of the University Hospitals Leuven (S54875). A prospectively maintained database was used to identify all female patients with invasive breast cancer who underwent mastectomy from January 2000 until December 2011. Most patients had a large portion of carcinoma in situ as well, making them eligible for a treatment by mastectomy. Patients with only a carcinoma in situ were excluded. A final study population of 2326 patients was achieved after applying in- & exclusion criteria as shown in Fig. 1. The age cut off was based on the oldest patient in the reconstruction group.

A team of 5 experienced breast surgeons performed the mastectomy. The ABR was carried out by 3 reconstructive plastic surgeons. In conjunction with the mastectomy, all patients underwent axillary staging by sentinel lymph node biopsy and/or axillary lymph node dissection. Isolated tumour cells alone are not considered as a positive lymph node status, whereas micrometastases are considered as lymph node positive. All patients received adjuvant treatment according to the institutional guidelines. The main indication for immediate ABR was early stage breast cancer with a low estimated risk for adjuvant radiotherapy and/or chemotherapy. Therefore, comparatively few immediate breast reconstructions were performed. Delayed reconstruction was offered to patients preferably at least 2 years after the primary surgery. Patients who opted for another reconstruction technique (e.g. implant based) are considered in the non-reconstruction group, as the amount of surgical stress is significantly lower with these techniques.

The patients were all followed at the Multidisciplinary Breast Centre of the University Hospitals Leuven. The follow-up started from the time of mastectomy until the date of relapse, the date of death, or the date of last follow-up. As patients are followed at least annually at our centre, patients were considered lost to follow-up, if patients were still alive and the date of the last follow-up exam was more than 18 months before the end of the study. Local and axillary nodal recurrences were considered as locoregional recurrences. Metastases were considered as distant relapse. Contralateral invasive breast tumours were considered as new primary breast tumours. To test the hypothesis of tumour dormancy, the focus of this study was on the distant metastases.

The analysis of the patient data was based on the Cox proportional hazards model. To account for the occurrence of a delayed ABR, the model included the ABR status as a time-varying covariate. Differences between both groups (ABR and non-ABR) were analysed. Variables presented with percentage were analysed using a Chi-square test and the variables summarized by medians and range were analysed using a Mann-Whitney U test. A multivariable model including several prognostic factors was used to correct for possible confounding. Age at mastectomy, tumour grade, invasive tumour size, tumour type, lymphovascular invasion (LVI), lymph node status, ER/PR status and Her-2 status were considered as possible confounders [21‐23]. Follow-up summary statistics are based on the Kaplan-Meier estimates of potential follow-up [24]. To explore whether the development of metastases after an ABR was time-dependent, the cumulative probability to develop metastases was calculated over time (Kaplan-Meier estimates). Furthermore, a graph was constructed to present the evolution of the risk of metastasis over follow-up time. In this graph, the hazard (risk) of developing metastases was calculated within a (moving) time-window of 2 years to obtain a sufficiently smooth curve. The risk at a specific follow-up time was then calculated based on values observed in the period defined by the indicated time plus and minus 2 years. All statistical analyses were performed using SAS® software, version 9.2 (AS Institute Inc., Cary, NC, USA).

A total of 2326 patients met the inclusion criteria, 485 patients underwent an ABR and 1841 patients underwent a mastectomy alone. An immediate reconstruction was performed in 143/485 patients (30%), a delayed reconstruction in 342/485 patients (70%). Overall, the time from mastectomy to delayed breast reconstruction ranged from 1 to 117 months and a median of 22 months. ABR was performed using a variety of microvascular flaps, including deep inferior epigastric perforator (DIEP) flap (n = 417), superficial inferior epigastric artery (SIEA) flap (n = 27), superior gluteal artery perforator (SGAP) flap (n = 19), transverse rectus abdominus myocutaneus (TRAM) flap (n = 2), or a combination of microvascular flaps (n = 20). Clinicopathological characteristics for the entire study population by reconstruction group are shown in Table 1. The median age at mastectomy, the median Nottingham Prognostic Index (NPI), the median invasive tumour size in mm and the lymph node status were significantly different between both groups (p-value < 0.05). The median follow-up time of the entire cohort (from mastectomy to last contact) was 68 months (range 1–153 months). The median follow-up time for the ABR group was 76 months (range 4–152 months) and 68 months for the non-ABR group (range 1–153 months). One hundred forty-three of 2124 alive patients were lost to follow-up (7%), 22 patients were lost to follow-up in the ABR-group (5%) and 121 patients in the non-ABR group.

Overall, 323/2326 (14%) patients developed distant metastases. 282/1841 (15%) patients in the mastectomy alone group and 41/485 (8%) patients in the ABR group had metastases (univariate HR 0.70, 95% CI 0.50–0.97, p = 0.0323). After adjustment for possible confounding, the multivariable Cox model showed no longer a statistically significant difference in distant relapse risk between patients with and without an ABR (multivariate HR 0.82, CI 0.55–1.22, p = 0.3301) (Table 2). Tumour grade and lymph node status were the most important prognostic factors (both p <  0.0001). As the variable LVI contained a high percentage of missing data, LVI was considered as a three-category variable with values ‘Yes’, No and Unknown, to avoid the loss of a large number of observations. Next, the development of metastases after ABR was analysed whether it was time-dependent. Kaplan Meier estimates for the cumulative hazard of metastases after reconstruction (Fig. 2a) were calculated. The results do not demonstrate an increase of metastases for earlier follow-up times compared to later follow-up times. Additionally, the smoothed hazard function suggests a rather stable risk up until 5 years after the ABR (Fig. 2b).

Locoregional relapse rate was low: 3/485 patients (0.6%) in the ABR group and 44/1841 (2.4%) patients in the non-ABR group. All 3 locoregional recurrences in the ABR group were rather early events after an immediate ABR: two local recurrences after 19 and 28 months and 1 nodal recurrence after 13 months. Of all the patients who had a locoregional recurrence, 28/47 (60%) also developed distant metastases during follow-up. Within this group, 15/28 patients had synchronous locoregional and distant recurrence and in 13/28 patients, the distant recurrence was detected after the locoregional recurrence. A Kaplan Meier curve for distant-disease free survival (DDFS) is shown in Fig. 3.