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Open Access 27-10-2023

Health-related quality of life (HRQoL) after different axillary treatments in women with breast cancer: a 1-year longitudinal cohort study

Auteurs: N. J. M. C. Vrancken Peeters, Z. L. R. Kaplan, M. E. Clarijs, M. A. M. Mureau, C. Verhoef, T. van Dalen, O. Husson, L. B. Koppert

Gepubliceerd in: Quality of Life Research | Uitgave 2/2024

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Abstract

Purpose

As life expectancy continues to rise, post-treatment health-related quality of life (HRQoL) of breast cancer patients becomes increasingly important. This study examined the one-year longitudinal relation between axillary treatments and physical, psychosocial, and sexual wellbeing and arm symptoms.

Methods

Women diagnosed with breast cancer who received different axillary treatments being axilla preserving surgery (APS) with or without axillary radiotherapy or full axillary lymph node dissection (ALND) with or without axillary radiotherapy were included. HRQoL was assessed at baseline, 6- and 12-months postoperatively using the BREAST-Q and the European Organization for Research and Treatment of Cancer QoL Questionnaire Breast Cancer Module (EORTC QLQ-BR23). Mixed regression models were constructed to assess the impact of axillary treatment on HRQoL. HRQoL at baseline was compared to HRQoL at 6- and at 12-months postoperatively.

Results

In total, 552 patients were included in the mixed regressions models. Except for ALND with axillary radiotherapy, no significant differences in physical and psychosocial wellbeing were found. Physical wellbeing decreased significantly between baseline and 6- and 12-months postoperatively (p < 0.001, p = 0.035) and psychosocial wellbeing decreased significantly between baseline and 12 months postoperatively (p = 0.028) for ALND with axillary radiotherapy compared to APS alone. Arm symptoms increased significantly between baseline and 6 months and between baseline and 12 months postoperatively for APS with radiotherapy (12.71, 13.73) and for ALND with radiotherapy (13.93, 16.14), with the lowest increase in arm symptoms for ALND without radiotherapy (6.85, 7.66), compared to APS alone (p < 0.05).

Conclusion

Physical and psychosocial wellbeing decreased significantly for ALND with radiotherapy compared to APS alone. Shared decision making and expectation management pre-treatment could be strengthened by discussing arm symptoms per axillary treatment with the patient.
Opmerkingen

Supplementary Information

The online version contains supplementary material available at https://​doi.​org/​10.​1007/​s11136-023-03538-3.

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Background

Breast cancer is one of the most prevalent types of cancer among women, with an incidence of 16.000 new cases of invasive breast cancer per year in the Netherlands [13]. Due to the introduction of multiple novel therapies, the 10-year survival rate has gradually increased from 56 to 83% [4, 5]. Although the improvements in life expectancy are very promising, this also means that patients have to live with the possible negative consequences of breast cancer diagnosis and treatment which may affect their health-related quality of life (HRQoL), addressing the need for tailored treatment regimens [6, 7].
Axillary lymph node metastases are an important predictor of survival and recurrence in breast cancer patients and make treatment beyond the breast necessary [811]. In the early 90 s, the Sentinel Lymph Node Biopsy (SLNB) was introduced as a less invasive diagnostic for axillary lymph node staging in clinically node-negative (cN0) breast cancer patients [12]. If histopathological examination determined tumour-positive cells in the SLNB, several treatment options could follow, including an axillary lymph node dissection (ALND) and radiotherapy at different lymph node levels [13]. Treatment with ALND can be safely omitted in case of early stage breast cancer in a selection of patients who are treated with adjuvant chemotherapy or radiotherapy [1417]. In comparison, clinically node-positive (cN +) patients were until recently, routinely treated with an ALND combined with or without axillary radiotherapy, also after neoadjuvant treatment, irrespective of their response to systemic treatment [13].
Axillary treatment with ALND and radiotherapy can cause significant upper extremity morbidities, such as disfunction of the arm, radiation fibrosis and lymphedema causing a decrease in HRQoL [1820]. Recently, less invasive approaches for axillary treatment in cN + patients were introduced, known as Marking the Axilla with Radioactive Iodine seeds (MARI) procedure and Radioactive Iodine Seed Localization in the Axilla With the Sentinel Node (RISAS) procedure, a form of targeted axillary dissection [2123]. The RISAS procedure is a combination of the SLNB and MARI procedure [22]. The marking procedure with iodine seeds is very elegant since, due to its long half lifetime, this marker stays radioactive during the months neo-adjuvant treatment is given. Additional treatment with ALND can be safely omitted when patients have a complete pathologic response according to the RISAS after neo-adjuvant treatment [21, 24]. Axillary preserving surgery has been associated with fewer complications compared to ALND and may, therefore, result in better HRQoL outcomes in breast cancer patients [16, 17, 2527].
Previous studies have mainly focused on oncological outcomes of different axillary treatments in terms of overall survival or disease free survival [1417, 28, 29]. Several studies have tried to investigate the effect of axillary treatment on HRQoL but lacked the inclusion of novel axillary preserving techniques or radiotherapy to the axilla. Additionally, the methodological quality shows wide variability with relative small sample sizes and lack the inclusion of baseline HRQoL measurements [26, 3032]. Therefore, to enhance expectation management and shared decision-making, the objective of this study was to examine the longitudinal relation between different axillary treatments and HRQoL regarding the first year after surgery.

Methods

This is a longitudinal cohort study of women with breast cancer who received different axillary treatments for lymph node staging and/ or metastasis at the Erasmus MC Cancer Institute in the Netherlands between November 1st, 2015, and January 1st, 2022. Inclusion criteria were women with a diagnosis of breast cancer who received axillary treatment and who completed Patient-Reported Outcome Measures (PROMs) in the “patient data platform”, Erasmus MC’s online PROM collection tool [33]. Exclusion criteria were patients who underwent proton therapy, palliative treatment, patients with recurrent breast cancer or if data on treatment were missing.

Treatment

QoL was compared between four different axillary treatment groups, namely: [1] patients with axilla preserving surgery (APS) including SLNB and RISAS, [2] patients with an ALND (whether or not preceded by APS), [3] patients with APS followed by axillary radiotherapy and [4] patients with an ALND followed by axillary radiotherapy. In a SLNB, the median number of lymph nodes removed is 2. The RISAS procedure involves the removal of the marked lymph node metastasis plus the SLNB, which are in 71.3% the same lymph nodes. During an ALND usually a minimum of 10 lymph nodes are removed. The SLNB and RISAS procedure are combined in to one group since they only differ by a maximum of one lymph node in less than 30% of the cases.
Surgical treatment of the breast included either breast-conserving surgery (BCS) or mastectomy with or without reconstruction. Chemotherapy, hormonal therapy, and/ or (loco)regional radiotherapy were given to patients according to the national guidelines for breast cancer.

Data-collection procedure

Data on sociodemographic factors, clinical treatment and tumour characteristics were retrospectively collected from medical records. These variables entailed, age at diagnosis, body mass index (BMI), gene mutation, presence of bilateral cancer, hormone receptor status, her2Neu receptor status and stage of disease at presentation (TNM staging system). Treatment characteristics entailed radiotherapy of the axilla and/or breast/ chest, parasternal radiotherapy, neo-adjuvant and/or adjuvant chemo(immuno)therapy, neo-adjuvant and/or adjuvant hormonal therapy, type of breast surgery and type of axillary treatment.

HRQoL assessment

HRQoL data are routinely collected within the Erasmus MC Cancer Institute at baseline (first doctors visit; after diagnosis and before treatment initiation), at 6 months and at 12 months postoperatively according to the ICHOM Breast Cancer standard set [33, 34]. In this study, breast cancer specific questionnaires were used to assess HRQoL, namely the BREAST-Q and the EORTC QLQ-BR23 [35, 36]. In the statistical analysis only those domains in both questionnaires that are considered clinically the most relevant for comparing different axillary treatments were included to prevent the issues of multiple testing.
The BREAST-Q consists of two overarching themes, namely HRQoL and Patient Satisfaction. The HRQoL domains include psychosocial, sexual, and physical well-being. The satisfaction domains include satisfaction with breasts, outcome, and care. Scores of each domain range from 0–100 with higher scores representing better HRQoL and satisfaction. A minimal important difference score of 4 points was considered clinically relevant [35, 37]. Domains on psychosocial, physical, and sexual wellbeing from the BREAST-Q were included in the statistical analysis.
The EORTC QLQ-BR23 is a breast cancer-specific questionnaire consisting of 23 items. It incorporates functional scales and breast cancer specific symptom scales. Each item is scored on an ordinal scale: 1 = not at all, 2 = a little, 3 = quite a bit, 4 = very much [36]. According to the EORTC scoring manual, the EORTC QLQ-BR23 scores were linearly transformed to a numeric score (range 0–100) [36, 38]. For functional scales, higher scores represent a better level of functioning. Within the symptom-oriented scales, higher scores represent more severe symptoms. A minimal important difference score of 5 points on the transformed 0 to 100 scale was considered clinically relevant [38, 39]. The domain on arm symptoms from the EORTC QLQ-BR23 was included in the statistical analysis.

Data analysis

Descriptive statistics, including frequencies and proportions, were used to describe patient, tumour, and treatment characteristics. Depending on the type of variable, ANOVA and Chi-square tests were used to compare the baseline characteristics of the four treatment groups. Means, standard deviations and percentages were calculated to present the results of HRQoL for each axillary treatment group. In addition, the percentages of missing values were also calculated. All scores were tested for normality with the Kolmogorov–Smirnov and Shapiro–Wilk tests. If normally distributed, parametric ANOVA tests were used to compare HRQoL between the pre-defined axillary treatment groups. If not normally distributed, non-parametric Kruskal–Wallis tests were used.
The longitudinal nature of the data, with repeated measurements within one patient (i.e., scores at baseline, 6- and 12- months postoperatively) induces correlation among these measurements and demands a multilevel approach. Therefore, to assess the effect of different axillary treatments on psychosocial wellbeing, physical wellbeing, sexual wellbeing, and arm symptoms, mixed effect linear regression was used. Patient was included as a random effect and the following fixed effects were adjusted for; age at diagnosis, BMI, type of breast surgery, radiotherapy of breast/chest, parasternal radiotherapy, neo-adjuvant hormonal therapy, neo-adjuvant chemo(immuno)therapy, postoperative hormonal therapy, and postoperative chemo(immuno)therapy. To avoid multicollinearity, tumour characteristics were not included as variables in the mixed models since they determine the treatment protocol. To analyse the impact of axillary treatment at different time points, an interaction term between time (baseline, 6 months, and 12 months) and axillary treatment was included in the model. APS without additional axillary radiotherapy was chosen as reference group since this is the least extensive axillary treatment. The effect of the different axillary treatments, between the different time periods, on the predefined outcomes was expressed as the delta. Delta 1 represents the change in HRQoL from the baseline measurement to 6 months postoperatively, and delta 2 represents the change in HRQoL from baseline to 12 months postoperatively. The delta gives more intuitive information compared to the crude measurements as it represents the relative effect of treatment on HRQoL. Positive deltas in BREAST-Q domains indicate an improvement in HRQoL, negative deltas a decline in HRQoL. Conversely, positive deltas in the arm symptoms domain of the EORTC QLQ-BR23 reflect an increase in arm symptoms and negative deltas a reduction in arm symptoms since this is a symptom orientated domain.

Non-responder analysis

Because not all patients in the patient data platform completed all PROMs, a non-responder analysis was conducted to examine possible significant differences between responders and non-responders. Student’s unpaired t-tests and Chi-square tests were used to compare baseline characteristics. For all statistical analyses, a two-sided p-value of 5% was considered statistically significant. Statistical analyses were done using R statistical software (version 4.4.2) [40].

Sample size calculation

As this study is a secondary analysis on a healthcare registration process, a sample size calculation is not applicable in this context.

Results

Patient characteristics

A total of 734 breast cancer patients was included from the institutional database, of whom 731 patients remained after duplicates were removed. Of those patients, 152 were excluded because they did not meet the inclusion criteria. Another 27 non-responders (< 5%) did not fill out the PROMs and were excluded, leaving 552 patients for the analyses (Fig. 1).
Of the 552 included patients, 386 patients (69.9%) underwent APS, 59 patients (10.7%) an ALND, 39 patients (7.1%) APS in combination with axillary radiotherapy and 68 (12.3%) patients underwent an ALND in combination with axillary radiotherapy (Table 1).
Table 1
Baseline characteristics according to treatment group
Characteristics
APSa (n = 386)
ALND (n = 59)
APSa + Rtxa (n = 39)
ALND + Rtxa (n = 68)
p-value
Age
     
 Mean (SD)
55.5 (14.1)
50.9 (15.3)
50.0 (13.5)
48.4 (12.8)
 < 0.001
BMI (%)
     
  < 25
169 (43.8%)
30 (50.8%)
21 (53.8%)
35 (51.5%)
0.313
 25–30
161 (41.7%)
18 (30.5%)
14 (35.9%)
20 (29.4%)
 
  > 30
56 (14.5%)
11 (18.6%)
4 (10.3%)
13 (19.1%)
 
Gene mutation (%)
     
 No mutation
128 (33.2%)
33 (55.9%)
17 (43.6%)
41 (60.3%)
 < 0.001
 BRCA 1 mutation
35 (9.1%)
0 (0%)
3 (7.7%)
2 (2.9%)
 
 BRCA 2 mutation
20 (5.2%)
3 (5.1%)
0 (0%)
4 (5.9%)
 
 Other gene mutation
8 (2.1%)
2 (3.4%)
0 (0%)
1 (1.5%)
 
 Unknown
195 (50.5%)
21 (35.6%)
19 (48.7%)
20 (29.4%)
 
Bilateral cancer (%)
     
 Yes
15 (3.9%)
8 (13.6%)
0 (0%)
4 (5.9%)
0.006
 No
371 (96.1%)
51 (86.4%)
39 (100%)
64 (94.1%)
 
Surgery (%)
     
 Mastectomy
77 (19.9%)
31 (52.5%)
8 (20.5%)
45 (66.2%)
 < 0.001
 BCSa
211 (54.7%)
21 (35.6%)
27 (69.2%)
19 (27.9%)
 
 Mastectomy + reconstruction
98 (25.4%)
7 (11.9%)
4 (10.3%)
4 (5.9%)
 
Receptor (%)
     
 Triple negative
57 (14.8%)
4 (6.8%)
7 (17.9%)
17 (25.0%)
 < 0.001
 HER2 positiveb
28 (7.3%)
9 (15.3%)
4 (10.3%)
17 (25.0%)
 
 HRa positive & HER2 negative
258 (66.8%)
46 (78.0%)
28 (71.8%)
34 (50.0%)
 
 Unknown
43 (11.1%)
0 (0%)
0 (0%)
0 (0%)
 
T-stage (%)
     
 pT0
24 (6.2%)
6 (10.2%)
6 (15.4%)
17 (25.0%)
 < 0.001
 pT1
242 (62.7%)
27 (45.8%)
24 (61.5%)
18 (26.5%)
 
 pT2
69 (17.9%)
19 (32.2%)
9 (23.1%)
13 (19.1%)
 
 pT3
3 (0.8%)
5 (8.5%)
0 (0%)
9 (13.2%)
 
 pT4
0 (0%)
0 (0%)
0 (0%)
2 (2.9%)
 
 pTis
48 (12.4%)
2 (3.4%)
0 (0%)
9 (13.2%)
 
N-stage (%)
     
 pN0
378 (97.9%)
13 (22.0%)
6 (15.4%)
25 (36.8%)
 < 0.001
 pN1
8 (2.1%)
45 (76.3%)
33 (84.6%)
17 (25.0%)
 
 pN2
0 (0%)
1 (1.7%)
0 (0%)
19 (27.9%)
 
 pN3
0 (0%)
0 (0%)
0 (0%)
7 (10.3%)
 
Neoadjuvant CTxa (%)
    
 No
328 (85.0%)
32 (54.2%)
20 (51.3%)
17 (25.0%)
 < 0.001
 Yes
58 (15.0%)
27 (45.8%)
19 (48.7%)
51 (75.0%)
 
Adjuvant CTxa (%)
    
 No
324 (83.9%)
36 (61.0%)
23 (59.0%)
33 (48.5%)
 < 0.001
 Yes
62 (16.1%)
23 (39.0%)
16 (41.0%)
35 (51.5%)
 
Neoadjuvant HTxa (%)
    
 No
373 (96.6%)
54 (91.5%)
39 (100%)
65 (95.6%)
0.149
 Yes
13 (3.4%)
5 (8.5%)
0 (0%)
3 (4.4%)
 
Adjuvant HTxa (%)
     
 No
219 (56.7%)
11 (18.6%)
9 (23.1%)
25 (36.8%)
 < 0.001
 Yes
167 (43.3%)
48 (81.4%)
30 (76.9%)
43 (63.2%)
 
Breast/ chest Rtxa (%)
    
 No
174 (45.1%)
21 (35.6%)
0 (0%)
0 (0%)
 < 0.001
 Yes
209 (54.1%)
35 (59.3%)
37 (94.9%)
50 (73.5%)
 
 Yes & parasternal
3 (0.8%)
3 (5.1%)
2 (5.1%)
18 (26.5%)
 
Rtxa boost (%)
     
 No
302 (78.2%)
41 (69.5%)
23 (59.0%)
49 (72.1%)
0.032
 Yes
84 (21.8%)
18 (30.5%)
16 (41.0%)
19 (27.9%)
 
Bold values indicate the p-value < 0.05
aAPS, axilla preserving surgery; Rtx, radiotherapy; BCS, breast conserving surgery; HR, hormone receptor; CTx, chemo(immune)therapy; HTx, hormonal therapy
bHR + /HR- combined
Most baseline characteristics, except for BMI and neo-adjuvant hormonal therapy, demonstrated significant differences between treatment groups. Patients who underwent ALND were more likely to have undergone a mastectomy, had a higher tumour stage, and received systemic therapy more frequently (Table 1).

Non-responder analysis

The number of non-responders in the study was 27 (< 5%). The non-responder analysis showed similar distributions between responders and non-responders for almost all variables, except for BMI category. Non-responders had a higher BMI (BMI > 30) compared to responders (p = 0.008). The full non-responder analysis can be found in Apendix 1.

HRQoL scores according to axillary treatment

There were no statistically significant differences in sexual wellbeing scores between treatment groups (Table 2). However, physical wellbeing scores differed significantly between treatment groups at 6 months postoperatively (p < 0.001, Table 2). Additionally, the psychosocial wellbeing domain also showed significant differences between treatment groups at 6 months (p = 0.010) and 12 months postoperatively (p = 0.012, Table 2). Furthermore, at 6- and 12-months postoperatively arm symptoms differed significantly between treatment groups (both p < 0.001, Table 2). HRQoL scores of other domains of the BREAST-Q and EORTC QLQ-BR23 can be found in Appendix 2.
Table 2
BREAST-Q and EORTC QLQ-BR23 scores on all follow-up times according to treatment group
HRQoL
APS
ALND
APS + Rtx
ALND + Rtx
p-value
(n = 386)
(n = 59)
(n = 39)
(N = 68)
BREAST-Q: Physical wellbeing at baseline
    
 Mean (SD)
80.9 (15.2)
78.1 (14.8)
82.1 (15.4)
78.6 (17.8)
0.520
 Missing (%)
89 (23.1%)
15 (25.4%)
7 (17.9%)
14 (20.6%)
 
BREAST-Q: Physical wellbeing at 6 months
    
 Mean (SD)
69.4 (18.1)
66.8 (24.4)
67.1 (16.3)
57.8 (18.5)
 < 0.001
 Missing (%)
99 (25.6%)
12 (20.3%)
11 (28.2%)
16 (23.5%)
 
BREAST-Q: Physical wellbeing at 12 months
    
 Mean (SD)
71.9 (20.4)
66.0 (26.7)
70.7 (21.2)
65.3 (20.6)
0.145
 Missing (%)
87 (22.5%)
9 (15.3%)
8 (20.5%)
16 (23.5%)
 
BREAST-Q: Psychosocial wellbeing at baseline
 Mean (SD)
74.2 (17.5)
70.1 (19.0)
75.2 (17.6)
72.3 (20.1)
0.510
 Missing (%)
89 (23.1%)
15 (25.4%)
7 (17.9%)
14 (20.6%)
 
BREAST-Q: Psychosocial wellbeing at 6 months
    
 Mean (SD)
69.8 (18.0)
61.9 (16.5)
63.8 (15.2)
64.0 (20.7)
0.010
 Missing (%)
170 (44.0%)
19 (32.2%)
18 (46.2%)
22 (32.4%)
 
BREAST-Q: Psychosocial wellbeing at 12 months
   
 Mean (SD)
68.9 (19.5)
61.3 (18.1)
65.1 (18.7)
62.0 (21.3)
0.012
 Missing (%)
164 (42.5%)
14 (23.7%)
15 (38.5%)
21 (30.9%)
 
BREAST-Q: Sexual wellbeing at baseline
    
 Mean (SD)
63.7 (20.9)
64.3 (23.0)
68.5 (17.4)
64.3 (21.3)
0.729
 Missing (%)
151 (39.1%)
29 (49.2%)
15 (38.5%)
22 (32.4%)
 
BREAST-Q: Sexual wellbeing at 6 months
    
 Mean (SD)
48.3 (17.8)
45.4 (17.3)
49.6 (12.3)
49.4 (15.7)
0.729
 Missing (%)
176 (45.6%)
28 (47.5%)
22 (56.4%)
32 (47.1%)
 
BREAST-Q: Sexual wellbeing at 12 months
    
 Mean (SD)
50.3 (19.6)
46.3 (18.7)
48.6 (16.4)
49.1 (21.0)
0.739
 Missing (%)
171 (44.3%)
21 (35.6%)
21 (53.8%)
30 (44.1%)
 
EORTC QLQ_BR2a 3: Arm symptoms at baseline
   
 Mean (SD)
8.65 (15.8)
7.41 (13.6)
5.05 (7.90)
8.05 (16.0)
0.844
 Missing (%)
84 (21.8%)
14 (23.7%)
6 (15.4%)
10 (14.7%)
 
EORTC QLQ_BR23a: Arm symptoms at 6 months
   
 Mean (SD)
13.2 (17.4)
19.0 (22.3)
22.6 (18.5)
26.6 (20.1)
 < 0.001
 Missing (%)
88 (22.8%)
11 (18.6%)
8 (20.5%)
12 (17.6%)
 
EORTC QLQ_BR23a: Arm symptoms at 12 months
   
 Mean (SD)
12.8 (17.2)
19.4 (21.6)
22.2 (18.9)
27.3 (20.7)
 < 0.001
 Missing (%)
73 (18.9%)
8 (13.6%)
7 (17.9%)
15 (22.1%)
 
Bold values indicate the p-value < 0.05
Symptom-oriented scales; higher scores represent greater symptom severity
aFunctional scales; higher scores represent a better level of functioning

Effect of axillary treatments on HRQoL over time

HRQoL measured at baseline did not significantly differ between the more extensive axillary treatment groups (APS with axillary radiotherapy, ALND and ALND with axillary radiotherapy) compared to the APS group (reference) after adjusting for all variables (Table 3). For patients who underwent APS, physical wellbeing, psychosocial wellbeing, and sexual wellbeing decreased, and arm symptoms increased significantly at 6- and 12 months postoperatively (p < 0.05, Table 3, Fig. 2).
Table 3
Mixed model regression analysis
 
Physical wellbeing
Psychosocial wellbeing
Sexual wellbeing
Arm symptoms
Estimates
p-value
Estimates
p-value
Estimates
p-value
Estimates
p-value
APS: baseline (intercept)
66.29
 < 0.001
61.60
 < 0.001
67.30
 < 0.001
18.78
 < 0.001
APS: 6 months postoperatively
– 11.50
 < 0.001
– 3.32
0.010
– 15.68
 < 0.001
4.62
 < 0.001
APS: 12 months postoperatively
– 8.88
 < 0.001
– 3.69
0.004
– 14.09
 < 0.001
3.64
0.002
APS + Rtx
3.58
0.315
0.81
0.818
4.30
0.316
– 3.98
0.230
ALND
0.42
0.892
– 1.99
0.514
– 1.23
0.744
– 1.48
0.610
ALND + Rtx
4.37
0.193
2.92
0.380
2.44
0.526
– 1.98
0.516
APS + Rtx: delta 1a
– 2.24
0.541
– 6.14
0.142
– 4.62
0.356
12.71
0.001
APS + Rtx: delta 2b
– 1.66
0.644
– 4.20
0.300
– 6.31
0.199
13.74
 < 0.001
ALND: delta 1a
– 1.18
0.703
– 3.40
0.313
– 1.42
0.734
6.85
0.030
ALND: delta 2b
– 3.56
0.239
– 3.53
0.276
– 1.15
0.773
7.66
0.014
ALND + Rtx: delta 1a
– 10.64
 < 0.001
– 5.10
0.104
0.01
0.998
13.93
 < 0.001
ALND + Rtx: delta 2b
– 6.11
0.035
– 6.81
0.028
– 1.05
0.774
16.14
 < 0.001
Bold values indicate the p-value < 0.05
aChange in HRQoL from baseline to 6 months postoperatively
bChange in HRQoL from baseline to 12 months postoperatively
For patients who received APS with axillary radiotherapy, delta 1 (i.e., the difference between baseline and 6 months postoperatively) and delta 2 (i.e., the difference between baseline and 12 months postoperatively) of the arm symptoms domain increased significantly with 12.71 and 13.74 points respectively compared to patients undergoing APS alone (p < 0.05, Table 3, Fig. 2d). Similarly, for patients who underwent ALND, delta 1 (6.85) and delta 2 (7.66) of the arm symptoms domain increased significantly compared to patients undergoing APS alone (p < 0.05, Table 3, Fig. 2d). This indicates that arm symptoms increased significantly over time for patients undergoing APS with axillary radiotherapy and for patients undergoing ALND compared to patients undergoing APS alone. Furthermore, the increase in arm symptoms is greater for patients receiving APS with axillary radiotherapy than for patients receiving ALND. There were no significant differences in other BREAST-Q domains (Table 3, Fig. 2).
For patients who received ALND combined with axillary radiotherapy, negative delta 1 of the physical wellbeing domain increased with 10.64 significantly compared to patients undergoing APS (p < 0.001, Table 3, Fig. 2a). The corresponding negative delta 2 increased significantly with 6.11 points (p = 0.035, Table 3, Fig. 2a). Moreover, negative delta 2 of the psychosocial wellbeing domain increased with 6.81 points significantly for patients receiving ALND with axillary radiotherapy compared to patients undergoing APS (p = 0.028, Table 3, Fig. 2b). This indicates that the negative effect of axillary treatment on physical and psychosocial wellbeing increased significantly for patients undergoing ALND with axillary radiotherapy compared to patients undergoing APS alone. In addition, delta 1 (13.93) and delta 2 (16.14) of the arm symptoms domain increased significantly compared to patients undergoing APS (p < 0.001, Table 3, Fig. 2d). Sexual wellbeing did not significantly differ compared to APS (Table 3, Fig. 2c).
The effect plots demonstrate a decline in HRQoL from baseline to 6 months postoperatively. However, between 6 and 12 months postoperatively, HRQoL tends to stabilize again. The red colour represents the APS group, green the ALND group, blue the APS with axillary radiotherapy group and purple the ALND with axillary radiotherapy group (Fig. 2).

Discussion

This longitudinal cohort study of women with breast cancer aimed to investigate the association between different axillary treatments and HRQoL measured with the BREAST-Q and the EORTC QLQ-BR23 in the first year after surgery. The results demonstrated that all axillary treatments included in this study led to an increase in arm symptoms. Moreover, APS with axillary radiotherapy and ALND with and without axillary radiotherapy led to a significant greater increase in arm symptoms compared to APS alone. In addition, the most extensive axillary treatment consisting of ALND combined with axillary radiotherapy had also a clinically significant effect on physical and psychosocial wellbeing. This indicates that ALND with axillary radiotherapy affects not only arm morbidity, but also more general HRQoL domains. This may be due to the potential physical and emotional side effects associated with axillary treatments such as pain, emotional distress, anxiety, and uncertainty about the long-term effects of the treatment [41, 42]. No significant difference in sexual wellbeing were found between the different axillary treatment groups.
The results of this study are consistent with some previous studies that have demonstrated benefits of SLNB compared to ALND [26, 31, 32, 4347]. For instance, Belmonte et al. reported less arm morbidity in patients receiving SLNB compared to ALND which supports the use of SLNB. However, they did not find a significant difference in general well-being measured with the disease-specific FACT-B + 4 and the generic short form 36 health survey between ALND and SLNB [31]. Similarly, Peintiger et al. showed that SLNB is associated with significant less arm and shoulder morbidity compared to ALND. In addition, the study demonstrated significant higher levels of pain on the symptom scale of the EORTC QLQ-C30 in the ALND group [32]. Moreover, the prospective cohort study of Dabakuyo et al. showed that patients undergoing SLNB score better on both the global health status from the EORTC QLQ-C30, and the arm symptoms from the EORTC QLQ-BR23 compared to patients undergoing ALND [26]. A more recent study of Appelgren et al. also demonstrated that arm morbidity is significantly worse in patients receiving ALND compared to SLNB and highlights the importance of de-escalation of axillary surgery [47]. In contrast, Kootstra et al. did not demonstrate any association between SLNB and a better HRQoL measured with the EORTC QLQ-C30 compared to ALND [30]. Several randomized controlled trials have been conducted and all reported better HRQoL with fewer postoperative complications in patients undergoing SLNB compared to patients undergoing ALND [4346]. The discrepancies between previous HRQoL studies can be explained by differences in sample size and by the fact that different validated questionnaires were used to measure HRQoL.
The AMAROS trial demonstrated that axillary radiotherapy may be a feasible alternative to ALND in cN + breast cancer patients, with comparable axillary control and less morbidity. However, the AMAROS did not demonstrate significant differences in HRQoL measured with the pain domain of the EORTC QLQ-C30 and the arm symptoms and body image domain of the EORTC QLQ-BR23 [17]. An interesting finding of the current study is that arm symptoms increased with 12.71 (delta 1) and 13.74 (delta 2) for patients undergoing APS with axillary radiotherapy compared to APS alone, while arm symptoms increased with 6.85 (delta 1) and 7.66 (delta 2) for patients undergoing ALND compared to APS alone. This suggests that patients who undergo APS with axillary radiotherapy may experience a greater increase in arm symptoms than patients undergoing an ALND. However, it is important to note that the comparison is not directly between APS with axillary radiotherapy and ALND. Therefore, more research is necessary to determine whether the difference in arm symptoms is statistically significant between these two axillary treatments.

Strengths and limitations

One of the main strengths of this study is its relatively large sample size and the availability of a wide range of patient, treatment, and tumour characteristics that were collected from medical records and used in the regression analysis. Furthermore, there are no previous studies that have compared HRQoL as measured by the BREAST-Q or EORTC QLQ-BR23 between the four different axillary treatment groups (including axillary radiotherapy). This makes this research valuable for future comparisons. Another major strength is the longitudinal design of the study. Baseline and postoperative HRQoL outcomes were included, which allowed for the observation of the effect of different axillary treatments on HRQoL over time while correcting for clinically relevant variables. Additionally, by including baseline HRQoL measurements, it was possible to account for any potential missing patient history.
An important limitation is the fact that patients were not randomly assigned to a treatment group since there are specific treatment protocols for each breast cancer stage [11]. This may lead to confounding by indication. Moreover, most of the baseline characteristics differed significantly between treatment groups. By including various patient and treatment characteristics in the mixed models, it was tried to correct for as many confounders as possible. Especially the correction for neo-adjuvant chemotherapy was important, as patients undergoing a RISAS procedure always undergo neoadjuvant chemotherapy in contrast to patients undergoing an SLND and because chemotherapy affects HRQoL [48]. There may be residual confounding since it is not possible to control for unknown confounders. Furthermore, there was no data on for example socioeconomic status, educational level, and coping strategies, which can also have an impact on HRQoL [49, 50]. Additionally, the non-responder analysis revealed similar distribution patterns of baseline characteristics among the treatment groups, except for BMI. Non-responders tended to have a higher BMI compared to responders. Although BMI is linked to HRQoL, its influence on the overall outcomes is not expected to be significant since the non-responder subgroup accounts for less than 5% of the total sample size [51]. Lastly, there was a relatively high level of missingness per timepoint. This may be caused by patients switching hospitals or lacking motivation to complete PROMs. In addition, the sexual wellbeing domain of the BREAST-Q was not mandatory, resulting in even more missingness for this specific domain. The substantial missingness of data, especially in the BREAST-Q domains, may impact the validity of the results and may introduce bias. Therefore, it is recommended to validate the current results in other breast cancer cohorts.

Future perspectives

In the future, it would be beneficial to conduct a validation study utilizing a multicentre database such as the Dutch MINIMAX study to compare HRQoL among patients receiving APS with axillary radiotherapy and patients receiving ALND alone [52]. Those results will be of great value to both patients and healthcare providers especially when there is a choice between treatments with comparable oncological outcome. Moreover, it would be interesting to examine HRQoL at intervals of 2- or 5-years postoperatively to determine if there are any changes in HRQoL between treatment groups. Radiation fibrosis should then be included in the analysis as it typically occurs 12 months after treatment and significantly impacts HRQoL [5355]. Additionally, the use of more fixed HRQoL outcomes defined in core outcome sets is recommended to make more meaningful comparisons in future studies.
The findings of this study will be informative for healthcare providers and breast cancer patients in the future as they will enhance expectation management and shared decision making. In addition, this study offers patients perspective and demonstrates that the decline in their HRQoL may stabilize again after six months. This has the potential to motivate patients to complete PROMs, which may result in more HRQoL data for future research. Furthermore, this study provides a foundation for further research on the impact of axillary treatment on HRQoL, as axillary treatment is an emerging area of research [16, 5660]. Once the oncological safety of less invasive and less extensive axillary treatments has been evaluated and protocols may be adjusted, this study can be used to develop predictive models and decision-making tools for patients.

Conclusion

Physical and psychosocial wellbeing decreased significantly in patients receiving ALND with axillary radiotherapy compared to patients receiving APS alone. Patients undergoing APS without axillary radiotherapy had significantly fewer arm symptoms compared to patients receiving APS with axillary radiotherapy and patients receiving ALND with or without axillary radiotherapy. Shared decision making and expectation management could be strengthened by discussing arm symptoms per axillary treatment with the patient.

Acknowledgements

The authors wish to thank the Netherlands Institute for Health Sciences (NIHES) for supporting this research project.

Declarations

Conflict of interest

The authors have no relevant financial or non-financial interests to disclose.

Ethical approval

This is an observational study. The Erasmus MC Research Ethics Committee has confirmed that no ethical approval is required.
The Institutional Review Board was consulted and concluded that informed consent was not needed since the value-based healthcare-strategy is considered standard of care in Erasmus MC.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://​creativecommons.​org/​licenses/​by/​4.​0/​.

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Metagegevens
Titel
Health-related quality of life (HRQoL) after different axillary treatments in women with breast cancer: a 1-year longitudinal cohort study
Auteurs
N. J. M. C. Vrancken Peeters
Z. L. R. Kaplan
M. E. Clarijs
M. A. M. Mureau
C. Verhoef
T. van Dalen
O. Husson
L. B. Koppert
Publicatiedatum
27-10-2023
Uitgeverij
Springer International Publishing
Gepubliceerd in
Quality of Life Research / Uitgave 2/2024
Print ISSN: 0962-9343
Elektronisch ISSN: 1573-2649
DOI
https://doi.org/10.1007/s11136-023-03538-3