ASSESSMENT OF SURGICAL MANAGEMENT OF FEMALE BREAST CANCER PATIENTS AFTER NEOADJUVANT SYSTEMIC THERAPY FOR INVASIVE DUCTAL VERSUS INVASIVE LOBULAR CARCINOMA (T3 STAGE)

Document Type : Original Article

Authors

1 Departments of General Surgery, Faculty of Medicine, Al-Azhar University, Cairo, Egypt

2 Departments of Clinical Oncology & Nuclear Medicine, Faculty of Medicine, Al-Azhar University, Cairo, Egypt

3 Departments of Radiodiagnosis, Faculty of Medicine, Al-Azhar University, Cairo, Egypt

Abstract

Background: In the treatment of locally advanced breast cancer, neoadjuvant chemotherapy approach has several objectives, including downsizing of irresectable tumor into operable disease.
     ILC is known to be less responsive to NAC. The reported proportions of ILC patients with a pathologic complete response (pCR) range from 1 to 3 % compared with 9 to 15 % for IDC patients
Objectives: To assess surgical decision after using neoadjuvant systemic therapy for locally advanced breast cancer patients with invasive ductal carcinoma (IDC) versus whom with invasive lobular carcinoma (ILC). To determine the impact of neoadjuvant chemotherapy (NAC) on different pathological types of locally advanced breast cancer cases.
Patients and Methods: This retrospective study included 50 patients in the period from Jun 2018 to Jun 2019 who were diagnosed as invasive ductal and invasive lobular Carcinoma classified into two equal groups. Each group had received neoadjuvant systemic therapy, at Department of Clinical Oncology and Nuclear Medicine, while surgical treatment, in form of modified radical mastectomy (MRM) or breast conserving surgery (BCS), was done between June 2019 and Mar 2020, at the Surgical Oncology Department in Al-Azhar university hospitals.
Results: In our study, we observed a reduction in T stage after NAC in 6 cases (24%) of ILC patients compared to clinical down staging in 20 cases (80%) of IDC group.
Conclusion: ILC patients were less responsive to neoadjuvant chemotherapy compared with IDC patients. BCS is less frequently achieved after NAC in patients with lobular histology compared with ductal histology.

Keywords


ASSESSMENT OF SURGICAL MANAGEMENT OF FEMALE BREAST CANCER PATIENTS AFTER NEOADJUVANT SYSTEMIC THERAPY FOR INVASIVE DUCTAL VERSUS INVASIVE LOBULAR CARCINOMA (T3 STAGE)

By

El-Said Ahmed Mahmoud Douma, Saied Hosny Bendary, Ahmed Yosry El-Agamawi*, Amr Mahmoud Zayed**, Nader Mohamed Abd El-Hamid

Departments of General Surgery, Clinical Oncology & Nuclear Medicine* and Radiodiagnosis**, Faculty of Medicine, Al-Azhar University

E-mail: elsaid.a.douma@gmail.com

ABSTRACT

Background: In the treatment of locally advanced breast cancer, neoadjuvant chemotherapy approach has several objectives, including downsizing of irresectable tumor into operable disease.

     ILC is known to be less responsive to NAC. The reported proportions of ILC patients with a pathologic complete response (pCR) range from 1 to 3 % compared with 9 to 15 % for IDC patients

Objectives: To assess surgical decision after using neoadjuvant systemic therapy for locally advanced breast cancer patients with invasive ductal carcinoma (IDC) versus whom with invasive lobular carcinoma (ILC). To determine the impact of neoadjuvant chemotherapy (NAC) on different pathological types of locally advanced breast cancer cases.

Patients and Methods: This retrospective study included 50 patients in the period from Jun 2018 to Jun 2019 who were diagnosed as invasive ductal and invasive lobular Carcinoma classified into two equal groups. Each group had received neoadjuvant systemic therapy, at Department of Clinical Oncology and Nuclear Medicine, while surgical treatment, in form of modified radical mastectomy (MRM) or breast conserving surgery (BCS), was done between June 2019 and Mar 2020, at the Surgical Oncology Department in Al-Azhar university hospitals.

Results: In our study, we observed a reduction in T stage after NAC in 6 cases (24%) of ILC patients compared to clinical down staging in 20 cases (80%) of IDC group.

Conclusion: ILC patients were less responsive to neoadjuvant chemotherapy compared with IDC patients. BCS is less frequently achieved after NAC in patients with lobular histology compared with ductal histology.

Keywords: Locally advanced breast cancer, neoadjuvant chemotherapy, surgical management, invasive duct carcinoma, invasive lobular carcinoma.

 

 

INTRODUCTION

     Worldwide breast cancer is the most common invasive cancer in women. In 2012, it comprised 25.2% of cancers diagnosed in women, (Kwon and Seungjun, 2016).

     Neoadjuvant chemotherapy (NAC) is considered the standard treatment for the management of locally advanced breast cancer and is increasingly being used for women with earlier stage disease (Aragon-Ching et al., 2018). The neoadjuvant chemotherapy approach has several objectives, including downsizing of irresectable locally advanced breast cancer into operable disease to increase the possibility of conservative breast surgery (CBS) (Henderson et al., 2017).

     Furthermore, it allows in vivo monitoring of the tumor’s chemosensitivity. And also gives the opportunity for downstaging of disease in the axilla, obviating the need for axillary treatment in some patients (Chehade et al., 2016).

     ILC is known to be less responsive to NAC. The reported proportions of ILC patients with a pathologic complete response (pCR) range from 1 to 3 % compared with 9 to 15 % for IDC patients (Loibl et al., 2014).

     Endocrine therapy alone (aromatase inhibitor or tamoxifen) may be considered for patients with hormone-receptor positive disease as a preoperative therapy, (Huober et al., 2012).

     Invasive lobular carcinoma (ILC) is the second most common subtype of invasive breast cancer (BC), accounting for approximately 5 –15% of all invasive tumors (Michaut et al., 2016).

     ILC offers an exclusive clinical, radiological and pathological appearance compared to invasive ductal carcinoma (IDC). For example, ILC is always an estrogen-receptor positive tumor with a high frequency of multicentricity and laterality. It is more commonly associated with older age, larger diameter and well-differentiated morphology (Veys et al., 2015).

     Furthermore, in a small study including patients with ILC, NAC did not appear to increase the likelihood of breast conservation. Also, when treated with NAC, patients with ILC have been more likely to have positive surgical margins than patients with IDC (Marmor et al., 2017).

     This study aimed to compare the impact of neoadjuvant systemic therapy on the patients with invasive ductal versus invasive lobular breast cancer in form of difference in response and surgical management.

PATIENTS AND METHODS

     This prospective study included fifty female patients, ranging from 20-60 years old, classified into two equal groups with proven histopathology of locally advanced invasive lobular or invasive ductal carcinoma of the breast.  All patients had completed her neoadjuvant chemotherapy with Anthracyclin-based regimen, with or without hormonal therapy according to receptors status, at the Department of Clinical Oncology and Nuclear Medicine, while surgical treatment, in form of modified radical mastectomy (MRM) or breast conserving surgery (BCS), was done between June 2019 and Mar 2020, at the Surgical Oncology Department in Al-Azhar university hospitals.

     Patients were excluded if they had any of the following criteria. Patients with early stage of breast cancer, metastatic breast cancer, not in the period from June 2019 to Mar 2020 and medically unfit for surgery.

     After NAC, each patient was subjected to comprehensive medical history and careful clinical examination for assessment of clinical response to NAC and the patient’s ability to perform surgery. Laboratory and radiological investigations for preparation for surgery, excluding metastasis and assessment of breast lesion response to neo-adjuvant treatment. All patients had been subjected to surgical treatment in the form of modified radical mastectomy or conservative breast surgery according to the results of NAC.

     The patients were informed of the study and signed a consent term of their participation, after explanation of possible complications, ethical and legal implications. They underwent modified Radical Mastectomy or conservative breast surgery.

     Postoperative clinical follow-up was done at three months intervals, and included local examination of chest wall, both breasts and axilla. Tumor marker (CA 15-3), mammograms, and ultrasonography were done according to our protocol.

Statistical Analysis:

     The collected data was revised, coded, tabulated and introduced to a PC using Statistical package for Social Science (IBM Corp. Released 2011. IBM SPSS Statistics for Windows, Version 20.0. Armonk, NY: IBM Corp). Data was presented and suitable analysis was done according to the type of data obtained for each parameter.

•   Description of quantitative variables as mean, SD and range.

•   Description of qualitative variables as number and percentage.

•   Chi-square test was used to compare qualitative variables.

•   Two sample t-tests were used to compare quantitative variables between independent groups in parametric data.

•   Paired t-test was used to assess the statistical significance of the difference between two means measured twice for the same study group.

•   McNemar test was used assess the statistical significance of the difference between a qualitative variable measured twice for the same study group.

•   P- value  was considered Signihceut when P-value < 0.05.

 


 

RESULTS

 

 

     According to the patient's age and chronic diseases at time of presentation, (estimated median age was 50.52 ± 6.22 years for IDC and 51.48 ± 4.04 for ILC) There is no significant difference between the studied groups. While there is significant deference between the two groups as regard BMI, the patients of ILC is more likely to be over weigh and obese than IDC patients (Table 1).


 

 

 

 

 

Table (1):   Demographic data of all patients

Groups

Parameters

IDC group

ILC group

P-value

No. = 25

No. = 25

Age (year)

Mean±SD

50.52 ± 6.22

51.48 ± 4.04

< 0.521

Range

38 – 60

43 – 58

BMI

Mean±SD

26.65 ± 2.30

28.02 ± 2.46

< 0.049

Range

24.07 – 33.06

23.94 – 32.32

HTN

No

10 (40.0%)

13 (52.0%)

< 0.395

Yes

15 (60.0%)

12 (48.0%)

DM

No

14 (56.0%)

18 (72.0%)

< 0.239

Yes

11 (44.0%)

7 (28.0%)

IHD

No

19 (76.0%)

18 (72.0%)

< 0.747

Yes

6 (24.0%)

7 (28.0%)

 

 

     All patients conducted to our study selected in T3 stage (LABC) tumor, size more than 5 cm, and all patients have positive axillary LN (N1) by clinical examination and ultrasonographic investigation. No skin manifestation or metastatic lesion (Table 2).

 

 

Table (2):   Tumor stage of both groups at time of presentation before NAC

Groups

Parameters

IDC group

ILC group

No.

%

No.

%

T

T3

25

100.0%

25

100.0%

T2

0

0.0%

0

0.0%

N

N0

0

0.0%

0

0.0%

N1

25

100.0%

25

100.0%

M

M0

25

100.0%

25

100.0%

 

 

     All pre-therapeutic core needle biopsies that were confirmed to show invasive breast carcinoma were automatically subjected for automated immunostaining assessment for estrogen receptor (ER), progesterone receptor (PR) and HER-2/neu. Patients with ILC were more likely to have positive ER in (80%) and positive PR in (76%) of cases, compared to patients with IDC home have positive ER in (40%) and positive PR in (36%) of cases which highly significant. Also, patients with ILC were more likely to have HER2 negative tumor in (76%) of cases rather than HER2 positive tumors (24%), while patients with IDC showed more HER2 positive tumor (64%) and less HER2 negative tumor (36%), which statistically significance (p value < 0.005) (Table 3).

 

 

 

 

 

 

 

 

 

Table (3):   Comparison between the groups regarding the status of hormonal receptors and Her-2/neu

Groups

Parameters

IDC group

ILC group

P-value

No.

%

No.

%

ER

Negative

15

60.0%

5

20.0%

< 0.004

Positive

10

40.0%

20

80.0%

PR

Negative

16

64.0%

6

24.0%

< 0.005

Positive

9

36.0%

19

76.0%

Her2neu

Negative

9

36.0%

19

76.0%

< 0.005

Positive

16

64.0%

6

24.0%

 

 

     After NAC, patients of group A showed remarkable response by clinical examination and ultrasonographic investigation in (80%) which became T2 instead of T3 before NAC. The tumors in group B experienced clinical downstaging only in (24%). This result was statistically significant. As regards to axillary response to NAC, only (56%) cases of group A (IDC) became N0, compared to (40%) from cases of group B (ILC), which was statistically nonsignificant (Table 4).

 

 

Table (4):   Comparison of two groups regarding clinical response to NAC

Groups

Parameters

IDC group

ILC group

P-value

No.

%

No.

%

T

T3

5

20.0%

19

76.0%

< 0.001

T2

20

80.0%

6

24.0%

N

N0

14

56.0%

10

40.0%

< 0.258

N1

11

44.0%

15

60.0%

M

M0

25

100.0%

25

100.0%

NA

 

 

     Among group A, (IDC) downstaging achieved in (80%) of cases and conservative surgery achieved in 17 cases (68%). In the group B, (ILC) only, 6 cases (24%) experienced downstaging and conservative surgery performed in these 6 cases, which was statistically significant (Table 5).

 

 

Table (5):   Comparison between the two groups regarding downstaging and type of surgery performed

Groups

Parameters

IDC group

ILC group

P-value

No.

%

No.

%

Down Staging

No

5

20.0%

19

76.0%

< 0.001

Yes

20

80.0%

6

24.0%

Type of Surgery

MRM

8

32.0%

19

76.0%

< 0.002

CBS

17

68.0%

6

24.0%

Local Recurrence

No recurrence

25

100.0%

25

100.0%

NA

 

 

     In the ILC patients, MRM was the primary surgical intervention done in 19 cases (76%) while CBS done in 6 cases (24%). In the IDC patients, the BCS was the main surgical procedure 17 cases (68%) and MRM done for 8 cases (32%).

 

 

 

 

DISCUSSION

     The Neoadjuvant chemotherapy (NAC) is the first line of treatment for patients with locally advanced breast cancer. The objectives, including downsizing of irresectable locally advanced breast cancer into operable disease. Furthermore, it allows in vivo monitoring of the tumor’s chemo sensitivity and also gives the opportunity for down staging of disease in the axilla, obviating the need for axillary treatment in some patients. This study was conducted to determine the impact of neoadjuvant chemotherapy (NAC) on different pathological types of locally advanced breast cancer cases. We compared the effects of NAC on the surgical decision for two similar groups of patients with locally advanced invasive lobular carcinoma (ILC) and locally advanced invasive ductal carcinoma (IDC).

     In our study, we observed a reduction in T stage after NAC in (24%) of ILC patients compared to clinical down staging in (80%) of IDC group. Our results were near to previous study of Nagao et al, whom observed reduction in T stage after NAC in 31.8 % of the patients with ILC and 75 % of the patients with IDC. They found that down staging was more frequently observed in the patients who presented with larger size and hormone receptor-negative tumors in both histologic subtypes (Nagao et al., 2012).

     There was no impact of breast cancer histology on the use of breast conservation and the risk of positive resection margins and interventions is well established. Since the introduction of NAC for locally advanced tumors, BCS can be achieved more. However, the surgical benefits after NAC for patients with locally advanced breast cancer of lobular histology compared with ductal histology remain unclear (Truin et al., 2016).

     Our study showed a remarkable low percentage of patients undergoing BCS after NAC for ILC group (24 %) compared to 68 % BCS for IDC group. These BCS rates were lower than the data in literature as the study of (Cain et al. 2017), which pooled nine randomized trials that calculated a BCS rate was (59.1 %) for ILC patients and (71.1 %) for IDC patients after NAC (Salati et al., 2018).

     In another meta-analysis of Petrelli and Barni (2013) on the response after NAC for locally advanced breast cancer, and concluded that the BCS rates were 35.4 % for ILC and 54.8 % for IDC. This was nearly similar to our results.

     The differences in percentage between BCS results after NAC for different histology is due to that patients with ILC present with significantly larger tumors at the time of diagnosis, and more often show multifocal or multicentric disease. The diffuse infiltrative growth pattern of ILC poses a difficulty in determining the extent of the tumor. As a result of these characteristics, higher rates of positive surgical resection margins are observed in the primary surgical procedure in ILC compared with IDC. This results in higher rates of re-resection and completion mastectomy for patients with lobular histology (Truin et al., 2016).

     The definition of a pathological complete response (pCR) was necrosis and the disappearance of all invasive cells in post-operative specimen and this observed only in cases with infiltrating ductal carcinoma (Gebreamlak et al., 2013). In our study, there was no cases show pCR. Patients with IDC are more likely to experience a pCR than patients with ILC, especially when their tumors are ER-, PR- negative and HER2-neu positive (Barquet-Muñoz et al., 2015). The reported proportions of ILC patients with a pathologic complete response range from 1 to 3 % compared with 9 to 15 % for IDC patients (Lobbes et al., 2013).

CONCLUSION

     BCS were less frequently achieved after NAC in patients with lobular histology compared with ductal histology.

Conflicts of Interest: The authors declare that there were not any conflicts of interest regarding the publication of this paper.

Acknowledgment: The authors would like to thank all staff members, residents, nurses and ancillary staff of the Surgical Oncology Department, Al Azhar University Hospitals and El Matarya Teching Hospital for their precious help. Prof, Yasser Ali from Al Azhar University Hospitals, Egypt, for his great help preparing the manuscript, Finally, we would like to thank our kind patients for their helpful participance.

REFERENCES

  1. Aragon-Ching JB, Werntz RP, Zietman AL, Werntz RP and Steinberg GD (2018): Multidisciplinary Management of Muscle-Invasive Bladder Cancer Current Challenges and Future Directions. American Society of Clinical Oncology Educational Book, 38(12): 307-318.‏
  2. Barquet-Muñoz, SA, Villarreal-Colin SP, Herrera-Montalvo LA, Soto-Reyes E, Pérez-Plasencia C, Coronel-Martínez J and De León DC (2015): Metaplastic breast cancer: a comparison between the most common histologies with poor immunohistochemistry factors. BMC cancer, 15(1): 75-84.
  3. Chehade, HEH, Headon H, Kasem A and Mokbel K (2016): Refining the performance of sentinel lymph node biopsy post-neoadjuvant chemotherapy in patients with pathologically proven pre-treatment node-positive breast cancer: an update for clinical practice. Anticancer research, 36(4): 1461-1471.
  4. Gebreamlak E, MK Tse G and Niu Y (2013): Progress in evaluation of pathologic response to neoadjuvant chemotherapy of breast cancer. Anti-Cancer Agents in Medicinal Chemistry (Formerly Current Medicinal Chemistry-Anti-Cancer Agents), 13(2): 222-226.
  5. Henderson JR, Kandola S, Hignett SP, Teasdale RL, Topps AR, Pennick M and Kirwan CC (2017): Infection Prophylaxis for Breast Implant Surgery: Could We Do Better? Eplasty, 17.
  6. Huober J, Fasching PA, Barsoum M, Petruzelka L, Wallwiener D, Thomssen C and Kubista E (2012): Higher efficacy of letrozole in combination with trastuzumab compared to letrozole monotherapy as first-line treatment in patients with HER2-positive, hormone-receptor-positive metastatic breast cancer–results of the eLEcTRA trial. The Breast, 21(1): 27-33.
  7. Kwon S and Seungjun L (2016): Recent advances in microwave imaging for breast cancer detection. International Journal of Biomedical Imaging, 8(13): 1-26.
  8. Lobbes MB I, Prevos R, Smidt M, Tjan-Heijnen VCG, Van Goethem M, Schipper R and Wildberger, J. E. (2013): The role of magnetic resonance imaging in assessing residual disease and pathologic complete response in breast cancer patients receiving neoadjuvant chemotherapy: a systematic review. Insights into imaging, 4(2): 163-175.
  9. Loibl S, Volz C, Mau C, Blohmer JU, Costa S D, Eidtmann H, Kümmel S (2014): Response and prognosis after neoadjuvant chemotherapy in 1,051 patients with infiltrating lobular breast carcinoma. Breast cancer research and treatment, 144(1): 153-162.
  10. Marmor S, Hui JYC, Huang JL, Kizy S, Beckwith H, Blaes AH and Tuttle TM (2017): Relative effectiveness of adjuvant chemotherapy for invasive lobular compared with invasive ductal carcinoma of the breast. Cancer, 123(16): 3015-3021.
  11. Michaut M, Chin SF, Majewski I, Severson TM, Bismeijer T, De Koning L and Tarrant F (2016): Integration of genomic, transcriptomic and proteomic data identifies two biologically distinct subtypes of invasive lobular breast cancer. Scientific reports, 6(43): 1849-18517.
  12. Nagao T, Kinoshita T, Hojo T, Tsuda H and Tamura K (2012): The differences in the histological types of breast cancer and the response to neoadjuvant chemotherapy: the relationship between the outcome and the clinicopathological characteristics. The Breast, 21(3): 289-295.
  13. Petrelli F and Barni S (2013): Response to neoadjuvant chemotherapy in ductal compared to lobular carcinoma of the breast: a metaanalysis of published trials including 1764 lobular breast cancer. Breast Cancer Res Treat., 14(142): 227–235.
  14. Salati A, Akbari, ME, Nafissi N, Noorian S, Mahdavi SR, Mirzaei HR and Shahani M (2018): Comparison of outcome between invasive lobular carcinoma (ILC) and invasive ductal carcinoma (IDC) patients treating with breast conserving surgery (BCS) and radical dose of intraoperative electron radiotherapy (IOERT). International Journal of Cancer Management, 11(11): 145-162.
  15. Truin W, Vugts G, Roumen RM, Maaskant-Braat AGJ and Nieuwenhuijzen GAP (2016): Differences in response and surgical management with neoadjuvant chemotherapy in invasive lobular versus ductal breast cancer. Annals of surgical oncology, 23(1): 51-57.‏
  16. Veys I, Pop CF, Barbieux R, Moreau M, Noterman D, De Neubourg F and Bourgeois P (2018): ICG fluorescence imaging as a new tool for optimization of pathological evaluation in breast cancer tumors after neoadjuvant chemotherapy. PloS one, 13(5): e0197857.

 

تقییم العلاج الجراحى لمرضى سرطان الثدى للإناث ما بعد العلاج الکیمیائى مقارنة بین سرطان القنوات اللبنیه والسرطان الفصی بالثدی (المرحلة الثالثة)

السعید احمد محمود دومة، سعید حسنى بندارى، احمد یسرى العجماوى*، عمرو محمود زاید**، نادر محمد عبد الحمید

أقسام الجراحة العامة، الطب النووى* والأشعة التشخیصیة**، کلیة الطبـ، جامعة الأزهر

خلفیة البحث: العلاج الکیمیائى الاولى لمرضى سرطان الثدى من المرحلة الثالثة له العدید من الفوائد منها تقلیل حجم الورم مما یجعله قابل للاستئصال الجراحى.

الهدف من البحث: تقییم العلاج الجراحى لمرضى سرطان الثدى بعد العلاج الکیمیائى مقارنة بین سرطان الفصى للثدى وسرطان الغدد اللبنیة.

المرضى وطرق البحث: تم اجراء هذه الدراسة فی قسم الجراحة بوحدة جراحة الأورام (دراسة مرجعیة) على 50 مریضة تتراوح أعمارهم مابین 20 الى 60 سنة مقسمین الى مجموعتین 25 مریضة بسرطان الفص بالثدى و25 مریضة بسرطان الغدة اللبنیة الذین تلقوا علاج کیماوى أولى بقسم الطب النووی بجامعة الازهر وخضعوا للجراحة بوحدة جراحة الأورام بجامعة الازهر فى الفترة ما بین شهر یونیو 2019 إلى شهر مارس 2020.

نتائج البحث: عملیة الإستئصال الجراحى التحفظى للثدى أقل حدوثا فى السرطان الفصى للثدى بنسبة 24% مقارنة بسرطان القنوات اللبنیة حیث کانت النسبة 68%.

الإستنتاج: السرطان الفصى للثدى أقل إستجابة للعلاج الکیمیائیى ما قبل التدخل الجراحى کعلاج أولى عند مقارنته بسرطان القنوات اللبنیه للثدى من حیث الإستجابه الإکلینکیه، والباثولوجیه التامه، والإستئصال الجراحى التحفظى للثدى.

  1. REFERENCES

    1. Aragon-Ching JB, Werntz RP, Zietman AL, Werntz RP and Steinberg GD (2018): Multidisciplinary Management of Muscle-Invasive Bladder Cancer Current Challenges and Future Directions. American Society of Clinical Oncology Educational Book, 38(12): 307-318.‏
    2. Barquet-Muñoz, SA, Villarreal-Colin SP, Herrera-Montalvo LA, Soto-Reyes E, Pérez-Plasencia C, Coronel-Martínez J and De León DC (2015): Metaplastic breast cancer: a comparison between the most common histologies with poor immunohistochemistry factors. BMC cancer, 15(1): 75-84.
    3. Chehade, HEH, Headon H, Kasem A and Mokbel K (2016): Refining the performance of sentinel lymph node biopsy post-neoadjuvant chemotherapy in patients with pathologically proven pre-treatment node-positive breast cancer: an update for clinical practice. Anticancer research, 36(4): 1461-1471.
    4. Gebreamlak E, MK Tse G and Niu Y (2013): Progress in evaluation of pathologic response to neoadjuvant chemotherapy of breast cancer. Anti-Cancer Agents in Medicinal Chemistry (Formerly Current Medicinal Chemistry-Anti-Cancer Agents), 13(2): 222-226.
    5. Henderson JR, Kandola S, Hignett SP, Teasdale RL, Topps AR, Pennick M and Kirwan CC (2017): Infection Prophylaxis for Breast Implant Surgery: Could We Do Better? Eplasty, 17.
    6. Huober J, Fasching PA, Barsoum M, Petruzelka L, Wallwiener D, Thomssen C and Kubista E (2012): Higher efficacy of letrozole in combination with trastuzumab compared to letrozole monotherapy as first-line treatment in patients with HER2-positive, hormone-receptor-positive metastatic breast cancer–results of the eLEcTRA trial. The Breast, 21(1): 27-33.
    7. Kwon S and Seungjun L (2016): Recent advances in microwave imaging for breast cancer detection. International Journal of Biomedical Imaging, 8(13): 1-26.
    8. Lobbes MB I, Prevos R, Smidt M, Tjan-Heijnen VCG, Van Goethem M, Schipper R and Wildberger, J. E. (2013): The role of magnetic resonance imaging in assessing residual disease and pathologic complete response in breast cancer patients receiving neoadjuvant chemotherapy: a systematic review. Insights into imaging, 4(2): 163-175.
    9. Loibl S, Volz C, Mau C, Blohmer JU, Costa S D, Eidtmann H, Kümmel S (2014): Response and prognosis after neoadjuvant chemotherapy in 1,051 patients with infiltrating lobular breast carcinoma. Breast cancer research and treatment, 144(1): 153-162.
    10. Marmor S, Hui JYC, Huang JL, Kizy S, Beckwith H, Blaes AH and Tuttle TM (2017): Relative effectiveness of adjuvant chemotherapy for invasive lobular compared with invasive ductal carcinoma of the breast. Cancer, 123(16): 3015-3021.
    11. Michaut M, Chin SF, Majewski I, Severson TM, Bismeijer T, De Koning L and Tarrant F (2016): Integration of genomic, transcriptomic and proteomic data identifies two biologically distinct subtypes of invasive lobular breast cancer. Scientific reports, 6(43): 1849-18517.
    12. Nagao T, Kinoshita T, Hojo T, Tsuda H and Tamura K (2012): The differences in the histological types of breast cancer and the response to neoadjuvant chemotherapy: the relationship between the outcome and the clinicopathological characteristics. The Breast, 21(3): 289-295.
    13. Petrelli F and Barni S (2013): Response to neoadjuvant chemotherapy in ductal compared to lobular carcinoma of the breast: a metaanalysis of published trials including 1764 lobular breast cancer. Breast Cancer Res Treat., 14(142): 227–235.
    14. Salati A, Akbari, ME, Nafissi N, Noorian S, Mahdavi SR, Mirzaei HR and Shahani M (2018): Comparison of outcome between invasive lobular carcinoma (ILC) and invasive ductal carcinoma (IDC) patients treating with breast conserving surgery (BCS) and radical dose of intraoperative electron radiotherapy (IOERT). International Journal of Cancer Management, 11(11): 145-162.
    15. Truin W, Vugts G, Roumen RM, Maaskant-Braat AGJ and Nieuwenhuijzen GAP (2016): Differences in response and surgical management with neoadjuvant chemotherapy in invasive lobular versus ductal breast cancer. Annals of surgical oncology, 23(1): 51-57.‏
    16. Veys I, Pop CF, Barbieux R, Moreau M, Noterman D, De Neubourg F and Bourgeois P (2018): ICG fluorescence imaging as a new tool for optimization of pathological evaluation in breast cancer tumors after neoadjuvant chemotherapy. PloS one, 13(5): e0197857.