Introduction

Oncology Letters

1792-1074 1792-1082

D.A. Spandidos

10.3892/ol.2020.12375

OL-0-0-12375

Articles

Comparisons of ICG-fluorescence with conventional tracers in sentinel lymph node biopsy for patients with early-stage breast cancer: A meta-analysis

Yin

Rui

1 Ding

Lu-Yu

2 Wei

Qing-Zhong

1 Zhou

3 Tang

Guang-Yuan

3 Zhu

Xun

1Department of General Surgery, Beijing Aerospace General Hospital, Beijing 100076, P.R. China 2Department of Psychiatry, The First Affiliated Hospital of China Medical University, Shenyang, Liaoning 110001, P.R. China 3Department of General Surgery, The Second Affiliated Hospital of Soochow University, Suzhou, Jiangsu 215004, P.R. China

Correspondence to: Dr Xun Zhu, Department of General Surgery, The Second Affiliated Hospital of Soochow University, 1055 SanXiang Road, Suzhou, Jiangsu 215004, P.R. China, E-mail: szdxfsdeyyzhuxun@163.com

02 2021

15 12 2020

21 2

114

18112019 24082020

2020

This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.

Radioisotopes (RI) and blue dye (BD) are routinely used markers for staining during sentinel lymph node biopsy (SLNB) in breast cancer. Compared with traditional tracers, tracer performance of indocyanine green (ICG) has been controversial. A total of 21 studies were selected from the PubMed, EMBASE and Cochrane Library databases. Detection ability was judged based on four endpoints: i) The identification rate (IR) of the patients; ii) the IR of the sentinel lymph nodes (SLNs); iii) the IR of the positive SLNs; and iv) the false negative rate (FNR). Compared with BD, ICG was superior in terms of the IR of the patients [odds ratio (OR)=7.17; 95% CI, 3.98-12.94), the IR of the SLNs (OR=8.84; 95% CI, 6.71-11.66) and FNR (OR=0.20; 95% CI, 0.08-0.48) using a fixed-effects model. There was a significant difference in both the IR of the positive SLNs (OR=21.32; 95% CI, 2.84-160.14) and FNR (OR=0.46; 95% CI, 0.23-0.91) in the ICG vs. RI group. Furthermore, when using ICG at the recommended dose, a significant difference was found in the IR of the patients (OR=1.77; 95% CI, 1.09-2.85) and the IR of the SLNs (OR=21.62; 95% CI, 5.23-89.43) using a fixed-effects model. In the ICG vs. BD combined with RI group, there were no differences in either the IR of the patients (OR=5.10; 95% CI, 0.24-107.48) or the IR of SLNs (OR=5.10; 95% CI, 0.60-256.66). In conclusion, ICG was a better tracer compared with BD or RI alone and was not a worse tracer compared with BD combined with RI. The use of the recommended dose of ICG had an improved tracer effect. ICG is expected to be widely used in SLNB in view of its clinical advantages.

sentinel lymph node biopsy indocyanine green radioisotope blue dye

Introduction

The sentinel lymph node biopsy (SLNB) method has been widely used to evaluate axillary lymphatic status. Compared with SLNB, the incidence and severity of postoperative complications, including lymphedema, swelling of the arm and sensory loss, caused by axillary lymph node dissection are higher (1). Since Krag et al (2) first reported the use of radioisotopes (RI) in 1993 and Giuliano et al (3) reported using blue dye (BD) in 1994, the combination of BD and RI has been used as a standard technique to increase the detection rate of sentinel lymph nodes (4). Certain clinical limitations of BD and RI, including allergies and radioactivity, have prompted the development of other tracer technologies (4). Indocyanine green (ICG)-guided SLNB has been employed for the staging of the axillary lymphatic status since 2005 (4) and numerous clinical trials and cohort studies have shown that ICG is a promising technology in patients with early stage breast cancer (4,5). Though the majority of these data supported the conclusion that using ICG was not worse in SLNB compared with other tracers, some studies reported that ICG is a less effective tracer. A systematic review performed in 2014 stated that ICG was significantly better than BD with regard to improving sentinel lymph node identification (5). However, a more recent systematic review reported that the ICG fluorescence method demonstrated improved axillary staging compared with the RI method (6). Therefore, it is difficult to draw a clear conclusion, because the results for comparing ICG with traditional tracers are usually contradictory. To the best of our knowledge, whether ICG can be applied clinically as a valid tracer and replace traditional standard techniques has not yet been established.

Considering the lack of conclusions regarding the clinical utility of ICG, the present study collected data from relevant randomized controlled trials and cohort studies and compared the tracer ability of ICG with BD and RI, both individually and in combination. The aim of the present study was to confirm whether ICG can act as a better tracer agent compared with conventional techniques.

Materials and methods <sec> <title>Search strategy

The present study was performed according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses statement (7). To assess the level of sensitivity, the main international electronic data sources, including PubMed (https://pubmed.ncbi.nlm.nih.gov), EMBASE (http://www.embase.com) and the Cochrane Library (https://www.cochranelibrary.com), were searched simultaneously.

The terms ‘breast cancer’, ‘sentinel lymph node biopsy’, ‘blue dye’, ‘indocyanine green’, ‘radioisotope’ and similar terms were cross-searched using the following search algorithms: ((((breast cancer OR breast neoplasms OR breast carcinoma)) AND (SLNB OR sentinel lymph node biopsy)) AND (indocyanine green OR ICG OR radioisotope OR RI OR blue dye OR BD))). All relevant studies were published between May 2009 and March 2017.

Selection criteria

The current meta-analysis included all studies meeting the following criteria: i) Patients: Patients with clinical axillary lymph node-negative early breast cancer; ii) research methods: SLNB using ICG-guided near-infrared fluorescence imaging, using ≥ two tracers and using the patient as the self control; iii) study type: Cohort study or randomized clinical trial; and iv) language: English.

The following exclusion criteria was used: i) Meeting abstracts and studies that did not contain comparisons of ICG with other tracers and articles with neoadjuvant therapy; ii) study sample sizes <10; iii) studies that performed axillary reverse mapping; and iv) studies that did not use the patients as their own controls.

All eligible studies were categorized into three groups: i) ICG vs. BD; ii) ICG vs. RI; and iii) ICG vs. BD and RI. The outcomes considered included studies that comprised the identification rate (IR) of the patients, the IR of the sentinel lymph nodes (SLNs) and the IR of the positive SLNs and false negative rate (FNR).

Data extraction

In the present study, RY and XZ assessed and screened the literature independently. Titles and abstracts were first inspected, then full texts of potentially relevant publications were obtained and screened. Any discrepancy was resolved by discussion between the reviewers. Disagreements were solved by full discussion until consensus was reached.

The characteristics of the cohort and randomized clinical studies, including first author, year of publication, number of cases and controls, device, dose of tracers and detection outcomes for each study are presented in Table I. Different equipment, including PhotoDynamic Eye (PDE), Mini-fluorescence-assisted resection and exploration (Mini-FLARE) and a charge-coupled camera (CCD) were used.

Quality assessment

The quality and bias risk of the selected papers were critically appraised separately by RY and LD. A quality assessment was performed for each of the eligible studies using the validated Newcastle-Ottawa Quality Assessment Scale (NOS) (8). This scale is composed of eight items that assess patient selection, study comparability and outcome with scores ranging 0–9. In the present meta-analysis, studies with a score of ≥6 were graded as high quality. The quality of the included studies assessed by NOS are presented in Table II. Disagreements were discussed until a consensus was reached.

Statistical analysis

Dichotomous results were summarized as pooled odds ratios (ORs) and 95% CIs around the point estimates. OR was abstracted or calculated to quantitatively evaluate the association between ICG and the other tracers. The overall pooled effect was assessed using the z-statistic with P≤0.05 indicating a statistically significantly difference. Heterogeneity between studies was assessed by the ‘I²’ value. When I²≥50% or the P-value for the I² statistic was <0.05, which indicated significant heterogeneity across the studies, the pooled estimate was calculated using a random-effects model. If the data were contrary, a fixed-effect model was adopted. Statistical heterogeneity was explored using the χ² and Τau² statistical tests. Subgroup analysis was based on the ICG dose, and studies were divided into ‘standard dose of reference’, ‘more than standard dose of reference’ and ‘less than standard dose of reference’. All statistical analyses were performed using RevMan software (version 5.3; The Nordic Cochrane Centre) and Stata software (version 15.1; StataCorp LLC). Forest plot and receiver operating characteristic plot were obtained to evaluate the sensitivity and specificity of subgroup. Funnel plots with Egger's test were used to identify publication bias. All analyses were based on previous published studies; therefore, no ethical approval or patient consent was required.

Results <sec> <title>Characteristics of eligible studies

A total of 262 articles were retrieved from PubMed, EMBASE and The Cochrane Library and, ultimately, 21 studies were selected with a total of 2,499 patients for detailed assessment (9–29). A flow diagram of the selection process is presented in Fig. 1. All the selected studies were scored ≥6 according to NOS (Table II).

Meta-analysis results

Comparison of SLNB using BD, RI and ICG was performed in 21 studies and analyzed using four outcome variables. ICG was compared with BD alone, RI alone and RI with BD separately. The results of the meta-analysis are presented in Table III.

ICG vs. RI IR of patients

A total of 13 studies involving 1,731 patients reported the identification rate for patients using ICG and RI, which revealed no differences in the random-effects model (OR=1.63; 95% CI, 0.65-4.10; P=0.30; Fig. 2A). The heterogeneities of the detection rate of these patients were high (I²=55%; P=0.02).

Taking the high heterogeneities into account, the concentration of ICG was variable and ranged from 0.1-10 mg/ml. Therefore, a subgroup analysis was performed based on a previous study by Mieog et al (30), which concluded that the optimal dose of ICG was 400–800 µM. The fixed-effects model was used to calculate the results and demonstrated that the detection rate of patients with ICG was significantly higher compared with that of RI and the heterogeneity was decreased in the standard dose subgroup (OR=1.77; 95% CI, 1.09-2.85; P=0.02; Fig. 2B).

IR of SLNs

A total of 10 studies with 881 patients investigated the detection rate for SLNs between ICG and RI, and revealed significant differences in the random-effects model (OR=12.05; 95% CI, 1.57-92.74; P=0.02; Fig. 3A). Considering the significant heterogeneity (I²=90%; P<0.01), a subgroup analysis was performed according to the dose of ICG, and the results demonstrated that the SLN detection rate of ICG was significantly higher compared with that of the standard dose of RI (OR=21.62; 95% CI, 5.23-89.43; P<0.0001; Fig. 3B) and I² dropped from 90 to 0%, which indicated that the heterogeneity comes from the high dose group. Furthermore, a sensitivity and specificity analysis of ICG and RI lymph node detection was performed in the recommended dose group. A total of three studies including 961 lymph nodes reported the accuracy of ICG in lymph node detection was higher compared with RI (Fig. 4).

IR of positive SLNs

A total of four studies consisting of 744 patients reported the detection rate of positive SLNs between ICG and RI, which revealed significant differences in the fixed-effects model (OR=21.32; 95% CI, 2.84-160.14; P=0.003; Fig. 5A), indicating that ICG had an improved identification rate of positive SLNs compared with RI.

FNR

A total of five studies with 1,326 patients reported the FNR between ICG and RI, which revealed significant differences in the fixed-effects model (OR=0.46; 95% CI 0.23-0.91; P=0.03; Fig. 5B).

ICG vs. BD IR of patients

A total of 10 studies that included 771 patients reported the detection rate of patients using ICG and BD. The results demonstrated a significant difference in the fixed-effects model (OR=7.17; 95% CI, 3.98-12.94; P<0.00001; Fig. 6A), indicating that the detection rate of ICG was higher compared with BD. There was no heterogeneity (I²=0%. P=0.68; Fig. 6A).

IR of SLNs

A total of 10 studies involving 449 patients reported the detection rate for SLNs between ICG and BD. The results identified 1,460 SLNs and the mean number of SLNs (the number of lymph nodes detected/total number of patients) retrieved using ICG was 3.07, which was higher compared with the number of SLNs retrieved using BD (2.35). The fixed-effects model (OR=8.84; 95% CI, 6.71-11.66; P<0.00001; Fig. 6B) was used and significant differences between ICG and BD were observed, demonstrating that ICG had a statistically higher detection rate of SLNs. The heterogeneity was low with I²=37% and P=0.11 (Fig. 6B).

IR of positive SLNs

A total of four studies involving 246 patients reported the detection rate for positive SLNs between ICG and BD. The results revealed no differences in the fixed-effects model (OR=3.54; 95% CI, 0.78-16.06; P=0.10; Fig. 6C). However, the overall detection rate of positive SLNs (the number of positive lymph nodes detected/total positive lymph nodes) using ICG was 97.5% and the detection rate of using BD was 91.1%. No heterogeneity was observed at I²=0% and P=0.59.

FNR

A total of eight studies including 683 patients reported the FNR between ICG and BD, a total of 154 positive SLNs were identified and the overall FNR (the number of positive lymph nodes not detected/total positive lymph nodes) using ICG was 3.25%. This was lower than the FNR of using BD, which was 16.88%. Using the fixed-effects model, the results revealed significant differences (OR=0.20; 95% CI, 0.08-0.48; P=0.0004; Fig. 6D), which demonstrated that ICG had a lower FNR compared with BD. There was no heterogeneity at I²=0% and P=0.59. For further analysis, sensitivity and specificity analyses on this group of studies were performed and the results demonstrated that the accuracy of ICG was higher compared with that of BD in lymph node detection (Fig. 7).

ICG vs BD and RI

A total of four studies including 169 patients reported the detection rate of patients with ICG and BD combined with RI. The identification rate using the ICG method was 100%, while the identification rate of patients using the BD combined with the RI method ranged from 98–100%. No difference was reported in the fixed-effects model (OR=5.10; 95% CI, 0.24-107.48; Fig. 8A). Therefore, heterogeneity was not applicable.

Only two studies with 22 patients provided data on the detection rate of SLNs with ICG and BD combined with RI. The mean number of SLNs (the number of lymph nodes detected/total number of patients) retrieved using ICG was 1.50, which was more compared with the number detected using BD combined with RI at 1.32. No difference was revealed in the fixed-effects model (OR=12.43; 95% CI, 0.60-256.66; Fig. 8B), with heterogeneity not being applicable.

For groups with <10 studies, the publication bias was not assessed. The Egger's test was performed using the software Stata. No obvious publication bias was found since P=0.700 (Fig. 9A) and 0.259 (Fig. 9B) for IR of patients and IR of SLNs, respectively.

Discussion

The number of lymph nodes obtained from SLNB is used as a guide to decide whether or not to continue subsequent axillary lymph node dissection according to the latest National Comprehensive Cancer Network guidelines (10). Although the range of the armpit area subjected to surgery has been a decreasing, the accuracy of lymph node biopsies is becoming increasingly important and obtaining effective and convenient tracers are particularly important for surgeons (11).

The near-infrared fluorescence released by the ICG after being excited by infrared light can be imaged using an in vitro device, revealing the shape of the lymphatic vessel and positioning the breast SLN (6). It is a sufficient in vivo imaging tool due to its soft tissue penetration and is less disturbed by natural light (10).

The use of BD has the advantages of being inexpensive and easy to prepare intraoperatively (12); however, the surgeon needs to rely on vision to locate lymph nodes during tracing. Therefore, the detection rate is more dependent on the surgeon's experience and requires a longer learning curve. Additionally, the low detection rate of SLNs and high FNR render it an unsuitable tracer agent (10). RI can aid in positioning SLNs by detecting γ rays from lymph nodes on the body surface (13). It is superior to BD in detection rate; however, it has an increased surgery cost and complex operation as radioactive tracers need to be injected into the patient the day prior to surgery (10). Furthermore, the subsequent processing of radionuclides limits their use in high-volume centers (6,12).

Although the combined use of BD and RI increases the detection rate of SLNs, the advantages of an inexpensive procedure and rapid localization of lymph nodes do not apply. ICG has the clinical advantages of both BD and RI (14). ICG is a real-time navigation system that can guide the surgical procedure with visible lymphatic drainage using near-infrared fluorescence devices (12). Furthermore, ICG has the advantages of low cost and convenient preparation prior to surgery compared with BD (15). Additionally, ICG has the potential to improve operating room efficiency considering that patients are not required to visit the nuclear medicine department prior to surgery, which may contribute to improved patients experience (12). Although the required dose of RI carries safety concerns for healthcare professionals, using a non-radiative substance can certainly be an advantage (12).

A meta-analysis by Ahmed et al (5) demonstrated that ICG was superior to BD in with regard to the IR of SLNs. Furthermore, Sugie et al (6) reported that the ICG fluorescence method was better at determining axillary staging compared with the RI method. However, this previous meta-analysis (5) did not agree with the results of the present study, which indicated that ICG was superior to RI in the detection rate of SLNs and the positive SLN detection rate. Additionally, the current meta-analysis indicated that when the dose was limited to the standard dose, there was still a significant difference in the combined OR.

The effect of the ICG dose on the tracer effect has been controversial. Mitsuo et al (31) hypothesized that the concentration and total dose of ICG injection varies depending on the application. For instance, 2.5 mg/ml concentration and 0.5-1.0 ml ICG are generally used for breast cancer SLN navigation surgery. However, there is certain evidence of improved SLN detection rate at a concentration of 0.5 mg/ml compared with 2.5 mg/ml concentration. The present study analyzed the traceability of ICG by dose. The grouping of ICG doses was based on a study by Mieog et al (30), which concluded that the optimal dose of ICG was between 400 and 800 µM by assigning patients to different ICG concentration groups of 50–1,000 µM. As per the study by Mieog et al (30), the grouping of ICG doses is reasonable. The results of the current study demonstrated that using the recommended dose of ICG obtained an improved detection result and the use of a higher dose may cause difficulties in detection due to leakage of fluorescent tracer in lymphatic vessels (14).

The present study has the following differences compared with previous studies. Firstly, the condition of patients being their own controls was incorporated into the inclusion criteria, which avoids bias due to population differences. Secondly, the patient detection rate was differentiated from the SLN detection rate, making the definition ‘sentinel lymph node detection rate’ more objective. Lastly, different doses of ICG ultimately have different effects on lymph node detection, which provided guidance for the future use of ICG doses.

The present meta-analysis compared ICG with BD combined with RI in breast cancer. The results demonstrated that ICG alone is not significantly different to BD combined with RI in terms of the detection rate of patients and the detection rate of SLNs, indicating that ICG alone is not worse compared with BD combined with RI. Although there was no statistical difference observed in the overall lymph node detection rate using ICG at 100%, this was higher than the 87.88% of BD combined with RI.

Several limitations in the current meta-analysis should be noted. Firstly, the ICG fluorescence imaging equipment used by the previous studies was not uniform; therefore, data was extracted from studies that used different equipment, including PDE, Mini-FLARE and CCD. Among these, PDE was the most commonly used. However, other equipment have also been used clinically and were able to achieve a high detection rate of SLNs. Secondly, the definition of SLNs varies in different trials. Wishart et al (17) demonstrated that all tracers (including ICG, BD and RI) detected lymph nodes as SLNs, while Sugie et al (18) concluded that intraoperatively palpable lymph nodes, termed para-SLN, should also be classified as SLNs. Other studies (19–21) did not reach the same conclusion. Therefore, altering the intended definition of SLN may lead to certain differences in the detection rate of SLN. Thirdly, the criteria for enrollment for each trial were different, particularly in regard to previous axillary surgery history. Although all patients were clinically node-negative, there were studies that did not specify the exclusion criteria, making the patients heterogeneous in the present meta-analysis. Lastly, the authors may have missed certain unpublished investigations, considering studies with positive results are usually more prone to being published.

In conclusion, the present comprehensive meta-analysis indicated that using ICG alone is a better tracer agent compared with using BD or RI alone, and is not worse compared with BD combined with RI. A suitable dose of ICG can increase the detectability and accuracy, and decrease the heterogeneity. Considering the clinical convenience of ICG, it may be used as a suitable alternative to traditional tracers to detect SLNs in patients with breast cancer.

Acknowledgements

Not applicable.

Funding

No funding was received.

Availability of data and materials

The datasets generated and/or analyzed during the current study are available from the corresponding author on reasonable request.

Authors' contributions

RY conceived the current study and collected data. XZ put forward the concept of ICG as a new tracer superior to traditional tracers and helped design the article and gave final approval of the version to be published, participated in the revision of the article, checked the data, provided the final conclusion for the version to be published, provided support for obtaining some documents in the article, provided administrative support and gave final approval of the version to be published. LD, QW, YZ and GT collected, analyzed and interpreted the data. RY drafted and revised the manuscript. All authors read and approved the final manuscript.

Ethics approval and consent to participate

Not applicable.

Patient consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

Abbreviations

SLNB

sentinel lymph node biopsy

radioisotopes

blue dye

ICG

indocyanine green

identification rate

SLN

sentinel lymph nodes

FNR

false negative rate

References 1

Mansel

Fallowfield

Kissin

Goyal

Newcombe

Dixon

Yiangou

Horgan

Bundred

Monypenny

Randomized multicenter trial of sentinel node biopsy versus standard axillary treatment in operable breast cancer: The ALMANAC trial

J Natl Cancer Inst985996092006

10.1093/jnci/djj158

16670385

Krag

Weaver

Alex

Fairbank

Surgical resection and radiolocalization of the sentinel lymph node in breast cancer using a gamma probe

Surg Oncol23353401993

10.1016/0960-7404(93)90064-6

8130940

Giuliano

Kirgan

Guenther

Morton

Lymphatic mapping and sentinel lymphadenectomy for breast cancer

Ann Surg2203914011994

10.1097/00000658-199409000-00015

8092905

Kitai

Inomoto

Miwa

Shikayama

Fluorescence navigation with indocyanine green for detecting sentinel lymph nodes in breast cancer

Breast Cancer122112152005

10.2325/jbcs.12.211

16110291

Ahmed

Purushotham

Douek

Novel techniques for sentinel lymph node biopsy in breast cancer: A systematic review

Lancet Oncol15e351e3622014

10.1016/S1470-2045(13)70590-4

24988938

Sugie

Ikeda

Kawaguchi

Shimizu

Toi

Sentinel lymph node biopsy using indocyanine green fluorescence in early-stage breast cancer: A meta-analysis

Int J Clin Oncol2211172017

10.1007/s10147-016-1064-z

27864624

Moher

Liberati

Tetzlaff

Altman

PRISMA Group

Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement

Ann Intern Med151264269, W642009

10.7326/0003-4819-151-4-200908180-00135

19622511

Stang

Critical evaluation of the Newcastle-Ottawa scale for the assessment of the quality of nonrandomized studies in meta-analyses

Eur J Epidemiol256036052010

10.1007/s10654-010-9491-z

20652370

Schaafsma

Verbeek

Rietbergen

van der Hiel

van der Vorst

Liefers

Frangioni

van de Velde

van Leeuwen

Vahrmeijer

Clinical trial of combined radio and fluorescence guided sentinel lymph node biopsy in breast cancer

Br J Surg100103710442013

10.1002/bjs.9159

23696463

Liu

Huang

Wang

Chen

Indocyanine green detects sentinel lymph nodes in early breast cancer

J Int Med Res455145242017

10.1177/0300060516687149

28415938

Sugie

Kinoshita

Masuda

Sawada

Yamauchi

Kuroi

Taguchi

Bando

Yamashiro

Lee

Evaluation of the clinical utility of the ICG fluorescence method compared with the radioisotope method for sentinel lymph node biopsy in breast cancer

Ann Surg Oncol2344502016

10.1245/s10434-015-4809-4

26275781

Samorani

Fogacci

Panzini

Frisoni

Accardi

Ricci

Fabbri

Nicoletti

Flenghi

Tamburini

The use of indocyanine green to detect sentinel nodes in breast cancer: A prospective study

Eur J Surg Oncol4164702015

10.1016/j.ejso.2014.10.047

25468752

Stoffels

Dissemond

Pöppel

Schadendorf

Klode

Intraoperative fluorescence imaging for sentinel lymph node detection: Prospective clinical trial to compare the usefulness of indocyanine green vs technetium Tc 99m for identification of sentinel lymph nodes

JAMA Surg1506176232015

10.1001/jamasurg.2014.3502

26017057

Luo

Jiang

Wei

Yang

Liu

Clinical utility of the additional use of blue dye for indocyanine green for sentinel node biopsy in breast cancer

J Surg Res21588922017

10.1016/j.jss.2017.03.038

28688667

Grischke

Röhm

Hahn

Helms

Brucker

Wallwiener

ICG fluorescence technique for the detection of sentinel lymph nodes in breast cancer: Results of a prospective open-label clinical trial

Geburtshilfe Frauenheilk759359402015

10.1055/s-0035-1557905

Tong

Guo

Gao

Use of fluorescence imaging in combination with patent blue dye versus patent blue dye alone in sentinel lymph node biopsy in breast cancer

J Breast Cancer172502552014

10.4048/jbc.2014.17.3.250

25320623

Wishart

Loh

Jones

Benson

A feasibility study (ICG-10) of indocyanine green (ICG) fluorescence mapping for sentinel lymph node detection in early breast cancer

Eur J Surg Oncol386516562012

10.1016/j.ejso.2012.05.007

22704050

Sugie

Sawada

Tagaya

Kinoshita

Yamagami

Suwa

Ikeda

Yoshimura

Niimi

Shimizu

Toi

Comparison of the indocyanine green fluorescence and blue dye methods in detection of sentinel lymph nodes in early-stage breast cancer

Ann Surg Oncol20221322182013

10.1245/s10434-013-2890-0

23429938

Hirano

Kamimura

Ogura

Kim

Hattori

Setoguchi

Okubo

Inoue

Miyamoto

Kinoshita

A comparison of indocyanine green fluorescence imaging plus blue dye and blue dye alone for sentinel node navigation surgery in breast cancer patients

Ann Surg Oncol19411241162012

10.1245/s10434-012-2478-0

22782671

van der Vorst

Schaafsma

Verbeek

Hutteman

Mieog

Lowik

Liefers

Frangioni

van de Velde

Vahrmeijer

Randomized comparison of near-infrared fluorescence imaging using indocyanine green and 99(m) technetium with or without patent blue for the sentinel lymph node procedure in breast cancer patients

Ann Surg Oncol19410441112012

10.1245/s10434-012-2466-4

Jung

Kim

Kwon

Lee

Kang

Shin

Lee

Park

Comparison of sentinel lymph node biopsy guided by the multimodal method of indocyanine green fluorescence, radioisotope, and blue dye versus the radioisotope method in breast cancer: A randomized controlled trial

Ann Surg Oncol21125412592014

10.1245/s10434-013-3437-0

24356798

Hojo

Nagao

Kikuyama

Akashi

Kinoshita

Evaluation of sentinel node biopsy by combined fluorescent and dye method and lymph flow for breast cancer

Breast192102132010

10.1016/j.breast.2010.01.014

20153649

Hutteman

Mieog

van der Vorst

Liefers

Putter

Löwik

Frangioni

van de Velde

Vahrmeijer

Randomized, double-blind comparison of indocyanine green with or without albumin premixing for near-infrared fluorescence imaging of sentinel lymph nodes in breast cancer patients

Breast Cancer Res Treat1271631702011

10.1007/s10549-011-1419-0

21360075

Verbeek

Troyan

Mieog

Liefers

Moffitt

Rosenberg

Hirshfield-Bartek

Gioux

van de Velde

Vahrmeijer

Frangioni

Near-infrared fluorescence sentinel lymph node mapping in breast cancer: A multicenter experience

Breast Cancer Res Treat1433333422014

10.1007/s10549-013-2802-9

24337507

Ballardini

Santoro

Sangalli

Gentilini

Renne

Lissidini

Pagani

Toesca

Blundo

del Castillo

The indocyanine green method is equivalent to the 99mTc-labeled radiotracer method for identifying the sentinel node in breast cancer: A concordance and validation study

Eur J Surg Oncol39133213362013

10.1016/j.ejso.2013.10.004

24184123

Pitsinis

Provenzano

Kaklamanis

Wishart

Benson

Indocyanine green fluorescence mapping for sentinel lymph node biopsy in early breast cancer

Surg Oncol243753792015

10.1016/j.suronc.2015.10.002

26555151

Polom

Murawa

Nowaczyk

Rho

Murawa

Breast cancer sentinel lymph node mapping using near infrared guided indocyanine green and indocyanine green-human serum albumin in comparison with gamma emitting radioactive colloid tracer

Eur J Surg Oncol381371422012

10.1016/j.ejso.2011.11.004

22130469

Guo

Zhang

Gao

Liu

Tong

Evaluation of the benefit of using blue dye in addition to indocyanine green fluorescence for sentinel lymph node biopsy in patients with breast cancer

World J Surg Oncol122902014

10.1186/1477-7819-12-290

25239029

Murawa

Hirche

Dresel

Hünerbein

Sentinel lymph node biopsy in breast cancer guided by indocyanine green fluorescence

Br J Surg96128912942009

10.1002/bjs.6721

19847873

Mieog

Troyan

Hutteman

Donohoe

Van Der Vorst

Stockdale

Liefers

Choi

Gibbs-Strauss

Putter

Toward optimization of imaging system and lymphatic tracer for near-infrared fluorescent sentinel lymph node mapping in breast cancer

Ann Surg Oncol18248324912011

10.1245/s10434-011-1566-x

21360250

Kusano

Kokudo

Toi

Kaibori

ICG fluorescence imaging and navigation surgery

Springer

Japan

2016

10.1007/978-4-431-55528-5

Figure 1.

Flow diagram for the selection of the including studies. RCT, randomized clinical trial.

Figure 2.

Comparison of ICG and RI in the IR of patients. (A) Results prior to grouping ICG doses. (B) Results following grouping of ICG doses. ICG, indocyanine green; RI, radioisotope; IR, identification rate; M-H, Mantel-Haensze.

Figure 3.

Comparison of ICG and RI in the IR of sentinel lymph nodes. (A) Results prior to grouping ICG doses. (B) Results following grouping of ICG doses. ICG, indocyanine green; RI, radioisotope; IR, identification rate; M-H, Mantel-Haensze.

Figure 4.

Comparison of the sensitivity and specificity between ICG and RI subgroups. (A) Forest plot of tests and (B) the summary of receiver operating characteristic plot of tests for the two study groups, indicating the accuracy of ICG in lymph node detection was higher compared with that of RI. ICG, indocyanine green; RI, radioisotope; TP, true positive; FP, false positive; FN, false negative; TN, true negative.

Figure 5.

Comparison of ICG and RI in the other outcomes. (A) Comparison of ICG and RI in the identification rate of positive sentinel lymph nodes. (B) Comparison of the false negative rate of ICG and RI. ICG, indocyanine green; RI, radioisotope; M-H, Mantel-Haensze.

Figure 6.

Comparison of ICG and BD in different outcomes. (A) IR of patients. (B) IR of SLNs. (C) Result of IR of positive SLNs. (D) False negative rate results of ICG and BD. ICG, indocyanine green; BD, blue dye; IR, identification rate; SLNs, sentinel lymph nodes; M-H, Mantel-Haensze.

Figure 7.

Comparison of sensitivity and specificity between ICG and BD. (A) Forest plot of tests and (B) the summary of receiver operating characteristic plot of tests for the two study groups, indicating the accuracy of ICG in lymph node detection was higher compared with that of BD. ICG, indocyanine green; BD, blue dye; TP, true positive; FP, false positive; FN, false negative; TN, true negative.

Figure 8.

Comparison of ICG and BD combined with RI in different outcomes. (A) IR of patients. (B) IR of sentinel lymph nodes. ICG, indocyanine green; BD, blue dye; RI, radioisotope; IR, identification rate; M-H, Mantel-Haensze.

Figure 9.

Funnel plots with Egger's test were used to identify publication bias. (A) Result of publication bias in IR of patients and (B) results of IR of SLNs for the two study groups. No obvious publication bias was observed. IR, identification rate.

Table I.

Characteristics and technical details in each group of the selected studies in the current meta-analysis.

A, ICG vs. BD

											IR of patients		IR of SLNs		IR of positive SLNs		FNR

Author, year	Type	No. of tracers	Device	Concentration, mg/ml	Volume, ml	Dose, mg	Procedures	SLNs	Positive SLNs	Positive SLN patients	ICG	BD	ICG	BD	ICG	BD	ICG	BD	(Refs.)
Hirano et al, 2012	Cohort	2	PDE	N/A	2.5	N/A	108	N/A	N/A	16	107/108	100/108	N/A	N/A	N/A	N/A	1/16	5/16	(19)
Wishart et al, 2012	Cohort	3	PDE	0.39	2	0.78	104	201	25	18	104/104	101/104	201/201	191/201	25/25	25/25	0/18	0/18	(17)
van der Vorst, 2012	RCT	3	Mini-FLARE	0.39	1.6	0.62	12	19	N/A	N/A	12/12	12/12	19/19	16/19	N/A	N/A	N/A	N/A	(20)
Jung et al, 2014	RCT	3	ICG-F	0.6	1	0.6	43	N/A	N/A	9	43/43	39/43	N/A	N/A	N/A	N/A	N/A	N/A	(21)
Hojo et al, 2010	Cohort	3	PDE	N/A	2	N/A	113	N/A	N/A	31	113/113	105/113	N/A	N/A	N/A	N/A	0/31	5/31	(22)
Sugie et al, 2013	Cohort	2	PDE	0.39	0.5-1.0	N/A	99	340	N/A	20	98/99	77/99	281/340	121/340	N/A	N/A	0/20	6/20	(18)
Pitsinis et al, 2015	Cohort	2	PDE	0.39	5	1.95	50	87	18	10	50/50	48/50	87/87	84/87	18/18	18/18	0/10	0/10	(26)
Guo et al, 2014	Cohort	2	PDE	1.25	1	1.25	86	291	N/A	25	80/86	70/86	281/291	255/291	N/A	N/A	3/25	4/25	(28)
Schaafsma et al, 2013	Cohort	3	Mini-FLARE	0.125/0.25	N/A	N/A	32	48	N/A	13	N/A	N/A	48/48	42/48	N/A	N/A	N/A	N/A	(9)
Liu et al, 2017	Cohort	2	PDE	1	1	1	60	177	N/A	12	60/60	53/60	177/177	106/177	N/A	N/A	N/A	N/A	(10)
Tong et al, 2014	Cohort	2	PDE	5	2	10	96	N/A	N/A	28	93/96	83/96	N/A	N/A	N/A	N/A	1/29	4/29	(16)
Ji et al, 2017	RCT	2	PDE	0.39	1	0.39	65	243	31	20	N/A	N/A	232/243	198/243	29/31	26/31	N/A	N/A	(14)
Hutteman et al, 2011	RCT	3	Mini-FLARE	0.39	1.6	0.62	10	14	N/A	N/A	N/A	N/A	14/14	10/14	N/A	N/A	N/A	N/A	(23)
Verbeek et al, 2014	Cohort	3	Mini-FLARE	0.39	1.6	0.62	27	40	5	3	N/A	N/A	40/40	31/40	5/5	3/5	0/5	2/5	(24)

B, ICG vs. RI

											IR of patients		IR of SLNs		IR of positive SLNs		FNR

Author, year	Type	No. of tracers	Device	Concentration, mg/ml	Volume, ml	Dose, mg	Procedures	SLNs	Positive SLNs	Positive SLN patients	ICG	BD	ICG	BD	ICG	BD	ICG	BD	(Refs.)

Ballardini et al, 2013	Cohort	2	PDE	0.39	1	0.39	134	246	N/A	N/A	134/134	133/134	245/246	231/246	N/A	N/A	N/A	N/A	(25)
Samorani et al, 2015	Cohort	2	PDE	5	0.4-1.2	2.0-6.0	301	589	70	46	297/301	287/301	583/589	452/589	70/70	55/70	0/46	6/46	(12)
Wishart et al, 2012	Cohort	2	PDE	0.39	2	0.78	104	201	25	18	104/104	93/104	201/201	156/201	25/25	25/25	0/18	0/18	(17)
van der Vorst et al, 2012	RCT	3	Mini-FLARE	0.39	1.6	0.62	24	37	N/A	N/A	23/24	23/24	37/37	35/37	N/A	N/A	N/A	N/A	(20)
Polom et al, 2012	Cohort	2	PDE	0.1/10	1	0.1/10	28	68	N/A	3	28/28	27/28	68/68	58/68	N/A	N/A	0/3	0/3	(27)
Jung et al, 2014	RCT	3	ICG-F	0.6	1	0.6	43	N/A	N/A	9	43/43	43/43	N/A	N/A	N/A	N/A	N/A	N/A	(21)
Hojo et al, 2010	Cohort	3	PDE	N//A	2	N/A	29	N/A	N/A	N/A	29/29	27/29	N/A	N/A	N/A	N/A	N/A	N/A	(22)
Sugie et al, 2016	Cohort	2	PDE	0.39	1	0.39	821	N/A	N/A	180	798/821	796/821	N/A	N/A	N/A	N/A	12/180	18/180	(11)
Schaafsma et al, 2013	Cohort	3	Mini-FLARE	160/320uM	N/A	N/A	32	48	N/A	13	32/32	32/32	48/48	48/48	N/A	N/A	N/A	N/A	(9)
Murawa et al, 2009	Cohort	2	IC-View	5-15	1-3	N/A	20	N/A	N/A	13	20/20	17/20	N/A	N/A	12/13	10/13	1/13	3/13	(29)
Stoffels et al, 2015	Cohort	2	CCD	0.5	N/A	N/A	80	147	27	24	78/80	80/80	147/147	141/147	27/27	27/27	0/24	0/24	(13)
Grischke et al, 2015	Cohort	2	CCD	2	5	10	105	162	N/A	27	93/105	103/105	138/162	157/162	N/A	N/A	N/A	N/A	(15)
Hutteman et al, 2011	RCT	3	Mini-FLARE	0.39	1.6	0.62	10	14	N/A	0	10/10	10/10	14/14	14/14	N/A	N/A	N/A	N/A	(23)
Verbeek et al, 2014	Cohort	3	Mini-FLARE	0.39	1.6	0.62	95	177	22	N/A	N/A	N/A	177/177	155/177	22/22	20/22	N/A	N/A	(24)

C, ICG vs. BD and RI

											IR of patients		IR of SLNs		IR of positive SLNs		FNR

Author, year	Type	No. of tracers	Device	Concentration, mg/ml	Volume, ml	Dose, mg	Procedures	SLNs	Positive SLNs	Positive SLN patients	ICG	BD	ICG	BD	ICG	BD	ICG	BD	(Refs.)

Wishart et al, 2012	Cohort	3	PDE	0.39	2	0.78	104	201	25	18	104/104	102/104	N/A	N/A	25/25	25/25	N/A	N/A	(17)
van der Vorst et al, 2012	RCT	3	Mini-FLARE	0.39	1.6	0.62	12	19	N/A	6	12/12	12/12	19/19	19/19	N/A	N/A	N/A	N/A	(20)
Jung et al, 2014	RCT	3	ICG-F	0.6	1	0.6	43	N/A	N/A	N/A	43/43	43/43	N/A	N/A	N/A	N/A	N/A	N/A	(21)
Hutteman et al, 2011	RCT	3	Mini-FLARE	0.39	1.6	0.62	10	14	N/A	N/A	10/10	10/10	14/14	10/14	N/A	N/A	N/A	N/A	(23)

SLNs, sentinel lymph nodes; IR, identification rate; FNR, false negative rate; ICG, indocyanine green; BD, blue dye; Cohort, cohort study; PDE, PhotoDynamic Eye; N/A, not available; RCT, randomized clinical trial; ICG-F, ICG-fluorescence; RI, radioisotope; CCD, charge-coupled camera; FLARE, fluorescence-assisted resection and exploration.

Table II.

The quality of the included studies as assessed by the Newcastle-Ottawa Quality Assessment Scale.

Author, year	Selection				Compa-rability		Outcome			Score	(Refs.)
Hirano et al, 2012	☆	☆	☆	☆	☆	☆	☆	☆	☆	9	(19)
Wishart et al, 2012	☆	☆	☆	☆	☆	☆	☆			7	(17)
van der Vorst et al, 2012	☆	☆	☆	☆	☆	☆	☆			7	(20)
Jung et al, 2014	☆	☆	☆	☆	☆	☆	☆	☆		8	(21)
Hojo et al, 2010	☆	☆	☆	☆	☆	☆	☆			7	(22)
Sugie et al, 2013	☆	☆	☆	☆	☆	☆	☆	☆		8	(18)
Pitsinis et al, 2015	☆	☆	☆	☆	☆	☆	☆	☆		8	(26)
Guo et al, 2014	☆	☆	☆	☆	☆	☆	☆			7	(28)
Schaafsma et al, 2013	☆	☆	☆	☆	☆	☆	☆			7	(9)
Liu et al, 2017	☆	☆	☆	☆	☆	☆	☆	☆	☆	9	(10)
Tong et al, 2014	☆	☆	☆	☆	☆	☆	☆			7	(16)
Ji et al, 2017	☆	☆	☆	☆	☆	☆	☆	☆		8	(14)
Hutteman et al, 2011	☆	☆	☆	☆	☆	☆	☆			7	(23)
Verbeek et al, 2014	☆	☆	☆	☆	☆	☆	☆			7	(24)
Ballardini et al, 2013	☆	☆	☆	☆	☆	☆	☆			7	(25)
Samorani et al, 2015	☆	☆	☆	☆	☆	☆	☆			7	(12)
Polom et al, 2012	☆	☆	☆	☆	☆	☆	☆			7	(27)
Sugie et al, 2016	☆	☆	☆	☆	☆	☆	☆			7	(11)
Murawa et al, 2009	☆	☆	☆	☆	☆	☆	☆			7	(29)
Grischke et al, 2015	☆	☆	☆	☆	☆		☆			6	(15)
Stoffels et al, 2015	☆	☆	☆	☆	☆	☆	☆			7	(13)

Table III.

Results of the meta-analysis.

	Pooled estimates		Heterogeneity

Variable	OR	95% CI	I², %	P-value
IR of patients
ICG vs. BD	7.17	3.98-12.94	0	0.68
ICG vs. RI	1.63	0.65-4.10	55	0.02
Standard dose of reference	1.77	1.09-2.85	47	0.11
More than standard dose	0.86	0.41-1.83	71	0.02
Less than standard dose	N/A	N/A	N/A	N/A
ICG vs. BD and RI
IR of SLNs
ICG vs. BD	8.84	6.71-11.66	37	0.11
ICG vs. RI	12.05	1.57-92.74	90	<0.05
Standard dose of reference	21.62	5.23-89.43	0	0.53
More than standard dose	2.50	1.56-3.99	95	<0.05
Less than standard dose	N/A	N/A	N/A	N/A
IR of positive SLNs
ICG vs. BD	3.54	0.78-16.06	0	0.59
ICG vs. RI	21.32	2.85-160.14	0	0.34
ICG vs. BD and RI	N/A	N/A	N/A	N/A
FNR
ICG vs. BD	0.20	0.08-0.48	0	0.59
ICG vs. RI	0.46	0.23-0.91	23	0.27
ICG vs. BD and RI	N/A	N/A	N/A	N/A

OR, odds ratio; IR, identification rate; ICG, indocyanine green; BD, blue dye; RI, radioisotope; N/A, not available; SLNs, sentinel lymph nodes; FNR, false negative rate.