Assessment of tumor response to chemotherapy in patients with breast cancer using ¹⁸F-FLT: a meta-analysis

Introduction

Breast cancer is a leading cause of cancer death in women in the world, accounting for 23% of the total cancer cases and 14% of the cancer deaths (1). Chemotherapy is a widely accepted treatment for breast cancer. However, many patients will still be incurable despite the significant advances in treatment. There is a need to develop imaging methodologies that can enable early and objective assessment of response to chemotherapy. Currently, treatment responses are assessed on the basis of measurement of tumor size before and after treatment with serial conventional radiography, such as chest X-ray, computed tomography (CT) or magnetic resonance imaging (MRI) (2). However, response monitoring by conventional methods is recommended after 2-3 cycles of chemotherapy. Patients with breast cancer receiving chemotherapy cannot benefit from conventional radiography, since ineffective treatment could not be timely detected and replaced.

A potential novel way of response monitoring is by molecular imaging positron emission tomography (PET) imaging with 3'-deoxy-3'-¹⁸F-fluorothymidine (¹⁸F-FLT PET). ¹⁸F-FLT is a pyrimidine nucleoside that is a substrate for the cytoplasmic enzyme, thymidine kinase 1 (TK1). TK1 phosphorylates ¹⁸F-FLT into a highly charged product which is trapped and can be imaged using PET (3). Recently, some studies evaluated the ability of this tracer to monitor response in breast cancer. However, the numbers of cases in studies were insufficient. Thus, we perform a meta-analysis to review the update relevant literature, and assess the diagnostic role of ¹⁸F-FLT PET for evaluating response to chemotherapy in patients with breast cancer.

Materials and methods

Literature search

A systematic literature search was performed to find articles that evaluate the response of breast cancer to chemotherapy. Two investigators (BZ and SMD) independently searched the PubMed (MEDLINE included) database, EMBASE to identify relevant studies published from January 1, 1993 to October 1, 2013. It was performed with no language restrictions and limited to human studies. The key words used were (“positron emission tomography” OR “PET” OR “positron emission tomography/computed tomography” OR “PET/CT” OR “PET-CT” OR “positron emission tomography-computed tomography” OR “thymidine” OR “fluorothymidine” OR “deoxy-thymidine” OR “deoxy-l-thymidine” OR “¹⁸F-fluorodeoxy-L-thymidine” OR “3’ -deoxy-3’- fluorothymidine” OR “fluorodeoxythymidine” OR “FLT” OR “¹⁸F-FLT” OR “¹⁸FLT”) AND (“breast cancer” OR “breast carcinoma” OR “breast neoplasm” OR “breast neoplasia”) AND (“prediction” OR “response” OR “response monitoring” OR “chemotherapy” OR “neoadjuvant”) AND (“sensitivity” OR “specificity” OR “false negative” OR “false positive” OR “accuracy”). The list of articles was supplemented with extensive cross checking of the reference lists of all retrieved articles.

Study identification and selection

The inclusion criteria were as follows:

• The study investigated the performance of FLT PET/CT or PET for evaluating chemotherapy in patients with proven breast cancer;
• Histopathological analysis and/or clinical and/or radiological follow-up for at least 6 months were used as the reference standard;
• The reported primary data were sufficient to calculate the totals of true and false positives and negatives;
• The study included more than nine lesions or patients with histological breast cancer;
li>When data or subsets of data were presented in more than one article, the one with most details was chosen.

Studies were excluded based on the following criteria:

• Animal studies, case report, abstracts, reviews, letters, editorials, comments, in vitro studies, studies without raw data;
• PET/CT or PET examination used other radiotracers.

Discrepancies in judgment were resolved after discussion.

Data extraction and quality assessment

Data collected from the individual studies included: authors, year of publication, sample size, age, study design, initial clinical stage, timing for PET scans, cutoff values, definition of positive PETs, number of responders and non-responders, characteristics of PET/CT or PET imaging, interpretation of the reference standard, and clinical and/or radiological follow-up. The numbers of true and false positives and negatives were also recorded.

The quality assessment of diagnosis accuracy studies (QUADAS) tool was selected to assess the methodological quality of the studies (4,5). QUADAS consists of 14 questions for assessing different categories of bias in a study. If the answer is “yes” then score “1”, and if the answer is “no” or “unclear” then score “0”. Two observers (BZ and SMD) independently assessed the methodological quality. A consensus was reached to resolve any differences between the two reviewers.

Statistical analysis

Two reviewers constructed 2×2 contingency tables for each study independently. For studies with zeroes in 1 or more cells, 0.5 was added to all four cells of the 2×2 table. Data on the sensitivity, specificity, positive likelihood ratio (LR+), negative likelihood ratio (LR-), diagnostic odds ratio (DOR), and 95% confidence intervals (CI) were calculated according to the numbers from the original publications. The summary receiver operating characteristic (SROC) curves and Q* index (Q* index is defined by the point where sensitivity and specificity are equal) were also obtained.

The presence of heterogeneity among different studies was analyzed by chi-square test and quantified by calculating the I² statistic with the equation: I² = (Q-df)/Q. Statistical heterogeneity was defined as an I² statistic value of more than 50% (6). According to the heterogeneity, a fixed effects model (FEM) was adopted to calculate the diagnostic indexes if homogeneity existed among different effect sizes, and a random effects model was adopted if heterogeneity existed.

All analyses were executed using, Microsoft Excel 2003 (Microsoft, Seattle, WA, USA), and Meta-Disc (version 1.4) software package (7). Meta-Disc is a freeware for performing a systematic review of diagnosis and screening tests, produced by Javier Zamora, free available at http://www.hrc.es/investigacion/metadisc_en.htm, Madrid, Spain.

Results

Search strategy and study selection

A total of 4,428 abstracts were identified by computer search and extensive cross-checking of reference lists. Twelve articles were considered as candidates after the perusal of titles and abstracts. After reading the full texts of the remaining 12 articles, 8 were excluded due to different reasons. Finally, four articles were identified as eligible, all of which were obtained with full-texts. The flow diagram for the selection of the studies is presented in Figure 1.

Figure 1 Flow diagram for selection of studies.

Methodological quality assessment

On basis of the results of the “QUADAS” quality assessment, all studies met at least 11 of the 14 standards. However, no study met all the 14 questions (Table 1). The main weakness was the execution of reference standard was not described in sufficient detail. Actually, a “clinical and/or radiological follow-up” was introduced as reference standard for all the four studies instead of “histopathological analysis”. Another weakness was blind interpretation of PET or reference standard results. In 2 of the 4 included studies, the time period between reference standard and PET was not short enough for using “follow-up” as standard criteria.

Table 1 The distribution of methodological characteristics
Full table

The characteristics of the studies

Characteristics of the four eligible studies included in the meta-analysis are outlined in Table 2. All were in English. There were total 46 patients in the selected studies with ages ranging 18-80 years. The sample size of the studies ranged from 6 to 18. In two studies, several patients had more than one tumor site; therefore, a total of 54 tumors were assessed in the meta-analysis.

Table 2 Characteristics of studies of ¹⁸F-Flt PET or PET/CT for assessing response to chemotherapy in breast cancer
Full table

There were three studies on PET and 1 on PET/CT. All studies performed a sequential PET or PET/CT both before and after the chemotherapy. All articles assessed treatment of same chemotherapy except one study also using endocrine therapy. In 1 study, an increase in tumor ¹⁸F-FLT uptake was selected as the cutoff criterion for response to chemotherapy after 1 hour of initiation of chemotherapy. The other 3 studies relied on reduction of ¹⁸F-FLT uptake as PET or PET/CT criteria for therapy response.

Data analysis

Across all four included studies evaluating ¹⁸F-FLT PET/CT or PET, we used a FEM to calculate pooled sensitivity, specificity, LR+, LR–, and DOR on the basis of statistical non-heterogeneity (Figures 2,3,4,5,6). The sensitivity of ¹⁸F-FLT PET/CT or PET to assess chemotherapy response in breast cancer ranged from 56.3% to 92.9%. The pool sensitivity was 77.3%. The specificity ranged from 45.8% to 91.7%. The pooled specificity was 68.5%. The detailed sensitivity, specificity, LR+, LR–, and DOR with 95% of CI for individual studies are presented in Table 3.

Figure 2 Pooled and individual studies estimating the sensitivity of ¹⁸F-FLT PET or PET/CT in monitoring response to chemotherapy in breast cancer. Studies are identified by the name of first author to the right of the graph. PET, positron emission tomography; CT, computed tomography.

Figure 3 Pooled and individual studies estimating the specificity of ¹⁸F-FLT PET or PET/CT in monitoring response to chemotherapy in breast cancer. Studies are identified by the name of first author to the right of the graph. PET, positron emission tomography; CT, computed tomography.

Figure 4 Pooled and individual studies estimating the LR+ of ¹⁸F-FLT PET or PET/CT in monitoring response to chemotherapy in breast cancer. Studies are identified by the name of first author to the right of the graph. PET, positron emission tomography; CT, computed tomography.

Figure 5 Pooled and individual studies estimating the LR- of ¹⁸F-FLT PET or PET/CT in monitoring response to chemotherapy in breast cancer. Studies are identified by the name of first author to the right of the graph. PET, positron emission tomography; CT, computed tomography.

Figure 6 Pooled and individual studies estimating the DOR of ¹⁸F-FLT PET or PET/CT in monitoring response to chemotherapy in breast cancer. Studies are identified by the name of first author to the right of the graph. PET, positron emission tomography; CT, computed tomography.

Table 3 True and false positives and negatives associated with the sensitivity, specificity, accuracy, and diagnostic odds ratios for the meta-analysis of chemotherapy assessment
Full table

The SROC curves with Q* index are shown in Figure 7. Of all four studies, the AUC (± standard error) was 0.8636 (±0.0655), the Q* index was 0.7942 (±0.0636).

Figure 7 The SROC curve for ¹⁸F-FLT PET or PET/CT. Solid circle represents each study in the meta-analysis. The size of the circle indicates the study size. SROC, summary receiver operating characteristic. PET, positron emission tomography; CT, computed tomography.

Discussion

Recently, whole-body imaging with fluorine-18 fluorodeoxyglucose positron emission tomography (FDG-PET) has gained widespread acceptance for assessing tumor response to chemotherapy in patients with breast cancer (12-14). However, it has been demonstrated that inflammatory tissues can accumulate ¹⁸F-FDG and that chemotherapy-induced inflammation can lead to misinterpretation of results. ¹⁸F-FLT has been used to demonstrate proliferative activity in various tumors. Most researchers have demonstrated that ¹⁸F-FLT is more specific than ¹⁸F-FDG for malignant tumors and is not susceptible to uptake due to inflammatory changes (15). Moreover, ¹⁸F-FLT PET images showed high tumor-to-background contrast. In a meta-analysis, 19 studies with total 786 breast cancer patients who received neoadjuvant treatment were included (16). In 15 studies ¹⁸F-FDG PET scan was performed before and at different moments during chemotherapy. The pooled analysis showed that ¹⁸F-FDG PET with a sensitivity of 84% and a DOR of 11.9 have a beneficial value to assess response of chemotherapy. However, the specificity (66%) is relatively low. Our statistical results confirmed that ¹⁸F-FLT PET/CT or PET has an important role in assessing response to chemotherapy in breast cancer, with relatively lower pooled sensitivity (77.3%), higher pooled specificity (68.5%) and DOR (14.891).

There were also drawbacks of ¹⁸F-FLT. Firstly, ¹⁸F-FLT PET or PET/CT had low sensitivity for the detection of regional lymph node metastases, which may be related to the lower uptake of ¹⁸F-FLT compared with ¹⁸F-FDG. Thus ¹⁸F-FLT scans showed more false-negative findings compared with ¹⁸F-FDG scans. Secondly, there was no standard regimen of ¹⁸F-FLT PET or PET/CT for assessing response to chemotherapy in breast cancer. The optimal moment of scanning, the quantification method and cutoff value of PET are issues. Most studies demonstrated that a decrease in ¹⁸F-FLT uptake after treatment of malignant tumors (8,9,11,17). SUV reduction rate was recommended as PET or PET/CT criterion. However, the increase in ¹⁸F-FLT uptake after treatment was also reported (10,18,19). In one included study, a repeat ¹⁸F-FLT PET was performed to assess the response and an increase in tumor ¹⁸F-FLT uptake was selected as the criterion of PET. Since no statistical heterogeneity was identified in this study, we did not performed subgroup analyses.

There are some limitations with the present study. Firstly, the number of studies is small. It may lead to imprecise and inconclusive results. Secondly, there was verification bias or workup bias, because not all patients were subjected to the same reference test. The most valid reference test for response of chemotherapy is histopathology. But not all patients and lesions were biopsied consistently. Therefore, the present study used histopathological analysis and/or close clinical and/or radiological follow-up for at least 6 months as reference standard. Other potential limitations include publication bias, selector bias.

Conclusions

To our knowledge, this is the first report using meta-analysis to assess the overall diagnostic role of ¹⁸F-FLT PET or PET/CT for evaluating response to chemotherapy in patients with breast cancer. As examined by the QUADAS tool, methodological quality of reports was relatively high. Despite some limitations, meta-analysis demonstrated a beneficial value of ¹⁸F-FLT PET or PET/CT to monitor the response to chemotherapy in breast cancer, with reasonable sensitivity, specificity and DOR. Studies with larger scale are warranted to further assess the regimen of ¹⁸F-FLT PET.

Acknowledgements

This study was supported by the Open Program of Key Laboratory of Nuclear Medicine, Ministry of Health and Jiangsu Key Laboratory of Molecular Nuclear Medicine (KF201305 and KF201306), Science and Technology Development Program of Suzhou (SYSD2013076).

Disclosure: The authors declare no conflict of interest.

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