Abstract
Objectives
Thyroid nodular disease is one of the most commonly observed medical conditions. Cytological evaluation of the specimens obtained with fine-needle aspiration biopsy (FNAB) is the most accurate tool for selecting nodules which should be further surgically removed. A major limitation of this method is the high occurrence of non-diagnostic results. This indicates the need for improvement of the thyroid biopsy technique. The aim of this meta-analysis was to compare the diagnostic value of thyroid core-needle biopsies (CNBs) and FNABs.
Materials and methods
PubMed/MEDLINE, Cochrane Library, Scopus, Cinahl, Academic Search Complete, Web of Knowledge, PubMed Central, PubMed Central Canada and Clinical Key databases were searched. Risk ratios (RRs) of non-diagnostic results were meta-analysed using the random-effects model.
Results
Eleven studies were included in the quantitative analysis. CNB yielded significantly more diagnostic results – the pooled risk ratio (RR) of gaining a non-diagnostic result was 0.27 (p<0.0001). For lesions with one previous non-diagnostic FNAB, RR was 0.22 (p<0.0001).
Conclusions
CNB seems to be a valuable diagnostic technique yielding a higher proportion of diagnostic results than conventional FNAB. It is also significantly more effective in case of nodules with a prior non-diagnostic result of FNAB results than repeated FNABs.
Key Points
• Core-needle biopsy yields a higher proportion of diagnostic results than fine-needle biopsy.
• Core-needle biopsies may decrease the amount of unnecessary thyroidectomies.
• Probability of gaining non-diagnostic result using core-needle biopsy is almost four times lower.
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Introduction
Thyroid nodular disease (TND) is one of the most commonly observed medical conditions, affecting a large number of individuals, especially women, subpopulations in iodine-deficient regions, elderly people and patients with some specific clinical conditions. The prevalence of TND is high, affecting 10–70 % of the general population and malignancies are observed in 3–10 % of patients [1–5]. Cytological evaluation of the specimens obtained with fine-needle aspiration biopsy (FNAB) is the most accurate tool for selecting nodules which should be further surgically removed (malignancies, indeterminate follicular lesions) [6]. One of the major limitations of this method is a high occurrence of non-diagnostic results, falling in group I of the Bethesda Classification [7]. According to numerous studies, around 10–20 % of FNABs yield non-diagnostic results [8–10]. Most endocrinological societies recommend consideration of total thyroidectomy in cases of repeated FNABs with non-diagnostic results [11]. This may increase the number of unnecessary thyroidectomies and also delay the final diagnosis of thyroid cancer. This indicates the need for improvement of the thyroid biopsy technique or even searching for new tools which may decrease the prevalence of non-diagnostic results. Biopsy with the use of a core needle (CNB) is believed to be reliable improvement on FNAB, bringing high diagnostic yield [12, 13]. The aim of the current meta-analysis was to compare the diagnostic value of thyroid CNBs and FNABs.
Materials and methods
Study selection
PubMed/MEDLINE, Cochrane Library, Scopus, Cinahl, Academic Search Complete, Web of Knowledge, PubMed Central, PubMed Central Canada and Clinical Key databases from January 2001 up to December 2014 were searched in order to find all relevant, full-text journal articles written in English. We used the search term: ((“core-needle”) or (core and needle)) and thyroid. Articles comparing the percentage of diagnostic results of thyroid FNAB and CNB, performed with sonographic guidance, were included in the meta-analysis. According to the Bethesda System for Reporting Thyroid Cytopathology [14], categories II–VI are interpreted as diagnostic results. Samples classified as Bethesda category III and IV are inconclusive results in the context of differentiation between benign and malignant lesions but assessed as adequate for cytological assessment. We excluded studies about very particular groups of lesions (e.g. hyalinasing trabecular tumours, follicular tumours) and studies where FNAB or CNB was performed without ultrasound guidance. Studies without control groups, comparing results of FNAB with FNAB and CNAB performed simultaneously (without distinct data about the FNAB and CNAB results) were systematically reviewed.
Two researchers (K.W. and A.S.) searched all included databases independently and prepared a list of included studies. In case of discrepancies between lists, authors read questionable articles together.
Quality assessment of the studies
All included studies were assessed using the Newcastle-Ottawa Scale [15]. Studies with a result of seven stars or more were included.
Statistical analysis
All calculations were performed using Statistica v.10 with the medical package from Statsoft. Risk ratios (RRs) of non-diagnostic result were meta-analysed using the random-effects model. Publication bias was assessed using Kendall’s tau.
Results
The search results and steps of selection are shown in the flowchart (Fig. 1). Eleven studies were included to the meta-analysis – the basic data are shown in Table 1 [6, 16–25]. CNB yielded significantly a higher amount of diagnostic results. The forest plot is shown on Fig. 2. The pooled RR of non-diagnostic results was 0.27 with a 95 % confidence interval (CI) 0.16–0.46 (p<0.0001). There is no evidence for publication bias (Kendall’s tau = −0.24, two-tailed p-value = 0.31). There was evidence of significant heterogeneity (Q =85.3, df=10, i2=88.3 %, p<0.0001).
(Table 2)
We have also performed some analyses in subgroups.
Seven studies focused on lesions with one previous non-diagnostic result of FNAB [17–21, 23, 24]. The forest plot is shown on Fig. 3. The pooledRR of gaining a non-diagnostic result was 0.22 (95 % CI 0.10–0.45, p=0.0001). There is no evidence for publication bias (Kendall’s tau = −0.33, two-tailed p-value = 0.29). There was evidence of significant heterogeneity (Q =47.5, df=6, i2=87.37 %, p<0.0001).
Four studies from South Korea were performed with very similar methodology [17, 18, 20, 23]. Lesions with one previous non-diagnostic FNAB were included, in all studies the ACECUT system by TSK, Japan was used. For these studies the pooled RR was 0.05 (95 % CI 0.02–0.10, p<0.0001). ). There is no evidence for publication bias (Kendall’s tau = 0.0, two-tailed p-value = 1.0). There was no evidence of significant heterogeneity (Q =1.2, df=3, i2=0.0 %, p=0.76).
Discussion
CNB yielded a significantly higher percentage of diagnostic results than FNAB in lesions with previous non-diagnostic results with FNAB. RR was 0.27, which means that the probability of gaining a non-diagnostic result was almost four times lower. However, the number of studies comparing the diagnostic efficacy of FNAB was rather low. We found 11 case-control studies on the topic. In addition, these studies differed with regard to the diameters of needles and design of the study (CNB as the first-line procedure or as a procedure performed after one or more non-diagnostic FNABs, prospective/retrospective character, simultaneous CNB and FNAB, or CNB and FNAB performed in distinct groups of subjects). Among these studies, nine had shown significantly higher diagnostic effectiveness of CNB, in one the difference was not significant [19], and in one FNAB had a significantly higher percentage of diagnostic results with borderline significance [25].
We also performed subgroup analyses. We found seven studies comparing FNAB and CNB in lesions with previous non-diagnostic results with FNAB; however, those studies were diverse in terms of methodology. Among those seven studies, four showed that CNB yielded incomparably higher diagnostic effectiveness – RR of non-diagnostic result <0.1 [17, 18, 20, 23]. According to two studies, CNB was significantly more effective; however, the result was less impressive than that of the four studies mentioned above [21, 24]. Another study did not reveal any advantage of CNB over repeated FNAB [19].
These discrepancies suggest that further studies are strongly recommended. One of the possible reasons could be different diameters of fine and core needles used in particular studies. Stangierski et al. [19] used 25 G fine and 22 G core needles, Samir et al. [21] used 25 and 20 G, respectively; in the study performed by Na et al. [20] 18 G needles were used for CNB and different types of needles for FNAB (21–25 G, proportion unknown), Lee et al. [18] used 18 G core needles, data about fine needles were not given. Similarly, Yeon et al. [26] reported very a high percentage of diagnostic results with CNB with 18 G needles in lesions after one non-diagnostic FNAB (over 98 %); however, this study was not included in the meta-analysis due to the lack of a control group.
Another possible reason for this heterogeneity could result from many variables, rather difficult to meta-analyse, such as experience of the radiologist/endocrinologist performing the biopsy, number of passes, equipment used, etc. Four studies performed using similar equipment (automatic biopsy guns from the same manufacturer) in patients with one previous non-diagnostic FNAB showed very homogenous results [17, 18, 20, 23]. This fact can suggest that equipment used and group of patients selected are the most important factors influencing the findings; homogeneity in these two areas resulted in very homogenous results. Pooled results of these studies were very impressive – the risk of gaining a non-diagnostic result was 20 times lower than in the case of FNAB. According to this data, automatic biopsy guns can be helpful in patients with non-diagnostic results with FNAB. However, the invasiveness of the procedure should also be taken into account.
Another aspect worth considering is a pain sensation among patients undergoing both kinds of procedures. The number of studies on this topic is limited. Reports performed by Stangierski et al. [19] and Nasrollah et al. [27] indicate CNB is slightly more painful than FNAB; however, it is tolerable for most patients. But it is worth keeping in mind that the difference in the diameter of core and fine needles in both studies was quite small – 21G versus 23G. In a study performed by Capri et al. [28], fine needles and large needles were used. The authors report no difference in pain sensation accompanying the two procedures; however, a small amount of anaesthesia was injected subcutaneously before the biopsy. According to the accessible data, it seems that the use of core needles is not accompanied by patient intolerance and a severe pain sensation.
The current study constitutes a large meta-analysis which aims to systematize this important topic. An interesting study on this issue was published by Trimboli et al. in 2014 [29]. These authors found and briefly described many previously published studies. However, it was systematic review so there was no quantitative synthesis of the results. There was also one conceptually similar meta-analysis published by Li et al. [30]. However, the authors of that study included a smaller number of studies, five, whereas 11 studies were included in the current study. Partially this difference can be explained by the fact that quite a few studies have been published recently and were not available for Li et al. [16–19]. A greater number of included studies allowed for additional analyses in subgroups (e.g. comparison of FNAB and CNB in lesions with one previous non-diagnostic FNAB). Finally, the meta-analysis published by Li et al. brought some confounding results: a visible, but nonsignificant difference in the diagnostic values of FNAB and CNB. Our study including more studies provides more definite, clinically important conclusions.
In conclusion, the CNB seems to be a valuable diagnostic technique yielding a higher proportion of diagnostic results than conventional FNAB. It is also significantly more effective in cases of nodules with prior non-diagnostic results with FNAB than repeated FNABs. However, further studies on the topic are required.
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Acknowledgments
The scientific guarantor of this publication is Prof. Marek Ruchala, Head of the Department of Endocrinology, Metabolism and Internal Medicine, Poznan University of Medical Sciences. The authors of this manuscript declare no relationships with any companies, whose products or services may be related to the subject matter of the article. This study was supported by the Poznan University of Medical Sciences, Faculty of Medicine II (grant nr 502-14-02221354-41127). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
One of the authors has significant statistical expertise. Institutional Review Board approval was not required because the study is a meta-analysis. Written informed consent was waived by the Institutional Review Board. Some study subjects or cohorts have not been previously reported.
Methodology: meta-analysis, performed at one institution.
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Kosma Wolinski and Adam Stangierski contributed equally to this work.
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Wolinski, K., Stangierski, A. & Ruchala, M. Comparison of diagnostic yield of core-needle and fine-needle aspiration biopsies of thyroid lesions: Systematic review and meta-analysis. Eur Radiol 27, 431–436 (2017). https://doi.org/10.1007/s00330-016-4356-9
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DOI: https://doi.org/10.1007/s00330-016-4356-9