Background
Accurate nodal staging of the neck is essential in guiding management and predicting prognosis for patients with head and neck squamous cell carcinoma (HNSCC). A single nodal metastasis reduces a patient’s survival rate by 50 %–this is further halved with bilateral lymphadenopathy [
1‐
3]. The use of
18F-fluorodeoxyglucose positron emission tomography (
18 F-FDG PET) in the workup of HNSCC has allowed non-invasive, quantitative assessment of a tissue by analysing the 3-dimensional distribution of radioactivity based on the annihilation photons that are emitted by labelled tracer [
4]. PET scans are superior to computed tomography (CT) and magnetic resonance imaging (MRI) because metabolic changes resulting from malignancies precede structural changes [
5]. However, while providing metabolic information about tissues, PET scans offer poor visualization of anatomic structures, thereby limiting their use. This shortcoming has been overcome by integrated
18F-FDG PET/CT scanners and has improved the nodal staging of the neck [
6,
7].
At present, there have been only two studies that have examined the relationship between the maximum standardized uptake value (SUV
max) of a node and the presence of nodal metastasis [
8,
9]. Both studies used nodal SUV
max in conjunction with nodal size measured from the CT images to predict nodal metastasis. There have been no studies using nodal SUV
max alone or using a ratio nodal SUV
max and background tissue SUV
max to negate variables that could cause different SUV
max readings between patients and between institutions.
The aims of this study were to define a nodal SUVmax cut-off with the greatest sensitivity and specificity for the detection of nodal metastasis, as well as to determine if a ratio between nodal SUVmax and each of aortic blood pool SUVmax, liver SUVmax and primary tumour SUVmax could be used as a universal predictor of cervical lymph node metastasis.
Methods
Study population
This retrospective single tertiary centre study identified 74 patients from January 2011 to December 2014 with newly diagnosed HNSCC who had undergone elective neck dissection with curative intent at the Department of Otolaryngology and Head & Neck Surgery, Monash Health, Melbourne.
The exclusion criteria included the following: patients who had previous chemotherapy or radiotherapy for any malignancy; patients who did not undergo pre-operative 18 F-FDG PET/CT or had 18 F-FDG PET/CT scans performed external to our institution; patients whose neck dissection specimens were not clearly divided into the individual levels; and patients who did not have a HNSCC, were excluded. The study protocol was approved by the ethics committee at Monash Health.
PET/CT imaging and SUV measurements
18 F-FDG PET/CT scans were obtained with an advanced integrated PET/CT scanner (Siemens Biograph™ TruePoint™). All patients were fasted for at least six hours prior to the PET/CT examination. A standard dose of 300 MBq 18 F-FDG tracer was used for all patients. In the period between injection of 18 F-FDG tracer and image acquisition, the patient was instructed to remain seated or recumbent and silent in order to minimize muscular 18 F-FDG uptake. Patients were kept warm 30–60 min prior to tracer injection and throughout the uptake period in order to minimize 18 F-FDG accumulation in brown fat. Blood glucose was measured for all diabetic patients to ensure that it was within acceptable limits. Patients with blood glucose >10 mmol/L were rescheduled. Image acquisition was performed 53 to 124 min after tracer injection. Dual time point imaging was not used in this study.
A standard scan for suspected HNSCC at our institution covered vertex to upper thighs. The CT images were acquired without contrast and comprised of a topogram and the helical CT scan. The reconstruction parameters used for a standard scan were 168matrix, True D reconstruction, FWHM 5.0, 3 iterations, 21 subsets and 1.0 zoom.
After the acquisition, SUV
max was assessed on the Siemens syngo MultiModality WorkPlace (MMWP) system by a single nuclear medicine physician. SUV
max was determined by manually placing a cylindrical region of interest (ROI) over the largest lymph node in each nodal basin of interest, as well as the primary tumour site, the descending aorta and liver. This was done on trans-axial images by an experienced nuclear medicine physician. Node SUV
max values were divided by the SUV
max of the primary tumour, descending aorta and liver to calculate the following:
-
nodal SUVmax/primary tumour SUVmax
-
nodal SUVmax/aortic SUVmax
-
nodal SUVmax/liver SUVmax
The short and long axis of the largest node in each nodal basin were also recorded.
Only cervical nodal levels 1 to 5 were examined in this study as these were the most common levels removed in a neck dissection.
Two nuclear medicine physicians then systematically examined each PET/CT scan visually and determined which cervical nodal levels had metastatic nodes. This was compared to the pathology results. A nodal basin with at least one metastatic node was deemed to be a ‘metastatic basin’, regardless of the number of metastatic nodes within the basin or the size of the metastatic deposit(s).
Histopathological analysis
Neck dissection specimens were either removed level by level or enbloc and then divided into the individual nodal levels. Nodal evaluation was performed by dedicated head and neck pathologists at our institution, in accordance with the guidelines issued by the Royal College of Pathologists in the United Kingdom. The specimens were inspected and palpated and each discrete palpable node was dissected out with attached peri-capsular adipose tissue. These nodes were then placed in a cassette which was then stained and serially sliced prior to being loaded onto pathology slides for viewing under the microscope. Pathologic findings on the lymph nodes were recorded at each anatomic level. Only lymph nodes in cervical levels one to five were examined–intra-parotid, occipital or pre-auricular nodes were excluded.
The pathology reports were reviewed by the investigators to determine if the nodal basin contained any metastatic nodes.
Statistical analysis
All statistical analyses were performed using IBM SPSS version 22 by two bio-statisticians. The pathologic status and SUVmax of cervical lymph nodes were collected for calculating the receiver operating characteristic (ROC) curve and Youden’s Index for determining the cut-off value for SUVmax. The Youden index, which is a comprehensive measurement for the performance of a diagnostic test, was generated considering every possible cut-off point. The value that generates the highest Youden’s Index for the particular ratio is considered as the best cut-off for that ratio, as it provides highest discrimination between pathology and no pathology. A p-value of 0.05 or less was considered statistically significant.
Binary logistic regression was applied to assess the association of individual predictor with chance of metastasis adjusting for all possible confounding. For choosing the most suitable predictor for metastatic node a backward logistic regression was fitted including all plausible predictors. P <0.05 was considered as significant.
Discussion
The introduction of
18 F-FDG PET/CT has greatly improved preoperative staging of HNSCC. As the presence of nodal metastasis is one of the most important prognostic factors for patients with HNSCC, accurate nodal staging of these patients is essential for both appropriate management and prognostic purposes [
2,
7,
10].
For malignancies with a high risk of occult nodal metastasis, such as oral cavity SCC, elective neck dissections are routinely performed on patients with clinically negative necks. This serves staging as well as therapeutic purposes. However, for patients in whom an elective dissection is not planned based on the site and histological grade of the primary tumour, nodal staging is based solely on clinical examination and radiological imaging. In these cases, the use of SUVmax can aid in distinguishing between metastatic and benign nodes, and thus in deciding whether an elective neck dissection should be undertaken.
The standardized uptake value (SUV) is the most widely used method for the quantification of
18 F-FDG uptake [
11]. The SUV of a target can be expressed as SUV
mean or SUV
max. SUV
mean is the average SUV calculated from multiple voxels, while SUV
max is the highest voxel SUV reading in the region of interest. [
12] The SUV
max is the more common method of reporting SUV, due to the fact that it is more reproducible and less observer-dependent than SUV
mean [
12,
13]. The SUV
max is used at our institution for this reason. In our study, we have also decided to perform a per-nodal-level analysis as this analysis is commonly presented in the literature and allows comparison with other studies.
The use of SUV
max to detect nodal metastases has been studied extensively in lung cancers, but not in head and neck malignancies. A study by Bryant et al. included 397 patients with non-small cell lung cancer and found that the median SUV
max of metastatic mediastinal lymph nodes was significantly higher than that of benign nodes. Indeed, when a SUV
max cutoff of 5.3 was used instead of the traditional value of 2.5, the accuracy of
18 F-FDG-PET/CT for detecting mediastinal lymph node metastasis increased to 92 % [
14]. Another study by Ela Bella et al. looked at the ideal SUV
max cutoff for identification of metastatic mediastinal lymph nodes and found SUV
max of 4.1 to be ideal. This cut-off yielded a sensitivity of 80 % and specificity of 92 % [
15]. A similar SUV
max cut-off for identifying metastatic mediastinal lymph nodes was reported by Vansteenkiste et al. [
16].
The use of SUV
max to detect nodal metastases in the head and neck has only been reported in two studies. In 2012, Matsubara et al. looked at 38 patients with oral SCC and compared their pre-operative
18 F-FDG-PET/CT scan results with histopathological findings [
8]. The authors reported that nodes with a SUV
max of more than 4.5 were all pathologically confirmed as being metastatic, but for nodes with SUV
max ≤ 4.5, it was not possible to distinguish between true positives and false positives. Hence, the long and short axis diameters were measured for those nodes and the long-axis diameter was found to be significantly longer in the true positive nodes. No significant difference between the true positive and false positive nodes were found in the short-axis diameter.
Murakami et al. studied 23 patients with HNSCC and found that SUV
max accurately characterized lymph nodes >15 mm in diameter, but was not reliable with respect to nodes <15 mm. Thus, size based SUV
max cut-offs were used in this study: they were 1.9 for nodes less than 10 mm in diameter, 2.5 for those 10–15 mm, and 3.0 for nodes more than 15 mm. These values yielded 79 % sensitivity and 99 % specificity [
9].
The limitations of these studies are the small sample sizes and the lack of accounting for other variables that could influence SUV readings. These include the blood sugar level of the patient at the time of PET scanning, the presence of an inflammatory process near the tumour, patient movement and the interval between injection of 18 F-FDG and acquisition of PET.
In our study, we have found that nodal SUVmax was a statistically significant predictor of metastatic nodes (p < 0.001), and that a nodal SUVmax cut-off of ≥3.16 yielded a sensitivity of 74.4 % and specificity of 84.9 %. We then hypothesized that a ratio of SUVmax values (ie, nodal SUVmax/background SUVmax) may be one way to negate these inherent differences between PET centres and standardize the measurement. Thus we measured the SUVmax of the liver parenchyma, aortic blood pool and primary tumour to see if these ratios could improve the detection of metastatic nodes. Multi-variable logistic regression analysis found the nodal SUVmax/liver SUVmax ratio to be able to distinguish, with statistical significance, between metastatic and benign nodes. This ratio offered a similar sensitivity as nodal SUVmax alone (74.1 % compared to 74.4 %). The significance of our results are that the nodal SUVmax/liver SUVmax is able to negate inherent differences between patients and PET centres and therefore standardize the measurement.
This is the first study to propose using a SUV ratio to detect metastatic cervical nodes. Currently, the lack of literature on this matter means that arbitrary SUVmax cut-off values are used. These vary significantly between institutions and the evidence for their use is lacking. Using the nodal SUVmax cut-off and/or the SUVmaz ratio cut-off proposed in this study, in addition to the usual methods of detecting a nodal metastasis, might improve the overall sensitivity and specificity of PET/CT for the detection of metastatic nodes.
Improving the pre-operative detection of nodal metastasis is important as it has the potential to alter surgical management. In patients for whom an elective dissection is not planned based on the site and histological grade of the primary tumour, nodal staging is based mainly on clinical examination and radiological imaging. In these cases, the use of nodal SUVmax alone or nodal SUVmax/liver SUVmax can aid in distinguishing between metastatic and benign nodes, and thus in deciding whether an elective neck dissection should be undertaken.
Using a nodal SUVmax/liver SUVmax ratio also allows comparison of nodal tracer uptake between PET scans performed using different scanners. Currently, a comparison is not meaningful due to differences in scanner calibration and thus SUV readings. However, a ratio would negate inherent differences between scanners, making it possible to compare a pre-treatment PET scan with a post-treatment PET scan performed at a different centre to assess treatment response.
While we think the use of nodal SUV
max/liver SUV
max ratio is promising, there are a few caveats in the use of liver SUV as a proxy for background SUV
max. The first is that the liver has an abundance of glucose-6-phosphatase, which could cause continuous glycolysis and reduce its measured SUV more rapidly compared to other tissues. However, a prospective study by Laffon et al. performed PET acquisition at two time points on the same day and reported that the decay-corrected SUV of the liver remains nearly constant if the time delay between tracer injection and PET acquisition is in the range of 50–110 min. [
17] This suggests that in clinical practice, liver SUV can be used for comparison with SUV of suspected malignant lesions, if comparison is made within this timeframe.
Another caveat of using liver SUV is in the presence of fatty liver. This has been suggested to result in a slightly decreased metabolic activity [
18], while another study reported no significant difference in SUV
max [
19]. The presence of liver tumours or metastatic disease would also give spurious liver SUV readings [
20].
The main drawback of using nodal SUVmax is that this measurement might be spuriously low in necrotic nodes. In these cases, correlation with CT findings is essential.
Another limitation of this study is the time lapse between the PET/CT scan and surgery. The median time between a patient in our study having the PET/CT scan and the neck dissection was 27 days (range 1–62). Disease progression could have occurred during this time and what was initially a benign node at the time of scanning could have turned malignant by the time of surgery.
Despite these limitations, our study has shown nodal SUV
max and nodal SUV
max/liver SUV
max ratio to be better detectors of metastatic nodes than visual inspection. This is surprising as visual interpretation integrates more information than the nodal SUV
max or SUV
max ratio measurements, in particular the distribution pattern, size, number and relative intensity of lesions and the relationship of the lesions with the primary tumour, to determine the probability of these foci of uptake representing metastatic disease. A meta-analysis by Sun et al. published in 2015 included 19 studies that performed a per-nodal-level analysis and found that the pooled sensitivity and specificity was 80 % (range 0 %–96.3 %) and 96 % (range 73.4 %–98.9 %) respectively [
21]. We acknowledge that our sensitivities and specificities for visual inspection were somewhat lower than this but when a Nodal SUV
max/Liver SUV
max ratio of >0.903 was used the sensitivity and specificity yielded was comparable.
A few reasons may account for the difference. Firstly, selective reporting bias may have contributed to the high reported sensitivities and specificities of 18FDG-PET/CT in the meta-analysis. Furthermore, 12 of the 19 studies that were included in the meta-analysis had either CT and/or MRI performed in addition to the 18FDG-PET/CT. Thus, it is possible that the imaging observers might have known the diagnostic outcome of other conventional imaging methods before assessing the results of 18FDG-PET/CT imaging, resulting in a spuriously high sensitivity and specificity for 18FDG-PET/CT.
Acknowledgements
Mr. Jason Bradley, Charge Technologist of Nuclear Medicine and PET (Monash Imaging), who kindly helped with the technical retrieval of PET/CT scans for viewing by our nuclear medicine physicians and with the technical aspects of the PET scanning protocol.