Department of Radiology and Molecular Imaging, Sultan Qaboos University Hospital, Muscat, Oman
*Corresponding Author’s e-mail: dranjalinm@gmail.com

Evaluation of Diagnostic Value of SPECT/CT 
Imaging in Post-radioiodine Therapy in 

Thyroid Cancer

Asma Al Hatmi, *Anjali Jain, Alok K. Mittal, Samir Hussain

Sultan Qaboos University Med J, February 2022, Vol. 22, Iss. 1, pp. 74–81, Epub. 28 Feb 22
Submitted 30 Jun 20
Revision Req. 1 Nov 20; Revision Recd. 30 Nov 20
Accepted 26 Dec 20

This work is licensed under a Creative Commons Attribution-NoDerivatives 4.0 International License.

https://doi.org/10.18295/squmj.4.2021.054

CLINICAL & BASIC RESEARCH

abstract: Objectives: This study aimed to investigate the value of single photon emission computed tomography/
computed tomography (SPECT/CT) imaging in well-differentiated thyroid cancer (DTC) after radioiodine (I-131) 
ablation/therapy for clinical staging and risk stratification. It also aimed to determine whether SPECT/CT would 
change the management plan or predict the clinical outcomes of DTC patients. Methods: A total of 78 DTC patients 
underwent first post radioiodine therapy “Whole body iodine-131 scintigraphy (WBS) along with SPECT/CT” at 
the Department of Radiology and Molecular imaging, Sultan Qaboos University Hospital, Muscat, Oman, between 
January 2014 and August 2017. Differences between WBS and SPECT/CT, change in clinical staging, risk stratification 
and management were recorded. The clinical outcome at 6–12 months was recorded. A generalised McNemar test was 
used to assess disagreement between WBS and SPECT/CT. Results: According to the American Thyroid Association 
(ATA) risk stratification, the sample showed low (35.8%), intermediate (53.8%) and high-risk groups (10.2%) on WBS, 
which changed to 44.8%, 38.4% and 16.6%, respectively, on SPECT/CT imaging. Overall change in risk stratification 
was noted in 16.7% and TNM stage in 11.5% of patients after SPECT/CT imaging. SPECT/CT changed the therapeutic 
plan and clinical outcome in 19.2% of patients. Conclusion: SPECT/CT allows better detection and characterisation 
of metastatic lymph nodes and distant metastasis in DTC patients compared to WBS imaging alone. It alters TNM 
staging, ATA risk classification and management in a significant number of patients. It is recommended that SPECT/
CT should be done routinely along with WBS in well-differentiated thyroid carcinoma.

Keywords: Thyroid Cancer; Iodine; Ablation Techniques; SPECT/CT; Oman.

Advances in Knowledge
- SPECT/CT has influenced American thyroid association risk stratification, TNM staging, management plan and clinical outcome in 

thyroid cancer patients.

Application to Patient Care
- This study recommends that SPECT/CT should be an integral part of Whole body I-131 scintigraphy imaging protocol in differentiated 

thyroid cancer patients.

Thyroid cancer has a good prognosis andis considered a treatable disease. The 5-year survival rates are 99.8% for localised disease, 
97.0% for regional metastases and 57.3% for distant 
metastases in well-differentiated thyroid cancer 
(DTC).1–3 It affects females more than males. The 
incidence of DTC is increasing globally over time 
due to the early detection of small lesions, which 
constitutes 87% of new cases.4,5 It is the second most 
common cancer among the Omani population as 
reported by the Ministry of Health in 2016.6 Treatment 
protocols of thyroid cancer patients vary depending 
on the initial American Thyroid Association (ATA) 
risk classification.2 ATA has divided thyroid cancer 
patients into three risk groups—low, intermediate 
and high risk.5 Radioactive iodine (RAI) treatment 
is an important aspect in the management of 
intermediate- and high-risk group patients.2 After 
total thyroidectomy, patients receive the first dose of 
radioactive iodine and routinely undergo post-therapy 

planar whole body scintigraphy (WBS) which detects 
residual thyroid tissue, lymph nodes and distant 
metastasis.3,4

The addition of single photon emission computed 
tomography/computed tomography (SPECT/CT) to 
planar WBS increases the diagnostic accuracy by 
improving the anatomic localisation of iodine uptake 
in the scan which changes the clinical stage and ATA 
risk classification.1,7 This further leads to alteration in 
the management plan such as the need for additional 
imaging, biopsy, surgery and external beam radiation 
or other systemic therapies.1,3

In addition to excellent three-dimensional local- 
isation of abnormal iodine uptake, SPECT/CT helps in 
attenuation correction as well as detecting non-iodine 
avid distant metastases, which has a tremendous 
impact on the clinical outcome and rate of survival in 
DTC patients.3,8,9 Many institutions recommend I-131 
SPECT/CT as part of the imaging protocol in selected 
high-risk patients with inconclusive findings on planar 

https://creativecommons.org/licenses/by-nd/4.0/


Asma Al Hatmi, Anjali Jain, Alok K. Mittal and Samir Hussain

Clinical and Basic Research | 75

imaging.1–3 This study examined the importance of 
SPECT/CT with I-131 WBS in Omani patients, as 
there was no such similar study done locally.

Methods

This retrospective study was conducted at Sultan 
Qaboos University hospital, Muscat, Oman. A 
computerised search of medical records of the patient 
database was made from the hospital information 
system and Radiology information system (IntelliSpace 
PACS Enterprise, Philips Healthcare Informatics Inc., 
USA). A total of 183 patients who underwent post-
RAI (ablation/therapy) whole body scintigraphy were 
recorded from January 2014 to August 2017.

The inclusion criteria were: 1) Patients with 
histopathologically proven well-differentiated thyroid 
carcinoma who underwent first RAI therapy after 
total thyroidectomy; 2) Patients on whom both, WBS 
planar and SPECT/CT were performed on the same 
day; and 3) Availability of 6–12 months follow-up with 
diagnostic I-131 WBS. Five patients were excluded 
because they did not have well-differentiated thyroid 
cancers on histopathology and another 94 patients 
were excluded as SPECT/CT was not performed. Six 
patients were excluded because of the unavailability of 
6–12 months follow up or diagnostic I-131 scan after 
the first therapy dose. Finally, a total of 78 patients 
were included in the current study [Figure 1]. 

After thyroidectomy, all patients received a high 
dose of radio-iodine for ablation/therapy. A diagnostic 
radioiodine scan was not performed as a protocol. 
Oral radioiodine dose was administered based on the 
surgical and pathological status of the tumour. Patients 
were classified into ATA low, intermediate or high-
risk groups. A 1.1–3.7 GBq of RAI was administered 
to low- to intermediate-risk groups and >3.7 GBq was 
administered to high-risk group patients and patients 
with metastases as per departmental protocol. All 
patients were prepared with adequate thyroid hormone 
stimulation before the RAI therapy. The majority 
of patients (83.4%) were kept off thyroxin for one 
month, while 16.6% of patients received recombinant 
thyroid-stimulating hormone (TSH) injection for 
thyroid hormone stimulation. A low iodine diet was 
recommended one week before RAI therapy.

Whole-body I-131 imaging was performed 3–7 
days after the radioiodine dose on Symbia T-series 
dual-head SPECT gamma camera with multidetector 
CT scanner (Siemens Healthcare A/S, Denmark). 
Both WBS planar and SPECT/CT were acquired. 
Initially, anterior and posterior WB planar images were 
acquired at a speed of 12 cm/minute with high energy 
parallel hole collimator matrix of 256 × 1,024 and 

photopeak at 364 KeV with a 15% window. Additional 
planar anterior images of the neck and lateral images 
of the abdomen were also acquired. At the same 
time, SPECT/CT images of the neck and chest were 
acquired from the skull base to the diaphragm. SPECT 
was acquired in step-and-shoot mode with 32 views 
and 180 degree rotation per detector. Acquisition time 
was between 30–60 seconds per step. Images were 
acquired with high energy parallel hole collimator with 
matrix of 128 × 128 and photopeak of 364 KeV with 
a 15% window. CT images were acquired at 130 KeV, 
reference mAs 30 with 5 mm slice thickness. Axial, 
sagittal and coronal reconstruction of images was 
done on the Siemens workstation (Siemens Healthcare 
A/S).

Both WBS and SPECT/CT images were 
interpreted by a senior nuclear medicine physician, 
blinded to other laboratory and radiological image 
results. First, the planar images were interpreted. Any 
foci of uptake higher than the surrounding background 
(other than the physiological sites of uptake) were 
considered abnormal. Foci of abnormal iodine uptake 
in the medial portion of the lower neck, approximately 
in the thyroid bed, were categorised as positive for 
residual thyroid tissue.

An abnormal focus of uptake in the lateral part 
of the neck was considered as lymph node metastases. 
Foci of uptake that are very close to the medial part of 
the neck were equivocal for lymph node metastases.3 
When more than one focus of uptake were seen in the 
medial part of the neck, the one with prominent uptake 
was considered as a residual tissue and the rest of the 
foci were interpreted as equivocal for lymph node 
metastases [Figure 2]. Foci of abnormal iodine uptake 
in mediastinum were categorised as mediastinal 
lymph node metastases, while abnormal foci adjacent 
to mediastinum were considered equivocal for lymph 
node metastases. Abnormal uptake in lung fields 
was considered as positive or equivocal for lung 
metastases. All areas of abnormal uptake beyond the 
neck and chest were also considered as positive or 
equivocal for metastatic foci and possible locations 
(bone, brain, liver, etc.) were also recorded.3

The findings were recorded as positive, negative 
and equivocal for thyroid bed, lymph node metastasis 
and distant metastasis. SPECT/CT images were 
also reviewed as a second step. Similarly, SPECT/
CT images were interpreted as positive and negative 
for thyroid bed, lymph node metastases and distant 
metastases. Non-iodine avid lesions seen on CT were 
also recorded. Changes observed in the interpretation 
of WBS planar and SPECT/CT were noted. Changes 
in ATA risk stratification and TNM staging were 
recorded.5,10 All patients were grouped into ATA low-, 



Evaluation of Diagnostic Value of SPECT/CT Imaging in Post-radioiodine Therapy in Thyroid Cancer

76 | SQU Medical Journal, February 2022, Volume 22, Issue 1

intermediate- or high-risk groups and also categorised 
into four stages according to the 8th edition of the 
American Joint Committee on Cancer (AJCC)/TNM 
staging of thyroid cancer. Changes in management 
plans like biopsies, additional cross-sectional imaging 
and further therapies were recorded. Clinical outcome 
like complete remission or additional treatment were 
noted on the 6–12 months follow-up.

A database in the SPSS programme, version 23 
(IBM Corp., Armonk, New York, USA) was created for 
statistical analysis. By using the generalised McNemar 
test, disagreement between WBS planar and SPECT/
CT was assessed in three groups, including thyroid 
bed, lymph node metastases and distant metastasis. A 
P-value of <0.05 was considered statistically significant.

This study was approved by Sultan Qaboos 
University Hospital’s Medical Research Ethical 
Committee and did not require informed consent 
(MREC# 1567).

Results

Among the 78 patients included in our study, 64 (82%) 
were females and 14 (18%) were males. The age of the 

patients ranged from 7–76 years with a mean age of 
41.6 ± 16. Papillary carcinoma was the most common 
histopathology presenting in 96% of patients compared 
to follicular and papillary carcinoma with poorly 
differentiated components in 3% and 1% of patients, 
respectively. These included nine patients of mixed 
papillary with follicular carcinoma, two patients with 
an oncocytic variant, one with a diffuse sclerosing type 
and one with Hurthle cell carcinoma. A background 
of multinodular goitre (MNG) was reported in 14% of 
patients, 6% had Graves’ disease, 10% had Hashimoto 
thyroiditis and 19% lymphocytic thyroiditis. TSH 
levels for all patients during iodine administration 
were >30 mIU/L. Thyroglobulin (TG) levels ranged 
between 1–67,795 µg/L and TG antibodies were 
positive in 20.5% of patients. Patients received high 
doses of radioactive iodine with activities ranging 
from 980–7,900 MBq. 

There was total agreement between WBS planar 
and SPECT/CT image findings in residual thyroid 
tissue uptake. Out of 78 patients, 77 showed positive 
iodine uptake in thyroid bed on both, WBS planar and 
SPECT/CT images, suggesting residual thyroid tissue. 
Only one patient did not show any iodine uptake in the 
thyroid bed on both planar and SPECT/CT images.

There was a significant difference noted between 
the WBS planar and SPECT/CT images pertaining 
to lymph node metastases. On WBS planar imaging, 
22 out of 78 patients were positive for lymph node 
metastases and 17 patients were equivocal for lymph 
node metastases. Out of the 22 patients (positive for 
lymph node metastases on WBS planar imaging), 
only 12 were positive on SPECT/CT images. In the 
remaining 10 patients (with false-positive lymph 
nodal uptake on WBS planar images), uptake was 
seen in thyroid bed on SPECT/CT images. These 10 
patients showed complete remission at 6–12 months 
follow-up with no requirement for a second RAI dose. 
All equivocal lymph node metastases on WBS planar 
images were negative for lymph node metastases 

Figure 2: Thyroid bed versus lymph nodal metastases in a 76-year-old male patient. (A) Anterior and (B) posterior I-131 whole 
body planar images reveal multiple foci of iodine uptake in medial and right lateral neck region consistent with thyroid bed residual 
and neck lymphadenopathy. (C) Coronal SPECT/CT images of the neck showing iodine avid foci are localised in post-operative 
thyroid bed with no neck lymph nodal metastasis.

Figure 1: Flowchart showing the selection process used 
for patient enrolment.



Asma Al Hatmi, Anjali Jain, Alok K. Mittal and Samir Hussain

Clinical and Basic Research | 77

on SPECT/CT imaging. The remaining 39 patients 
were negative for lymph node metastases on both 
WBS planar and SPECT/CT. There was a statistically 
significant difference between WBS planar and 
SPECT/CT imaging for lymph node metastases (P 
<0.01) [Figure 2].

WBS planar imaging has shown distant metastases 
in five patients while two patients were equivocal 
for distant metastases. The most common site of 
metastases was the lung followed by bone and liver. 
SPECT/CT confirmed distant metastases in five 
patients, while two equivocal findings on WBS planar 
imaging turned out to be negative on SPECT/CT. 
There was a statistically significant difference between 
WBS and SPECT/CT imaging in distant metastases (P 
<0.01) [Figure 3].

In addition, the CT portion of the SPECT/
CT also detected lung nodules in seven patients. 
These nodules did not show any iodine uptake on 
the post-therapy scan. Two of these patients showed 
complete resolution of nodules in the 6–12 months 
follow-up diagnostic I-131 WBS with normal TG 

levels (<1 µg/L), denoting these nodules were likely 
to be inflammatory. However, five patients in the 
6–12 months follow-up showed persistent lung 
nodules with raised TG levels and were suspicious 
for metastases. Histopathologically, two patients 
showed papillary carcinoma with an oncocytic 
variant, one with poorly differentiated components, 
one follicular carcinoma and one papillary carcinoma. 
These patients were further evaluated by F-18 
fluoro-deoxyglucose positron emission tomography/
computed tomography (FDG PET/CT) scan, which 
revealed abnormal increased FDG uptake and was 
considered as distant metastases of DTC. All of these 
patients were referred to an oncology centre and were 
treated with other systemic therapies (three patients) 
and radiotherapy (two patients) [Figure 4].

The difference between WBS planar imaging 
and SPECT/CT imaging categorising in the thyroid 
bed, neck lymph node and distant metastasis is well 
demonstrated in Figure 5.

Eight out of 10 patients with negative lymph node 
metastases on SPECT/CT imaging were restratified 

Figure 4: Non-iodine avid distant metastases in a 73-year-old male patient. (A) Anterior and (B) Posterior I-131 whole body planar 
images do not reveal any abnormal distant metastases. (C) SPECT/CT axial image showing non-avid multiple small pulmonary 
nodules. (D) 18-F FDG PET-CT axial fused image showing avid pulmonary nodules consistent with distant metastases.

Figure 3: Iodine avid distant metastases in a 67-year-old female patient. (A) Anterior and (B) posterior I-131 whole body planar 
images reveal multiple areas of abnormal iodine avid distant metastases. (C) SPECT/CT coronal image showing iodine avid 
multiple lung, liver and skeleton distant metastases.



Evaluation of Diagnostic Value of SPECT/CT Imaging in Post-radioiodine Therapy in Thyroid Cancer

78 | SQU Medical Journal, February 2022, Volume 22, Issue 1

from the intermediate to the low-risk group. Risk 
stratification in two patients did not change due to 
the presence of extra thyroidal tumour extension. Five 
out of seven patients with non-iodine avid metastases 
were restratified to high-risk group.

ATA thyroid cancer risk stratification in these 
patients was reported as low- (35.8%), intermediate- 
(53.8%) and high-risk groups (10.2%) on planar 
imaging, which changed to 44.8%, 38.4% and 16.6%, 
respectively, after SPECT/CT imaging. The overall 
change in risk stratification was noted in 13 (16.7%) 
out of 78 patients [Table 1].

The percentage of change in TNM staging was 
smaller than the change in risk stratification. Out of 
10 patients with negative lymph nodes on SPECT/
CT, TNM staging did not change in eight patients. 
These patients were <55 years old and continued to be 
categorised as stage I according to TNM staging for 
thyroid cancer. SPECT/CT down-staged the disease 
in two patients, as they were >55 years of age. The 
status of seven patients with non-iodine avid lesions 
changed from M0 to M1, thus upstaging the disease. 
The overall change in clinical staging was seen in nine 
(11.5%) patients.

All patients showing change in TNM staging and 
risk classification were from intermediate- to high-risk 
groups.

Twelve patients with positive lymph nodes 
metastases on SPECT/CT imaging did not show 
remission at 6–12 months follow-up. These findings 
were correlated with neck USG and CT scans. Out 
of these 12 patients, one underwent re-surgery for 
complete lymph nodal dissection after confirmation 

of disease on fine needle aspiration cytology (FNAC). 
The rest of the patients underwent second RAI 
therapy. Ten false-positive lymph node metastases 
on WBS planar imaging (negative on SPECT/CT) 
showed complete remission on 6–12 months follow-
up and did not require further RAI therapy, leading 
to change in clinical outcome. All five patients with 
non-iodine avid metastases on SPECT/CT (proven 
with F-18 FDG PET/CT) were upstaged from M0 to 
M1, which resulted in a change in the management 
plan. A total of 15 (19.2%) patients showed changes in 
clinical outcome and management plan. Ten patients 
with negative lymph nodes went into remission on 
follow-up, while five patients with non-iodine avid 
metastases required further treatment in terms of 
systemic therapy and radiotherapy.

Discussion

SPECT/CT has become very popular in recent years. 
With the availability of hybrid cameras, it is being used 
frequently in nuclear medicine departments. Both 
functional and structural imaging can be performed 
at the same time, giving maximum benefit in terms of 
diagnosis and further management. SPECT/CT is also 
being used with WBS planar imaging in DTC resulting 
in substantial advantage for diagnosis and localisation 
of the disease.11–19 

In the current study, all patients with DTC, who 
underwent both WBS planar and SPECT/CT imaging 
after the first RAI therapy were included. All the 
patients with only thyroid bed residual uptake showed 
no contradiction between WBS planar and SPECT/
CT findings. In some previous studies, SPECT/CT 
was acquired only in cases of diagnostic uncertainty 
and was not performed for clear thyroid bed residual 
uptake.7,15 In the current study, all patients with 
residual thyroid bed tissue also underwent SPECT/CT 
and had complete remission after the first round of 
RAI therapy. Another study has shown similar results 
in thyroid bed uptake.3 

Figure 5: Bar graph showing a comparison of results between (A) WBS Planer imaging and (B) SPECT/CT imaging. There is no 
discrepancy in thyroid bed residual tissue, while there is a significant change in interpretation of neck lymph node and distant 
metastasis.

Table 1: Change in risk stratification after SPECT/CT
Thyroid cancer risk 
stratification (%)

Whole body 
planar imaging

SPECT/CT

Low 35.8 44.8

Intermediate 53.8 38.4

High 10.2 16.6

SPECT/CT = single photon emission computed tomography/computed 
tomography.



Asma Al Hatmi, Anjali Jain, Alok K. Mittal and Samir Hussain

Clinical and Basic Research | 79

Different studies in the literature have shown the 
advantage of SPECT/CT over WBS planar imaging in 
lymph node metastases, distant metastasis and in the 
management of DTC patients.20–25 In the current study, 
there was a disagreement in nodal metastases between 
WBS planar and SPECT/CT imaging (P <0.01). These 
patients with false-positive nodes on WBS planar were 
downgraded on SPECT/CT images with complete 
remission of the disease at six months follow-up. On 
WBS planar imaging, these areas of iodine uptake 
were seen in the lateral or superior part of the neck 
and were interpreted as lymph node metastases, 
while they could be anatomically localised as residual 
thyroid tissue on three-dimensional tomographic 
acquisition of SPECT/CT images. Similarly, foci of 
uptake equivocal for lymph node metastases on WBS 
planar could also be delineated as residual thyroid 
tissue in the thyroid bed on SPECT/CT. In total, 
34% of lymph nodal disease status was changed with 
SPECT/CT, which is similar to previously reported 
results in the literature.7,16 These studies changed and 
reclassified the lymph nodal status in 34–36.4% of 
patients with SPECT/CT imaging. However; these 
studies also interpreted lymph nodal disease from N0 
status to N1 and from Nx status to N1. In the current 
study, lymph nodal status changed only from N1/Nx 
to N0. This could be explained either by differences 
in interpretation of findings on WBS planar with 
high suspicion of lymph nodal metastases. It may 
also be due to differences in surgical techniques and 
higher number of neck dissection during surgery in 
the current study, reducing the possibility of residual 
lymph nodal disease. 

Findings with distant metastases have also 
shown significant disagreement between WBS planar 
and SPECT/CT imaging (P <0.01). Two patients in 
the current study with equivocal finding of distant 
metastases were found negative on SPECT/CT. As 
shown by other studies, SPECT/CT reduced the 
number of indeterminate foci of metastases and also 
differentiated between benign physiological uptake 
from pathological uptake.3,18 In the current study, one 
of the foci in the mediastinum was localised to be 
oesophageal uptake. In another patient, diffuse linear 
uptake of iodine was seen in the lung, which was 
characterised as infective on CT images and showed 
resolution after a course of antibiotic. This is possible 
as the CT portion of SPECT/CT not only localises foci 
of uptake but also characterises the disease. Maruoka 
et al. have shown alteration of equivocal findings to 
benign findings in 38% of patients.3 The current study 
also showed a similar finding, although the number 
was much smaller. The detection of non-iodine avid 
lesions is very important in management since these 

patients cannot be treated with radioactive iodine 
and would need other treatment options. Diagnosis 
of these lesions on the post-therapy scan would save 
time and cost of additional imaging and would lead to 
proper management of the patient. Non-iodine lesions 
are also of prognostic significance and have a worse 
prognosis. In previous studies, authors have seen non-
iodine avid lesions in 21% of patients, while in the 
current study it was 9%.2 According to the literature, 
dedifferentiated thyroid cancer can show non-
iodine avid metastasis in 30% of cases and it is highly 
associated with certain aggressive histopathology 
like solid, insular and trabecular variants of poorly 
differentiated cancer, Hürthle cell carcinoma, papillary 
thyroid cancer with cribriform, columnar or tall cell 
variants.1 

The current study showed a significant difference 
in WBS planar and SPECT /CT imaging in ATA risk 
stratification, TNM staging and management and thus 
the outcome of DTC. The current findings are similar 
to other studies where risk classification was changed 
in 6.4%, 25% and 35.6% of patients, respectively, after 
SPECT/CT and change in TNM stage was seen in 6.1%, 
25.9% and 21% of patients.2,3,16,20,26 Similarly, change 
in therapeutic plan was observed in 2.0%, 24% and 
19.4% of patients after SPECT/CT.3,7,19 This variability 
in results may be explained due to differences in the 
qualitative assessment of image findings, patient 
population, age, histopathologies and variation 
in study protocols. Some studies have performed 
diagnostic I-131 scan before RAI therapy, while others 
did not.27,28 Other studies have performed SPECT/CT 
only in equivocal cases, while some studies did not 
include low-risk patients, as these patients were not 
treated with RAI.14,29 There were differences in study 
samples and type of analyses (lesion-based vs patient-
based).2,19

Overall, additional SPECT/CT imaging improves 
diagnostic accuracy, anatomic localisation and helps 
in further characterisation of lesions, especially 
equivocal areas of iodine uptake and non-avid iodine 
lesions. This alters the TNM staging and initial risk 
stratification of the patients. The management plan 
also changes accordingly and it avoids additional 
imaging in most cases. 

This study has limitations. It was a single-centre 
retrospective study with a small sample size and short 
term follow-up. Secondly, metastases were diagnosed 
on thyroglobulin levels and imaging results, while 
histopathology was not always available. Another 
limitation in this study was interpretation of WBS 
planar images with multiple foci of uptake in neck, 
where one prominent uptake was considered residual 
thyroid tissue and the rest of them as lymph node 



Evaluation of Diagnostic Value of SPECT/CT Imaging in Post-radioiodine Therapy in Thyroid Cancer

80 | SQU Medical Journal, February 2022, Volume 22, Issue 1

metastases due to limitation of planar images to 
localise the area of uptake. It has been seen on SPECT/
CT images that residual thyroid tissue can be seen as 
multiple foci of uptake.

Conclusion

SPECT/CT is a powerful diagnostic tool that allows 
better detection and further characterisation of lymph 
node and distant metastasis of well-differentiated 
thyroid carcinoma compared to WBS planar imaging 
alone. It also alters risk stratification, clinical staging 
and management plan of patients. It is recommended 
that SPECT/CT should be routinely performed in the 
evaluation of well-differentiated thyroid carcinoma 
patients after radioiodine therapy.

c o n f l i c t o f i n t e r e s t
The authors declare no conflicts of interest. 

f u n d i n g

No funding was received for this study.

a u t h o r s’ c o n t r i b u t i o n
AJ and SH conceptualised the work. AJ supervised the 
work. AAH prepared the proposal and collected the 
data. AAH and AJ analysed and interpreted the data. 
AAH drafted the manuscript. AJ and AKM reviewed 
and edited the drafted manuscript. AKM collected, 
labelled and formatted the images. All authors 
approved the final version of the work.

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