Introduction
Thyroid cancer is a common malignant tumor of the
endocrine glands. Previous findings have shown that the detection
rate of thyroid cancer is on the increase, particularly among
radiologists, where the rate of thyroid cancer has undergone an
increase of approximately 0.9–1.5%. This increase may be the result
of diet, work stress, and exposure to radiation (1). Differentiated thyroid cancer (DTC)
accounts for approximately 85% of thyroid cancers and early
surgical resection is the first choice of treatment. Although the
prognosis of DTC is good, recurrence or metastasis in DTC remains
at 10–30% (2). The recurrence of the
disease is commonly identified in the thyroid bed and local lymph
nodes. Metastasis is not common in DTC; however, when lung or bone
metastasis occurs, the prognosis is poor.
Radioactive iodine-131 (131I) cleared
postoperative residual thyroid tissue (referred to as ‘clear
residual thyroid tissue’ treatment) or treatment of recurrence and
metastasis (known as ‘clearing kitchen’), simultaneously combined
with the L-T4 inhibitor constitute the principal treatment
(3). The importantce of ‘clear
residual thyroid tissue’ treatment for patients with DTC lies in
the fact that it can destroy microscopic lesions that cannot be
idenfitied using visual observance and reduce the local recurrence
rate, while simultaneously removing residual thyroid tissue. For
patients with DTC metastasis, treatment with 131I is
imperative. The first key step in the treatment of local or distant
metastasis of DTC is ‘clear residual thyroid tissue’ treatment.
131I is considered an effective, safe, and simple
treatment for patients with DTC, and is capable of improving the
survival rate of patients. However, it has been previously reported
that due to the anatomical location of tumor, the parathyroid may
also suffer from radiation damage, causing hypoparathyroidism and
disorders of related electrolytes (such as blood calcium and
phosphorus) (4). Additionally, the
success rate and curative effect of ‘clear residual thyroid tissue’
treatment is influenced by a number of factors, such as cancer
classification, staging, and diameter (5). Thus, investigations to identify
appropriate treatment is of clinical significance.
The aim of the study was to determine the effect of
the 131I ‘clear residual thyroid tissue’ treatment
following DTC resection on the parathyroid function. The results
suggested that this type of treatment did not significantly impair
parathyroid function, thereby improving the treatment effect.
Materials and methods
Subjects
A total of 160 patients who were consecutively
admitted in our Hospital and diagnosed with DTC underwent total
thyroidectomy or subtotal resection between June 2012 and June
2014. The patients were diagnosed as DTC by color doppler
ultrasound, fine needle aspiration and postoperative pathology.
The inclusion criteria for the study
were
i) The patient age was ≥18 and <75 years; ii)
patients were confirmed to suffer DTC and underwent complete
thyroidectomy or subtotal thyroidectomy; iii) were previously
treated in our Hospital.
Exclusion criteria of the study
were
i) Thyroid secondary tumor, combined with malignant
tumor in other organs; ii) pregnancy, infection, autoimmune
diseases, and severe heart, liver, kidney and other organ
dysfunction; iii) parathyroid gland injury or parathyroid
transplantation owing to surgical resection; iv) patient already
undergoing 131I ‘clear residual thyroid tissue’
treatment, and assessment of parathyroid hormone (PTH), serum
calcium and phosphorus levels; v) recently ingested calcium or
vitamin D; vi) patients with poor compliance and intolerance to
131I treatment, and rejection of the study.
The subjects included 91 females and 69 males, aged
29–73 years, with an average age of 48.2±9.6 years. Of the 160
cases included in the study, 74 cases were thyroid papillary
carcinoma, 60 cases were follicular carcinoma and 26 cases were
mixed type.
Methods
The therapeutic equipment for 131I ‘clear
residual thyroid tissue’ treatment used was: Hamamatsu BHP6602
miniature gamma camera (General Electric Co., Fairfield, CT, USA),
and SN-697 fully automatic, reflex and immune R counter with dual
probes (Shanghai Nuclear FI Power Equipment Co., Ltd., Shanghai,
China). The treatment was administered according to the guidelines
of American College of Nuclear Medicine, which recommends that when
tumor-node-metastasis is above T2, patients with N1 or M1 should be
treated with 131I ‘clear residual thyroid tissue’. When
the wound is completely healed, thyroid preparation is terminated
for 2–4 weeks and an iodine diet is rigorously avoided for 4 weeks.
The drugs were administered via the 131I automatic
filling instruments of HTA Co., Ltd. (Beijing, China). Generally
the dose administered was 2.96–5.55 GBq depending on whether
metastatic lesions were present in vivo and the
postoperative residual thyroid tissue was adjusted for the initial
131I dose, which was ingested, without prior food
consumption, orally once. Following drug administration, the
patients immediately remained in the auxiliary hospital ward, and
consumed a light diet on the specific day. Thyroid hormone
suppression therapy was initiated 3 days later. Within one week,
patients underwent a whole body scan (WBS). If WBS showed no
abnormal radionuclide concentration in the whole body and the
thyroglobulin (TG) of patients continued to be <1 ng/ml, ‘clear
residual thyroid tissue’ treatment was considered successful,
otherwise 131I treatment was repeated again within 3
months.
Observation index
Prior to and following the initial treatment, and
the end of the follow up, the changes in PTH, serum calcium and
phosphorus levels were analyzed. PTH levels of <5 ng/dl were
regarded as hypoparathyroidism, while PTH levels of <5 ng/dl
lasting 6 months, were regarded as persistent hypoparathyroidism.
PTH levels that returned to a normal state within 6 months, were
regarded as transient hypoparathyroidism. Of these, the normal
reference range of FT3 was from 3.67 to 10.43 pmol/l, of FT4 was
from 11.2 to 20.1 pmol/l, and of thyroid-stimulating hormone (TSH)
was from 0.34 to 5.06 IU/ml. The normal reference range of TG was
from 5 to 40 ng/ml, of PTH was from 5 to 20 ng/dl, of serum calcium
was 2.25–2.75 mmol/l and of serum phosphorus was from 0.97 to 1.61
mmol/l.
TSH luminescent reagents
FT3 and FT4 reagents were provided by Siemens AG,
Munich, Germany. TSH was assessed by the ADVIA Centaur automatic
chemiluminescence analyzer. TSH utilizes the immunoradiometric
assay method of the direct chemiluminescence technique, and FT4 and
FT3 were estimated using the competitive ELISA method of direct
chemiluminescence technique. HG detection reagents for the
radioimmunoassay method were provided by Beijing Northern Institute
of Biological and Technology (Beijing, China).
Statistical analysis
The data were processed using SPSS 19.0 statistical
software package (SPSS, Inc., Chicago, IL, USA). The measurement
data were presented as mean ± standard deviation (SD). The
comparisons between groups were analyzed by means of variance
analysis, and the count data were expressed as a percentage. The
χ2 test was used for the comparison between groups.
P<0.05 was considered to indicate a statistically significant
difference.
Results
General state of patients
Of a total of 160 patients, 24 patients (15%) had
cancer metastasis with 11 cases of cervical lymph node metastasis,
7 cases of mediastinal lymph node metastasis, 4 cases of pulmonary
metastasis, and 2 cases of bone metastasis. There were 114 cases of
total thyroidectomy and 46 cases of subtotal resection. The first
131I dose administered was 2.6–8.2 GBq and the average
dose was 6.4+1.2 GBq. The treatment of ‘clear residual thyroid
tissue’ was successful in 66 cases (41.3%). The average treatment
time of 131I was 2.8±0.6 therapy sessions. Until the
termination of the follow-up period in June 2015, a total of 142
successful cases were identified.
Comparison of PTH, serum calcium and
phosphorus levels
Prior to and following the first treatment, and at
the end of the follow up, the PTH, serum calcium and phosphorus
levels were compared. The difference was not statistically
significant (P>0.05). Five patients were identified with
persistent hypoparathyroidism and 8 patients with transient
hypoparathyroidism (Table I).
 | Table I.Comparison of PTH, serum calcium and
phosphorus levels. |
Table I.
Comparison of PTH, serum calcium and
phosphorus levels.
| Group | PTH (ng/dl) | Serum calcium
(mmol/l) | Phosphorus
(mmol/l) |
|---|
| Prior to the first
treatment | 15.9±3.4 | 2.6±0.3 | 0.8±0.3 |
| Following
treatment | 13.6±3.5 | 2.5±0.4 | 0.7±0.2 |
| Until termination of
follow-up | 10.2±2.8 | 2.4±0.2 | 0.7±0.3 |
| F-value | 0.527 | 0.638 | 0.129 |
| P-value | 0.835 | 0.415 | 0.637 |
Comparison of thyroid function
The TG and FT3 levels were significantly decreased
and the difference was statistically significant (P<0.05). There
was no significant difference between FT4 and TSH (P>0.05).
There were 48 patients with hypothyroidism (30%) (Table II).
| Table II.Comparison of thyroid function. |
Table II.
Comparison of thyroid function.
| Group | TG (ng/ml) | FT3 (pmol/l) | FT4 (pmol/l) | TSH (IU/ml) |
|---|
| Prior to the first
treatment | 4.2±0.5 | 8.6±1.1 | 16.9±3.4 | 0.4±0.1 |
| Following
treatment | 2.3±0.3 | 5.4±0.8 | 13.5±3.2 | 0.6±0.2 |
| Until termination of
follow-up | 0.8±0.2 | 3.7±0.6 | 12.4±2.9 | 0.8±0.4 |
| F-value | 5.127 | 4.518 | 1.532 | 1.924 |
| P-value | 0.032 | 0.036 | 0.629 | 0.088 |
Discussion
Although the degree of malignany is decreased in
cases of DTC, recurrence or distant metastasis occurs in
approximately 30% of patients (5).
Radioactive 131I ‘clear residual thyroid tissue’
treatment is usually utilized by β rays in 131I to
damage the residual thyroid tissue, achieving the effect of maximum
reduction of cancer recurrence (6).
The parathyroid gland is located near the thyroid gland. In the
course of radiation therapy, the radioactive 131I uptake
in the thyroid gland produces β ray of ≤2 mm that is likely to
damage the adjacent parathyroid gland. The phenomenon of declined
adjacent parathyroid tissue function is considered a bystander
effect of radiation therapy (7).
The most common complications of the 131I
‘clear residual thyroid tissue’ treatment include radioactive
thyroiditis, radioactive sialadenitis, nausea and vomiting.
However, there controversy regarding whether radiation therapy
causes the functional impairment of the parathyroid glands
(8). As early as 1987, Glazebrook
and other researchers demonstrated that the parathyroid function of
patients treated with 131I was decreased mainly after 18
months of treatment (9). In
subsequent studies, Guven and others demonstrated that the
parathyroid function of the patients treated with 131I
was decreased mainly after 6 months of treatment (10). In addition, recent findings
demonstrated that the level of PTH in the third month after
radiation therapy had an insignifant increase, and required 6
months to return to normal (11). In
2004, Chatterjee reported that there was a persistent decrease in
parathyroid function in patients with hyperthyroidism after
radioactive 131I treatment (12). However, in previous studies it was
reported that the dose of 131I radiation did not affect
the parathyroid function (13).
Therefore, this study determined whether radioactive
131I ‘clear residual thyroid tissue’ treatment following
the resection of differentiated thyroid carcinoma resulted in the
decrease of the parathyroid function and the thyroid treatment
effect.
The results of the present study have shown that,
the initial average dose of 131I at 6.4+1.2 GBq yielded
a success rate of 41.3% for ‘clear residual thyroid tissue’.
Average 131I treatment times were 2.8+0.6 and until the
termination of the follow-up at 1.8±0.5 years, the success rate of
the treatment had increased to 88.8%. In related studies (14,15), the
first 131I dose was associated with the success rate of
‘clear residual thyroid tissue’. The treatment dose and number of
times treatment was administered were associated with
hypothyroidism and the effect of the parathyroid gland. However,
unlike previous studies, the results of the present study show that
when the PTH, serum calcium and phosphorus levels prior to the
initial treatment, following treatment and termination of the
follow-up were compared, the difference was not statistically
significant. This finding may be associated with the treatment dose
and time of treatment. At the same time, our findings show that the
appropriate dose and number of times treatment was administered
were safe for the function of the parathyroid. In the present
study, 5 patients had persistent parathyroid hypofunction and 8
patients had transient parathyroid hypofunction. The total
incidence rate was only 8.1%. At the same time, the level of TG was
significantly decreased, and the difference was statistically
significant. There were 48 cases (30.0%) with parathyroid
hypofunction. No serious complications occurred after
supplementation of thyroid tablets (16).
In summary, the results have shown that, DTC
resection and 131I ‘clear residual thyroid tissue’
treatment did not significantly impair the parathyroid function,
thereby improving the treatment effect.
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