Objective:To investigate the predictive value of early thyroid function changes on the efficacy of patients with Graves′ disease (GD) after 131I therapy. Methods:Data of patients with GD (59 males, 214 females; age (37.4±11.4) years) who underwent single therapy of 131I in Tianjin Medical University General Hospital from November 2017 to January 2019 were retrospectively analyzed. Symptoms, signs and laboratory tests (serum free triiodothyronine (FT 3) and serum free thyroxine (FT 4)) of patients were observed to assess the efficacy of 131I treatment. Efficacy was divided into complete remission (CR), partial remission (PR), non-remission (NR) or relapse. The changes of thyroid function (ΔFT 3=FT 3 before treatment-FT 3 after treatment)/FT 3 before treatment×100%; ΔFT 4=FT 4 before treatment-FT 4 after treatment)/FT 4 before treatment×100%) 1 month after 131I therapy in each efficacy group and differences among them were compared by using independent-sample t test, χ2 test, one-way analysis of variance and the least significant difference t test. ROC curves were drawn to analyze the predictive values of early thyroid function changes on the efficacy of 131I treatment for GD. Logistic regression analyses were performed to identify the influencing factors for the efficacy of 131I therapy. Results:CR rate and total effective rate of 273 GD patients after single therapy of 131I were 67.03%(183/273) and 92.67%(253/273), respectively. After 1 month, CR rate of euthyroidism group ( n=95) was significantly higher than that of hyperthyroidism group ( n=178; 81.05%(77/95) vs 59.55%(106/178); χ2=4.60, P=0.032). ΔFT 3 and ΔFT 4 at the first month were statistically significant and decreased sequentially in the CR group ( n=183), PR group ( n=70), NR or relapse groups ( n=20; F values: 15.40, 12.54, both P<0.001). ROC curve analysis showed that patients with ΔFT 3≥73.64% and (or) ΔFT 4≥59.03% had a higher probability of achieving CR, with sensitivities of 84.3% and 86.7%, and specificities of 62.6% and 62.6%, respectively. Logistic regression analysis showed that 24 h radioactive iodine uptake (odds ratio ( OR)=1.095, 95% CI: 1.031-1.139), dose of 131I given per gram of thyroid tissue ( OR=1.562, 95% CI: 1.321-1.694), ΔFT 3 ( OR=1.354, 95% CI: 1.295-1.482), ΔFT 4 ( OR=1.498, 95% CI: 1.384-1.608) were factors affecting the outcome of patients with GD treated with 131I treatment (all P<0.05). Conclusion:Effects of 131I treatment can be predicted based on the change of the thyroid function at the first month after 131I treatment in patients with GD.

Objective:To analyze the clinical outcomes of initial radioactive iodine 131I therapy (RIT) for patients with familial differentiated thyroid cancer (FDTC) and sporadic differentiated thyroid cancer (SDTC), along with their influencing factors. Methods:The clinical data of 120 FDTC and 480 SDTC patients who received RIT at the Department of Nuclear Medicine, Tianjin Medical University General Hospital from January 2016 to January 2022 were retrospectively analyzed. These patients, categorized into the FDTC and SDTC groups, were further divided into three subgroups based on their response to initial RIT: no evidence of disease (NED), biochemical persistence of disease (BPD), or structural/functional persistence of disease (S/FPD). For the NED subgroup, the disease-free survival (DFS) was analyzed. For the BPD and S/FPD subgroups, the progression-free survival (PFS) was investigated. Furthermore, risk factors for failure to reach the NED status were identified.Results:After initial RIT, 56 (46.7%), 50 (41.7%), 14 (11.6%) patients in the FDTC group reached the NED, BPD, and S/FPD statuses, respectively, while 284 (59.1%), 160 (33.3%), 36 (7.5%) and SDTC patients in the SDTC group were in the NED, BPD, and S/FPD statuses, respectively ( χ2 = 10.10, P = 0.013). The last follow-up revealed that 71 (59.1%), 36 (30.1%), 13 (10.8%) patients in the FDTC group were in the NED, BPD and S/FPD statuses, respectively, while 337 (70.2%), 114 (23.7%), 29 (6.1%) patients in the SDTC group reached the NED, BPD and S/FPD statuses, respectively ( χ2 = 8.99, P = 0.026). The F-NED and S-NED subgroups exhibited 5-year DFS rates of 92.4% and 97.4%, respectively, the F-BPD and S-BPD subgroups displayed 5-year PFS rates of 88.3% and 90.8%, respectively, while the F-S/FPD and S-S/FPD subgroups yielded in 5-year PFS rates of 78.2% and 79.6%, respectively. Univariate binary logistic regression analysis indicated that the maximum diameter of tumors, T stage, M stage, recurrence risk stratification, and postoperative stimulated thyroglobulin (p-sTg) were correlated with the achievement of the NED status ( χ2=6.37-13.10, P < 0.05). Multivariable binary logistic regression analysis showed that T stage and p-sTg were independent risk factors in the achievement of the NED status ( χ2=0.11-11.33, P < 0.05). Conclusions:The response to initial RIT assists in guiding the development of subsequent treatment and follow-up strategies for DTC patients. Given that the SDTC patients exhibited better outcomes than the FDTC patients, more alertness should be paid to the RIT for FDTC patients. For patients with higher p-sTg and T stage, the initial RIT dose and follow-up interval should be increased and reduced respectively as appropriate.

Objective:To explore the role and molecular mechanism of Shikonin(SKN) in inhibiting the growth of anaplastic thyroid carcinoma(ATC) cells.Methods:The effect of SKN on ferroptosis in ATC cell lines CAL-62 was detected by flow cytometry; the expression levels of NF-κB, ferroptosis-related genes glutathione peroxidase 4(GPX4) and selenoprotein thioredoxin reductase 1(TXNRD1), glucose metabolism-related genes pyruvate kinase isoform 2(PKM2) and glucose transporter protein 1(GLUT1) were detected by Western blotting; real-time fluorescence quantitative(qPCR) to detect changes in the expression levels of GPX4, PKM2 and GLUT1; reactive oxygen species(ROS) fluorescent probe to detect changes in intracellular ROS positivity; glucose and lactic acid assay kit to detect the levels of glucose, the raw material of glucose metabolism(GLU), and lactate(LD), the product of glucose metabolism; and establishment of a subcutaneous tumour model in BALB/c nude mice to analyse the inhibitory effect of SKN on ATC in vivo.Results:Compared to the control group, after SKN treatment, the protein expression levels of NF-κB, GPX4, TXNRD1, GLUT1, and PKM2 in CAL-62 cells decreased( P=0.004, P=0.012, P=0.043, P=0.001, P=0.018); the mRNA expression of GPX4, GLUT1, and PKM2 also decreased( P<0.001, P=0.029, P<0.001). Additionally, ROS production increased( P=0.041). After treatment with the ferroptosis inhibitor Liproxstatin-1(L-1), the proportion of cell death was reversed to a certain extent, and there was no statistically significant difference in cell death proportion after L-1 treatment. Intracellular ferroptosis occurred( P<0.001), with reduced levels of glutamate(GLU) uptake and lipid peroxidation(LD) generation( P<0.001). SKN inhibited ATC tumor growth in vivo( P=0.016). Conclusion:SKN promotes intracellular ferroptosis in ATC cells, inhibits glycolysis and glucose uptake, and suppresses ATC cell growth.

Objective:To investigate the mechanism of benzyl isothiocyanate(BITC) in the treatment of anaplastic thyroid cancer(ATC).Methods:Using network pharmacological analysis, key targets of BITC and ATC were screened, followed by GO and KEGG enrichment analysis. In order to validate the findings, AutoDock software was used to dock BITC and ATC key targets. BITC was applied to two ATC cell lines(8505C and CAL-62). Flow cytometry was used to analyze cell apoptosis. Autophagy inhibitors hydroxychloroquine sulfate(HCQ) and 3-methyladenine(3MA) were used in combination with BITC. Real-time quantitative PCR was conducted to detect the gene level of LC3B, while Western blotting was utilized to examine the expression of NF-κB, LC3B Ⅱ, Beclin-1, and Bcl-2. In animal experiments, a mouse tumor model was constructed using CAL-62 cells, treated with intraperitoneal injections of BITC(100 mg/kg) and normal saline respectively, administered every other day for a total of 21 days. Immunoblotting of tumor tissue was performed to detect the expression of LC3B Ⅱ, Bcl-2, Beclin-1, and NF-κB.Results:A total of 10 key targets with binding energies≤-4.0 kcal/mol were identified. KEGG analysis showed that these genes are mainly involved in NF-κB signaling pathway and apoptosis. BITC inhibited ATC cells with IC50 values of 27.56 μmol/L for 8505C and 28.30 μmol/L for CAL-62. The expression levels of NF-κB, Beclin-1, and Bcl-2 decreased, while LC3B Ⅱ and LC3B gene expression increased. Combining 3MA with BITC enhanced cell inhibition LC3B Ⅱ expression. HCQ increased LC3B Ⅱ expression without enhancing cell and viability inhibition. In the mouse tumor model, compared to the control group, the treatment group had higher LC3B Ⅱ and lower Bcl-2, Beclin-1, and NF-κB levels.Conclusion:BITC could inhibit the growth of ATC cells in vitro and in vivo, disrupt the autophagy degradation, and inhibit the NF-κB pathway.

Objective:To analyze the metabolic mechanism of papillary thyroid cancer(PTC) in normal and Hashimoto′s thyroiditis(HT) background, and to explore the relationship between HT and PTC.Methods:This study included a matched sample set collected from Tianjin Medical University General Hospital between January 2018 and January 2019, consisting of PTC and paracancular tissue from 31 cases with coexisting HT(HT group), and 30 cases without(NC group), all confirmed pathologically following thyroidectomy. The ultra-high performance liquid chromatography combined with mixed four-stage poles time-of-flight mass spectrometry(UPLC-Q-TOF-MS) was employed to acquire data from the samples. Metabolite differences between the two groups were compared, aiming to identify distinct metabolic mechanisms of PTC under different backgrounds. Metabolic pathway analysis was conducted using Metabo-Analyst 5.0 to explore relevant metabolic pathways.Results:The HT group and NC group shared 7 common differentially expressed metabolites, including arginine, glutamic acid, cysteine, citric acid, malic acid, uracil, and taurine. Logistic regression model combined with receiver operating characteristic(ROC) analysis of these 7 biomarkers yielded excellent discriminatory capacity for PTC(area under ROC curve of HT group and NC group were 0.867 and 0.973, respectively). The common metabolic pathways were taurine and hypotaurine metabolism, arginine biosynthesis, alanine, aspartic acid and glutamic acid metabolism, arginine and proline metabolism, and glutamine and glutamic acid metabolism. The specific metabolic pathways in HT group were aminoacyl tRNA biosynthesis, glycine, serine, and threonine metabolism.Conclusion:The metabolic profiles of thyroid cancer exhibit significant differences between cases with normal backgrounds and those with HT. The specific pathways for PTC and HT are aminoacyl tRNA biosynthesis and the metabolism of glycine, serine, and threonine.

Objective:To explore the association between body mass index (BMI) and the incidence of thyroid nodules, the clinical characteristics and efficacy evaluation of differentiated thyroid cancer (DTC), respectively.Methods:Clinical data of 1 375 healthy people (1 031 males, 344 females, age: (43.5±10.6) years) who underwent routine physical examination (PE) and 1 450 patients (490 males, 960 females, age: (44.3±12.4) years) with medium-high risk DTC in Tianjin Medical University General Hospital from April 2016 to July 2020 were analyzed retrospectively. PE and DTC patients were classified into underweight group (BMI<18.5 kg/m 2), normal weight group (18.5≤BMI<24.0 kg/m 2), overweight group (24.0≤BMI<28.0 kg/m 2) and obesity group (BMI≥28.0 kg/m 2) respectively. χ2 test was employed to analyze the relation between BMI and thyroid nodules (with/without), BMI and clinical characteristics and efficacy evaluation of DTC, respectively. Logistic regression analysis was used to analyze the independent risk factors for the occurrence of thyroid nodules and the aggressiveness of DTC. Results:Among PE, there were 779 cases with nodules, and 596 cases without nodules. Comparing with those without nodules, more overweight and obese were found in PE cases with nodules (42.1%(328/779) vs 37.2%(222/596), 24.5%(191/779) vs 20.5%(122/596); χ2=13.42, P=0.004). Higher risk of developing thyroid nodules was related with older age and lower thyroid stimulating hormone (TSH) level (odds ratio ( OR): 1.044, 0.919, 95% CI: 1.029-1.060, 0.845-0.999; P<0.001, P=0.046). People with high-risk nodules were more likely to be obese than those with intermediate and lower risk nodules (5/15 vs 24.3% (186/764); χ2=21.11, P<0.001). Among 1 450 DTC patients, comparing with patients with normal weight, patients in the overweight and obesity groups were more likely to have central regional lymph node metastasis ( OR: 1.418, 1.427, 95% CI: 1.075-1.870, 1.044-1.952; P values: 0.013, 0.026), and patients in obese group were with greater risk of lesions being bilateral ( OR=0.696, 95% CI: 0.519-0.934; P=0.016). BMI was not related with the efficacy evaluation of DTC ( χ2=9.13, P=0.425). Conclusions:The incidence of thyroid nodules in people with high BMI is higher. DTC patients with high BMI may have more aggressive incidence. But BMI has no correlation with the efficacy evaluation of DTC patients after treatment.

Objective:To analyze the short-term effect of targeted drugs on quality of life in patients with radioactive iodine-refractory differentiated thyroid cancer (RAIR-DTC).Methods:From February 2020 to April 2022, 19 RAIR-DTC patients (10 males, 9 females; age (54.5±14.5) years) who received targeted drugs therapy (sorafenib, lenvatinib or anlotinib) in Tianjin Medical University General Hospital were prospectively enrolled. The thyroglobulin (Tg) levels prior and 1, 3, 6 months post the targeted treatment, and the adverse events were measured and recorded. Response evaluation criteria in solid tumors (RECIST) 1.1 version was used to evaluate the treatment response. The quality of life based on five-level EuroQol five-dimensional questionnaire (EQ-5D-5L) was monitored prior and 3 months post the targeted treatment, and the prevalence rates of mobility, self-care, usual activities, pain/discomfort, and anxiety/depression were analyzed, and the scores of health assessment were assessed. Paired t test, Kruskal-Wallis rank sum test and χ2 test were used to analyze data. Results:The prevalence rates of mobility (8/19), self-care (6/19), usual activities (10/19), pain/discomfort (10/19), and anxiety/depression (12/19) in 3 months post treatment were higher than those prior treatment (1/19, 1/19, 1/19, 2/19, 2/19; χ2 values: 4.38-11.31, all P<0.05). The score of health assessment prior treatment was (84.37±6.25), which was higher than that at 3 months post treatment (71.63±9.14; t=5.02, P=0.001). After targeted treatment, 10 patients were with skin toxicity, 8 patients were with hypertension, 8 patients were with weight loss, 7 patients were with diarrhea, 6 patients were with fatigue, 5 patients were with hepatic dysfunction, 2 patients were with proteinuria, 2 patients were with muscle pain and 1 patient was with oral ulcer. Of 19 patients, 17 insisted on continuing treatment, and the other two stopped treatment. The Tg levels at 1, 3 and 6 months post treatment were 56.26(44.60, 210.50), 53.36(41.25, 203.07) and 54.35(34.71, 223.52) mg/L, respectively, which were lower than the level prior treatment with no significant difference (110.16(49.63, 294.50) mg/L; H=2.42, P=0.490). After 3 months of targeted treatment, the progression-free survival (PFS) rate was 16/17, including 7 patients with partial response (PR), 9 patients with stable disease (SD), and 1 patient with progression of disease (PD). After 6 months of targeted treatment, the PFS rate was 10/17, including 5 patients with PR, 5 patients with SD, and 7 patients with PD. Conclusion:After 3-6 months of targeted treatment, the tumor markers of most patients are decreased with metastases improved, but the adverse events of targeted drugs have a great impact on quality of life in patients with RAIR-DTC.

Objective:To explore new methods of treating Graves′ disease (GD) by targeting thyroid stimulating hormone receptor (TSHR) and intercellular adhesion molecule-1 (ICAM-1).Methods:The small interfering RNA (siRNA) targeting TSHR and the ICAM-1 monoclonal antibody (mAb) were designed and synthesized. Thirty GD model mice were randomly divided into siRNA treatment group, ICAM-1 mAb treatment group, and untreated GD group (10 mice in each group), and 10 normal mice were taken as blank control. Serum thyroxine (T 4), thyroid stimulating hormone (TSH), TSH receptor-stimulating antibody (TSAb) and TSH-stimulation blocking antibody (TSBAb) were measured before and after treatment. At the end of the treatment, body mass and heart rate of mice in each group were measured, and thyroid uptake of 99Tc mO 4-, thyroid size and pathological changes were evaluated. Independent-sample t test, paired t test and one-way analysis of variance were used to analyze data. Results:After three treatments, the body mass of mice in siRNA group and ICAM-1 mAb group were significantly lower than that of normal mice ( F=3.50, P=0.025); the heart rates of the mice in two groups were significantly lower than that of untreated GD mice ( F=24.73, P<0.001). Heart rate of mice treated with siRNA decreased significantly, close to that of normal mice. After treatment, the serum T 4((27.58±1.94) vs (65.71±6.89) μg/L, (27.24±3.50) vs (70.84±8.46) μg/L), TSAb ((331.44±43.38) vs (457.33±45.85) mU/L, (275.16±45.80) vs (443.91±42.32) mU/L) and TSBAb ((13.94±1.11) vs (15.83±5.92) mU/L, (14.59±1.02) vs (17.05±6.16) mU/L) levels of mice in both siRNA group and ICAM-1 mAb group significantly decreased ( t values: 4.45-10.87, all P<0.05), while the serum TSH levels of mice in two groups significantly increased ((0.13±0.05) vs (0.04±0.05) mU/L, (1.46±0.34) vs (0.06±0.03) mU/L; t values: -2.22, -5.87, P values: 0.007, <0.001). The elevated TSH level and decreased TSAb level of mice treated with ICAM-1 mAb were significantly different from those treated with siRNA ( t values: 1.03, -1.63, P values: 0.002, 0.031). After treatment, the uptake of 99Tc mO 4- in part of the thyroid lobes of mice was decreased, and the enlargement degree of the corresponding lobes was reduced. The thyroid pathology of mice in the treated groups showed that the absorption vacuoles of thyroid follicles were reduced, and the phenomenon of thinner colloids was improved. No obvious damage was observed in the heart, liver and kidneys of the mice. Conclusions:Both the siRNA targeting TSHR and ICAM-1 mAb have therapeutic effects on GD model mice. The siRNA is better at controlling heart rate, and ICAM-1 mAb is better at increasing TSH and decreasing TSAb. Each of the above treatment methods is safe and effective, which can provide new ideas for GD targeted therapy.

Objective:To investigate the therapeutic effect of levo-thyroxine ( L-T 4) gel on hypothyroidism in rat model. Methods:A total of 30 Wistar rats (15 males, 15 females, 2-month age) were completely randomized into 6 groups ( n=5 per group) with one group as the normal control and the other 5 groups were established as the hypothyroidism models by intraperitoneal injection of 18.5 MBq 131I. Of the 5 hypothyroidism groups, 3 groups were given 0.2 g (high-dose group), 0.1 g (medium-dose group) and 0.05 g (low-dose group) L-T 4 gel per 100 g body mass on alternate days, respectively, one group was given 0.1 g blank gel per 100 g body mass daily and the other group was given 5 μg levo-thyroxine sodium tablets (Euthyrox) per 100 g body mass daily. The levels of total thyroxine (TT 4), free triiodothyronine (FT 3), free thyroxine (FT 4) and thyroid stimulating hormone (TSH) in serum were determined by radioimmunoassay and chemiluminescence immunoassay at 2, 4 and 8 weeks after administration, respectively. One-way analysis of variance and Bonferroni test were used for data analysis. Results:At 2 weeks after administration, compared with the normal control group, TT 4, FT 4 decreased and TSH increased in the oral Euthyrox group (TT 4: (65.04±8.20) vs (40.34±1.41) nmol/L, FT 4: (29.63±4.03) vs (18.03±2.76) pmol/L, TSH: (6.04±0.80) vs (10.07±1.01) mU/L; F values: 60.081-108.128, t values: from -4.44 to 4.86, all P<0.05). However, TT 4 ((67.88±14.27) nmol/L), FT 3 ((4.04±0.84) vs (4.45±0.34) pmol/L), FT 4 ((33.76±7.71) pmol/L) and TSH ((8.20±0.40) mU/L) in the L-T 4 gel low-dose group showed no significant differences with the normal control group ( t values: 0.44-2.61, all P>0.05). At 4 weeks after administration, there were no significant differences of TT 4, FT 3, FT 4 and TSH between the L-T 4 gel low-dose group/the oral Euthyrox group and the normal control group ( F values: 34.527-90.976, t values: from -0.95 to 0.35, all P>0.05). The differences of TT 4, FT 3, FT 4 and TSH were not significant between the L-T 4 gel low-dose group and the oral Euthyrox group ( t values: from -0.71 to 1.03, all P>0.05), which was still not significantly different at 8 weeks ( F values: 47.239-160.679, t values: from -0.58 to 1.02, all P>0.05). Conclusions:L-T 4 gel has obvious therapeutic effect on hypothyroidism in rats. Its effect is fast and stable, and its therapeutic effect is better than L-T 4 sodium tablets (Euthyrox).

Objective:To explore the impact of urinary iodine concentration (UIC) on response to 131I treatment in differentiated thyroid cancer (DTC) patients with different risk stratifications. Methods:A total of 181 patients with DTC (75 males, 106 females, age: (44.1±12.5) years), who received the first 131I treatment in Tianjin Medical University General Hospital between January 2018 and February 2019, were retrospectively analyzed. Patients were divided into low- to intermediate-risk and high-risk groups. The treatment response was categorized into excellent response (ER) and non-excellent response (non-ER). Factors being evaluated including age, sex, preablative stimulated thyroglobulin (ps-Tg), UIC, etc. Mann-Whitney U test, χ2 test and logistic regression analysis were used for data analysis. Results:The UIC and ps-Tg in the low- to intermediate-risk group ( n=113) was 111.60(55.80, 204.65) μg/L and 2.08(0.63, 4.91) μg/L, respectively. Compared with the ER subgroup ( n=86), non-ER subgroup ( n=27) had higher UIC and ps-Tg level ( z values: -2.585, -4.511, both P<0.05). In the high-risk group ( n=68), UIC was 115.40(61.23, 167.28) μg/L and ps-Tg was 16.65(4.52, 43.45) μg/L. Compared with the ER subgroup ( n=20), non-ER subgroup ( n=48) had higher ps-Tg level ( z=-4.677, P<0.01), while the UIC was not significantly different between ER and non-ER subgroups ( z=-0.013, P>0.05). The multivariate logistic analysis indicated the ps-Tg level was the significant variable for non-ER in low- to intermediate-risk group (odds ratio( OR)=6.157(95% CI: 1.046-36.227); OR=22.965(95% CI: 3.591-146.857), both P<0.05) and high-risk group ( OR=9.696 (95% CI: 1.379-68.169), P<0.05); a high UIC could be an indicator of non-ER only in the low- to intermediate-risk group ( OR=3.715(95% CI: 1.201-11.488), P<0.05). Conclusions:The non-ER is associated with UIC in the low- to intermediate-risk group; however, UIC does not affect the non-ER in the high-risk group. Higher ps-Tg level is associated with non-ER in patients with low- to intermediate-risk and high-risk DTC.