8-hydroxydeoxyguanosine as a useful marker for determining the severity of trichloroethylene exposure.

The aim of this study was to determine 8-hydroxydeoxyguanosine (8-OH-dG) levels in trichloroethylene (TCE)-exposed workers. Oxidative stress biomarkers and biochemical parameters were monitored among 26 TCE-exposed workers and 78 age-matched control subjects. Levels of urinary 8-OH-dG were analyzed by liquid chromatography tandem mass spectrometry. Urinary 8-OH-dG levels were significantly higher for TCE-exposed group (p < .001). Spearman's correlation test revealed positive correlations between urinary trichloroacetic acid levels and age, urinary 8-OH-dG, urinary total oxidant status, and urinary total antioxidant status (p = .042, p < .001, p < .001, and p < .001, respectively). 8-OH-dG may be a useful marker to determine the extent of TCE exposure.

Increased serum interleukin-33 levels in patients with Graves' disease.

OBJECTIVE: Interleukin-33 (IL-33), a 30 kDa cytokine, is a member of IL-1 family. It is considered to be an autoimmune biomarker associated with T helper 2 (Th 2) response. γ-interferon is also produced by T helper 1 (Th 1) cells to induce cellular responses. γ-interferon is a 143-amino acid residue glycoprotein with several biological functions including potent anti-viral activity, stimulation of macrophage activity, modulation of Major Histocompatibilty Complex class I/class II expression, and regulation of a diversity of specific immune responses. The aim of this study was to investigate the serum levels of IL-33 and γ-interferon in different thyroid disorders. METHODS: Twenty patients with Graves' disease, 21 patients with Hashimoto hypothyroidism, 21 euthyroid Hashimoto patients, and 27 control subjects were recruited to this study. Blood samples were drawn and IL-33 and γ-interferon tests were analyzed from 89 participants. Serum IL-33 and γ-interferon analyses were performed by enzyme-linked immunosorbent assay. RESULTS: There was no statistically significant difference between groups for serum γ-interferon levels. Serum IL-33 concentrations were significantly higher in Graves' disease group compared to the other groups (p<0.000) There was a positive correlation between serum IL-33 and free triiodothyronine (fT3) and thyroxine (fT4). Also, negative correlation between serum IL-33 and thyroid-stimulating hormone (TSH) was statistically significant (p<0.000). CONCLUSIONS: The correlation of serum IL-33 with thyroid hormone levels may be a useful indicator for Graves' disease. These findings may help to make evident the pathophysiologic processes of the autoimmune thyroid diseases and improve therapeutic methods. .

Biological variation and reference change values of CA 19-9, CEA, AFP in serum of healthy individuals.

OBJECTIVE: The use of tumour markers in diagnosis and monitoring is very common. Tumour marker results vary - preanalytical sources of variation, total random analytical error (CV(a)), and within-subject (intraindividual) normal biological variation. There are not so many studies evaluating the biological variations and reference change values (RCV) of these parameters. The aim of our study was to assess: (i) the average inherent intra- and inter-individual biological variation (CV(i) and CV(g)) for CA 19-9, CEA, AFP in a group of healthy individuals; (ii) the significance of changes in serial results of each marker; and (iii) the index of individuality. MATERIAL AND METHODS: The study group comprised 49 healthy volunteers ranging in age between 18 and 60 years (25 M and 24 F). Four blood samples were obtained from each subject; one at each 14-day interval. Each sample from one individual was assayed in duplicate. CA 19-9, CEA, AFP levels were measured by an immunoluminometric assay on a random-access analyser (Architect i2000; Abbott Diagnostics Division). The intra- (CV(i)) and inter-individual (CV(g)) biological variations were estimated from the data generated. Reference change value (RCV) was calculated. RESULTS: The intra-individual/inter-individual biological variations (CVs) for CA 19-9, CEA, AFP were 27.2/64.24 %, 30.87/37.14 % and 26.67/43.65 %, respectively. The critical differences (RCVs) of CA 19-9, CEA, AFP were 64.71 %, 72.57 % and 62.62 %, respectively (Z = 1.65 for unidirectional changes; p<0.05). CONCLUSIONS: Intra-individual biological variation contributes to the variation in serial results and should therefore be included in the criteria for serum tumour marker assessment.

The effects of thyroid status on serum apolipoprotein A-I-containing lipoprotein particles.

Alterations of lipid profile are a well-known phenomenon in thyroid dysfunction. However, little is known about the influence of thyroid hormone on Lp A-I and LpA-I:A-II particles. We have, therefore, studied LpA-I and LpAI:A-II concentrations in a group of 20 patients with hyperthyroidism and in a group of 15 patients with hypothyroidism before and one month after attainment of euthyroidism. In hypothyroid patients, LDL-cholesterol and apo B concentrations decrease significantly after L-T4 replacement treatment (from 4.49+/-2.51 to 2.76+/-0.70 mmol/ L, P=0.036 and from 89.4+/-16.1 to 78.3+/-13.3 mg/dL, P=0.05, respectively), whereas no significant change was observed in the total cholesterol, HDL-C, LpA-I, LpA-I:A-II and apo A-I concentrations. In hyperthyroid patients, total cholesterol (from 3.58+/-0.72 to 4.74+/-1.39mmol/L, P=0.0025), HDL-C (from 1.19+/-0.23 to 1.41+/-0.27mmol/L, P=0.0084), LDL-C (from 1.83+/-0.69 to 2.96+/-1.20 mmol/l, P=0.0025), apo A-I (from 85.6+/-12.5 to 91.7+/-18.1 mg/dL, P=0.05) and apo B (from 52.7+/-8.2 to 65.6+/-16.5 mg/dL, P=0.0013) increased after restoration of euthyroidism while triglycerides, LpA-I and LpA-I: A-II concentrations were unchanged. LpA-I and LpA-I:A-II concentrations were not related to thyroid hormones in both groups. Our study suggests that LpA-I and LpA-I:A-II particles are not under the direct control of thyroid hormones.

Lipoprotein(a) concentration in subclinical hypothyroidism before and after levo-thyroxine therapy.

Subclinical hypothyroidism is a frequent disorder in populations and has been shown to be a risk factor for coronary heart disease (CHD). Less is known about the contribution of lipoprotein (a) [Lp(a)] to the development of CHD in this disorder. Therefore this study was designed to evaluate Lp(a) and other lipoprotein concentrations before and after L-T4 therapy in 20 patients with subclinical hypothyroidism and 20 normal healthy subjects matched for sex, age and BMI. In the basal state of subclinical hypothyroidism, a significant increase in total cholesterol, LDL-cholesterol and apolipoprotein (apo) B concentrations was observed in patients compared with those in the control group. The mean Lp(a) concentration before treatment was 163 +/- 15 mg/L. This is slightly but not significantly higher than those in the control group (131 +/- 15 mg/L). Treatment of subclinical hypothyroidism with a low dose of L-T4 (25 micrograms daily) for 3 months after restoration of euthyroidism led to decreases in levels of Lp(a) from 163 mg/L to 126 mg/L (23% reduction, P < 0.001), total cholesterol from 5.5 mmol/L to 5.1 mmol/L (7% reduction, P < 0.001), LDL-cholesterol from 4.14 mmol/L to 3.63 mmol/L (12%, P < 0.001), and apo B from 98 mg/dL to 86 mg/dL (12% reduction, P < 0.05), but triglyceride, HDL-cholesterol and apo A-I concentrations were unchanged. These data suggest that L-T4 replacement therapy in patients with subclinical hypothyroidism has beneficial effects on the lipid profile since L-T4 replacement therapy lowered the concentrations of Lp(a) and other atherogenic lipid particles.

Comparison of the effects of aminoguanidine and L-carnitine treatments on somatosensorial evoked potentials in alloxan-diabetic rats.

The effects of aminoguanidine (AG) and L-carnitine (LC) on somatosensorial evoked potential (SEP) latency and neural levels of thiobarbituric acid reactive substances (TBARS), products of lipid peroxidation, were compared in alloxan-diabetic rats. AG and LC were given to diabetic rats starting from the 3rd week after the induction of diabetes and lasting for 4 weeks. SEP latency was measured by stimulating via caudal nerve and recording via cortex, once weekly during the treatments. Diabetes caused deficits in SEP (P < 0.05 vs non-diabetic control rats, respectively). AG and LC restored SEP latencies slightly but not significantly, with the exception of the prominent effect of AG at the first week and both treatments at the 4th week of the treatments (P < 0.05 vs untreated diabetic rats, respectively). Diabetes caused elevation in neural TBARS levels (P < 0.05 vs non-diabetic group), which was prevented by both AG and LC (P < 0.05 vs untreated diabetic rats, respectively). Weight and the glucose levels were not influenced by the treatments. Our results suggest that AG improves SEP latencies better than LC. Our results also suggest that the beneficial effects of both AG and LC on diabetic neuropathy are not associated with the regulation of glycemia, but these effects may be related in part with prevention of lipid peroxidation.

Effects of gonadotropin and testosterone treatments on Lipoprotein(a), high density lipoprotein particles, and other lipoprotein levels in male hypogonadism.

It is known that lipoprotein(a) [Lp(a) is an independent risk factor for developing atherosclerosis, whereas the LpA-I particle of high density lipoprotein (HDL) is an antiatherogenic factor. The effects of androgen replacement therapy on lipid and lipoproteins have previously been reported in male hypogonadism. However, no study reported the effect of gonadotropin or testosterone treatment on Lp(a), LpA-I, or LpA-I;A-II levels in make hypogonadism. We, therefore, determined Lp(a), LpA-I, LpA-I:A-II, and other lipoprotein levels before and 3 months after treatment in 22 patients with idiopathic hypogonadotropic hypogonadism (IHH) and in 9 patients with Klinefelter's syndrome. All patients had been previously untreated for androgen deficiency. Plasma FSH, LH, PRL, testosterone (T), estradiol, and dehydroepiandrosterone sulfate levels were also determined before and 3 months after treatment. Patients with IHH were treated with hCG/human menopausal gonadotropin, whereas patients with Klinefelter's syndrome received T treatment. Three months after treatment, mean T levels role to low normal levels in both groups. Triglyceride, LpA-I:A-II, Lp(a), HDL cholesterol, HDL3 cholesterol, and apolipoprotein (apo) A-I concentrations did not change significantly after treatment, whereas total cholesterol, low density lipoprotein cholesterol, LpA-I, and HDL2 concentrations were significantly increased 3 months after treatment in both groups. The apo B concentration significantly increased in patients with klinefelter's syndrome, whereas no change was observed in the IHH group. Lp(a) concentrations were not related to all hormonal and clinical parameters in both groups. LpA-I concentrations were significantly and negatively correlated with free T (r = -0.80; P = 0.010) in patients with Klinefelter's syndrome and were not correlated with all hormonal and clinical parameters in the IHH group. The LpA-I:A-II concentration was only correlated with body mass index (r = -0.83; P = 0.005) in patients with Klinefelter's syndrome, whereas it was correlated negatively with dehydroepiandrosterone sulfate (r = -0.57; P = 0.005) in the IHH group.2 Overall, our study demonstrates that gonadotropin or T treatment has a complex effect on lipids and lipoproteins. This complexity will be resolved when sufficient large scale androgen treatment data are available for assessment of the long term outcome of androgen treatment. The increases in total cholesterol and low density lipoprotein cholesterol concentrations after treatments are the adverse effects of these treatments, whereas the increases in HDL2 and LpA-I concentrations and the lack of changes in Lp(a) are the beneficial effects. Gonadotropin or T treatment did not modify the Lp(a) concentration, indicating that it is not affected by the hormonal milieu in male hypogonadism. Our study also showed that LpA-I, but not LpA-I:A-II, particles could be modified by androgen replacement therapy.

Biological variation of serum lipids and lipoproteins in patients with clinically well controlled non insulin dependent diabetes mellitus.

To investigate how the visit-to-visit variation in serum lipids measurements affects the decision making concerning treatment according to the National Cholesterol Education Program (NCEP) guidelines in patients with clinically well controlled non-insulin-dependent diabetes mellitus (NIDDM) we have measured the biological variation (CVb) in serum total cholesterol (TC), triglycerides (TG), high density lipoprotein cholesterol (HDL-C) and low density lipoprotein cholesterol (LDL-C) in 26 patients with NIDDM. We found the CVb as follows: TC, 5.1%; TG, 17.0%; HDL-C 4.4% and LDL-C, 8.3%. Confidence intervals (95%) were determined with total intra-individual variance values around the NCEP cut-off points to evaluate how well one, two and three lipid measurements provided reliable risk classification. A single TC measurements < 177 mg/dL or > 263 mg/dL allowed confident classification as "desirable" or "high risk" respectively. For LDL-C, one measurement was accurate only at below 106.3 mg/dL or above 183.7 mg/dL. The average of three measurements contracted these limits to < 186.7 mg/dL and > 253.3 mg/dL for TC, and < 116.3 mg/dL and > 173.7 mg/dL for LDL-C. For HDL-C also, multiple measurements improved risk assignment in a similar fashion. There were no values which allowed assignment to the "borderline high" category with one TC measurement and with one and two LDL-C measurements. The mean of three TC and three LDL-C measurements allowed assignment to the "borderline high" category, if between 213.3 and 226.7 mg/dL for TC, 143.7 and 146.3 mg/dL for LDL-C. Seven patients (26.9%) in this risk group based on the mean of two LDL-C estimates could be placed into a different category when the mean of three estimates was taken, even though the first two LDL-C test results did not differ by more than 30 mg/dL. Our results suggest that repeated lipid measurement is important especially for the "borderline-high" risk group because big variations existed in some patients, and further that TC is the most reliable quantity.