TURKISH JOURNAL OF ONCOLOGY

Summary

OBJECTIVE
Several studies have shown that increased risk of venous thromboembolism (VTE) with hormonal contraceptives is mediated through the sex hormone-binding globulin (SHBG) through different pathways. Assuming SHBG as surrogate marker for hormonal stimulus as an increasing risk factor for VTE, we investigated if background SHBG has any impact on VTE in patient with advanced stage adenocarcinoma. Blood drawn from patients with VTE (n=45) and from patients without VTE (non-VTE; n=23), as a control group without a history of VTE, and SHBG levels were compared between groups. There was no difference in SHBG levels between VTE (59.7±41.5) and non-VTE (60±49) (p=0.71) group, but gastric cancer patients had statistically higher SHBG levels (73.7±39.9; range from 36.6 to 176.2 ) than rest of the cohort (56.54±44.4; range from 9.6 to 246.6) (p=0.033), although it was out of scope of this study. Although our study did not show any impact of SHBG levels on risk of VTE at patients with advanced stage adenocarcinoma, it revealed high levels of SHBG at gastric cancer patients which deserve further research.

METHODS
Blood drawn from patients with VTE (n=45) and from patients without VTE (non-VTE; n=23), as a control group without a history of VTE, and SHBG levels were compared between groups.

RESULTS
There was no difference in SHBG levels between VTE (59.7±41.5) and non-VTE (60±49) (p=0.71) group, but gastric cancer patients had statistically higher SHBG levels (73.7±39.9; range from 36.6 to 176.2 ) than rest of the cohort (56.54±44.4; range from 9.6 to 246.6) (p=0.033), although it was out of scope of this study.

CONCLUSION
Although our study did not show any impact of SHBG levels on risk of VTE at patients with advanced stage adenocarcinoma, it revealed high levels of SHBG at gastric cancer patients which deserve further research.

Summary

Introduction

Sex hormone binding-globulin (SHBG) is a carrier glycoprotein produced in the liver and binds the steroid sex hormones (testosterone and 17β-estradiol).[1] SHBG serum levels increase dose dependently on estrogen intake but decrease after the administration of progesterone and can be viewed as an indicator of total estrogenicity.[2] Several studies have shown that increased risk of venous thromboembolism (VTE) with hormonal contraceptives is mediated through the SHBG through different pathways. It has been demonstrated that SHBG levels were positively correlated with acquired activated protein C (APC) resistance among combined oral contraceptive (COC) users.[3,4] In addition, there is a positive correlation between SHBG and thrombin generation that increases the predisposition for VTE,[5] in the absence of APC resistance among users of hormonal contraceptives.[6] Consecutive evidence suggest that SHBG may be used as a biomarker in assessing prothrombotic profile of hormonal contraception. European Medicines Agency recommends SHBG measurements for the assessment of prothrombotic profile in the development of combined hormonal contraceptive.[7] However, SHBG serum levels are not only determined solely by estrogenicity but also associated with age, gender, body mass index, diabetes, hyperthyroidism, liver disease, and genetic variants of SHBG gene.[8] Recently, researchers identified that high serum SHBG would be a biomarker for early gastric cancer.[9]

SHBG can be easily and rapidly measured in routine laboratories and may be useful to asses prothrombotic profile and further validation with more studies as biomarker in gastric cancer. Assuming SHBG as surrogate marker for hormonal stimulus as an increasing risk factor for VTE, we herein sought to elucidate if background SHBG has any impact on VTE in patient with advanced stage adenocarcinoma.

Introduction

Methods

Patients
This is a retrospective case?control study including patients 18 years and older with histologic diagnosis of adenocarcinoma followed by Istanbul Bilim University Department of Medical Oncology between October 2007 and April 2012. Among 1845 patients, 99 (5.4%) experienced VTE. The diagnosis of VTE was confirmed by radiology and the patients were treated accordingly. We defined VTE according to their sites as deep venous thrombosis (DVT), pulmonary embolism (PE), other vascular territories (subclavian, jugular, superior vena cava, and iliac veins) (OVTs), and central venous catheter related (CVC-R). Blood drawn from patients with VTE (n=45) at any time, during active treatment or follow-up and any stage of cancer, and from patients without VTE (non-VTE; n=23), as a control group without a history of VTE during at least a 29-week duration after cancer diagnosis which is the median time from diagnosis to VTE in our cohort.

SHBG levels were compared between groups. All the laboratory analyses held in the Department of Biochemistry, Haseki Research and Training Hospital. The study protocol approved by the Local Ethics Committee of Haseki Research and Training Hospital, and written informed consent was obtained from all patients before inclusion into the study. The study granted by Tez ve Akademik Calısmalar Danısma ve Izleme Komisyonu, which is research support organization of Haseki Research and Training Hospital.

Assay of SHBG
Venous blood samples were collected in tubes from the antecubital vein, followed by overnight fasting. The tubes were centrifuged at 4000 rpm (10 min) to remove the serum. The serum samples were stored at -80°C until analysis SHBG. We used in vitro diagnostic reagent for the quantitative determination of SHBG in human serum by means of chemiluminescent immunoassay on Beckman Coulter Access Systems. (Beckman Coulter, Inc., 250 S. Kraemer Blvd., Brea, CA 92821 U.S.A.). The access SHBG assay is a sequential twostep immunoenzymatic ("sandwich") assay. A sample is added to a reaction vessel along with paramagnetic particles coated with monoclonal anti-SHBG antibody and saline buffer with proteins. After incubation in a reaction vessel, materials bound to the solid phase are held in a magnetic field while unbound materials are washed away. A second monoclonal anti-SHBG antibody conjugated to alkaline phosphatase is added to the reaction vessel. After the second incubation in the reaction vessel, materials bound to the solid phase are held in a magnetic field while unbound materials are washed away. Then, the chemiluminescent substrate Lumi-Phos* 530 is added to the vessel and light generated by the reaction is measured with a luminometer. The light production is directly proportional to the concentration of SHBG in the sample. The amount of analyte in the sample is determined from a stored, multipoint calibration curve. Reference unit was nmol/L.

Statistical Analysis
Descriptive statistics were reported as percentages and medians with standard deviations. The Chi-square test was used for the comparison of categorical variables. Student's t-test and Mann-Whitney U-test were used for the comparison of means. P<0.05 was considered statistically significant. Statistical analyses were performed with the use of SPSS version 17 (SPSS Inc., Chicago, Illinois, USA).

Methods

Results

There was no statistically significant difference in demographics variables. Sixty-eight patients, 35 of them women, aged between 37 and 80 are evaluated. At VTE group, 19 (42%) had PE, 18 (40%) had (DVT), 4 (9%) had CVC-R, and 4 (9%) had OVT. Frequencies of cancer sites for VTE and non-VTE group were colorectal 20 (29%), gastric 13 (19%), pancreatic 11(16%), breast 10 (15%), lung 6 (9%), and 8 (12%) other (prostatic 3, hepatobiliary 2, unknown primary 2, and ovarian 1) (Table 1). Thirteen (37%) women were younger than 50 years old and SHBG levels were not different between males (mean±SD; 63.6±53.6) and females (56.3±32.4) (p=0.98). There was no difference in SHBG levels between patients experienced VTE (59.7±41.5) and patients without VTE (60±49)(p=0.71), but gastric cancer patients (n=13, 11 with a history of VTE) had statistically higher SHBG levels (73.7±39.9; range from 36.6 to 176.2 ) than rest of the cohort (n=55) (56.54±44.4; range from 9.6 to 246.6) (p=0.033), although it was out of scope of this study.

Table 1: Characteristics of patients with adenocarcinoma (n=68) with and without VTE

Results

Discussion

The association between cancer and venous thrombosis was first described in 1823 by Bouillard[10] and in 1865, Trousseau,[11] later coined as Trousseau's syndrome. Almost all patients with active cancer have some degree of the activation of coagulation cascade[12] resulting 4-7-fold increased risk of VTE than general population[13] and making it an important cause of death in patients with cancer.[14] Even after adjusting for stage, cancer patients with thrombosis have 2-fold increased risk of mortality compared with cancer patients without.[15,16] Patients with adenocarcinoma are generally considered to more prone to developing VTE duo to the high frequency of adenocarcinoma in patients with thrombosis. A large cohort study of lung cancer showed that the risk of VTE was 20-fold higher in lung cancer patients than in general population (standardized morbidity ratio: 20 [14.6-27.4]), and within the cohort, adenocarcinoma was associated 3-fold increased risk compared to patients with squamous cell carcinoma (crude adjusted hazard ratio 3.1, 95% CI% 1.4-6.9).[17] Likewise, emerging evidence let to investigators develop a predictive model for chemotherapy-associated VTE, which citing as very high risk of primary cancer site for stomach and pancreatic adenocarcinoma.[18] Carcinoma mucins, interacting with selections, propagate platelet-rich thrombus without thrombin generation and suggest a fluid-phase coagulation-independent mechanism for Trousseau's syndrome thus provides a rationale for its frequent association with mucin-rich adenocarcinomas.[19,20] However, mechanism of this coexistence needs to be more explored.

Our results demonstrated that SHBG did not differ in patients with adenocarcinoma with VTE and without VTE indicating that hormonal stimulus or background hormonal milieu did not have any impact on increased risk of VTE in patient with advanced stage adenocarcinoma. The plasma levels of SHBG are the sum of multiple stimulatory and inhibitory factors. Women show decreasing level of SHBG between the second and sixth decades followed by a steady increase at around 60 years, a U-shaped trajectory, whereas men show an increasing levels with age.[21] There is now overwhelming evidence that both, estrogen-containing postmenopausal HRT and COCs is associated with clinically important increased risk of VTE, higher the estrogen content higher the risk, dose dependently. [22] At present, clear explanation for the correlation between the changes in SHBG level and thrombin generation and APC resistance induced by COCs does not exist. Hormonal contraceptives, which are metabolized in the liver, might interfere with the synthesis of procoagulant and anticoagulant factors and SHBG, which are produced in the liver.[6] Our results indicate that cancer-related thrombosis process does not have mutual pathways with hormonal mechanisms.

Tissue factor (TF) expression by cancer cells, which is the most likely explanation of procoagulant activity in cancer patients, is shown to be started at early stages carcinogenesis with the activation of MET oncogene. [23] In the Khorana scoring model for chemotherapyassociated VTE, pancreatic cancer cited as a "very highrisk" tumor type[18] which is reported to express high levels of TF.[24] Lately, Hingorani et al.[25] confirmed the hypercoagulability of pancreatic cancer emphasizing role of TF in VTE in advanced adenocarcinoma. In this Phase II trial, patients with advanced stage pancreatic adenocarcinoma were randomly allocated to treatment with pegvorhyaluronidase alfa (PEGPH20), which degrades hyaluronan, with nab-paclitaxel/gemcitabine (PAG) versus nab-paclitaxel/gemcitabine (AG). However, high rate of (43%) thromboembolic events (TEs) in PAG arm led to exclusion of patients with TE events in PAG arm, andand initiation of prophylactic use of enoxaparin. With the enoxaparin initiation, TE events were 14% in PAG and 10% in AG arms.

In a recent study by Cheng et al.,[9] plasma SHBG levels have been identified and suggested as a potential early diagnostic biomarker for gastric cancer. Although it was out of scope of this study, gastric cancer patients had statistically higher SHBG levels (73.7±39.9; range from 36.6 to 176.2) than rest of the cohort (56.54±44.4; range from 9.6 to 246.6) (p=0.033). In this case, SHBG needs to be identified if it is the smoke or the fire.

Although to the best of our knowledge, this is the first study sought to elaborate relationship between SGBG and thrombosis in adenocarcinoma, retrospective nature of study inherent limitations. We are aware and acknowledge that caution required interpreting results when a candidate surrogate marker like SHBG is studied, as they can be severely misleading, hence, its levels are affected by many dependent end independent factors. One other limitation of our study relates to the relatively small population sample.

In conclusion, SHBG levels were not different in cancer patients with VTE compared to controls without VTE. Our study cannot totally exclude the possible association between VTE and SHBG levels in gastric cancer.

Acknowledgment: The author thanks to the sponsor of the study, Tez ve Akademik Calismalar Danisma ve Izleme Komisyonu (TACDIC), which is research support organization of Haseki Research and Training Hospital.

Peer-review: Externally peer-reviewed.

Conflict of Interest: All authors declared no conflict of interest.

Ethics Committee Approval: The study was approved by The Haseki Research and Training Hospital Ethics Committee (No: 2, Date: 20/05/2013).

Financial Support: This study has received financial support from Tez ve Akademik Calismalar Danisma ve Izleme Komisyonu (TACDIC), which is research support organization of Haseki Research and Training Hospital.

Discussion