Hrev_master Veins and Lymphatics 2014; volume 3:4632 [Veins and Lymphatics 2014; 3:4632] [page 89] Internal jugular vein narrowing and body mass index in healthy individuals and multiple sclerosis patients Christopher Magnano,1,2 Pavel Belov,1 Jacqueline Krawiecki,1 Jesper Hagemeier,1 Robert Zivadinov1,2 1Department of Neurology, Buffalo Neuroimaging Analysis Center, School of Medicine and Biomedical Sciences, University at Buffalo, Buffalo, NY; 2MRI Clinical and Translational Research Center, School of Medicine and Biomedical Sciences, University at Buffalo, Buffalo, NY, USA Abstract Internal jugular vein (IJV) narrowing has been implicated in central nervous system (CNS) disorders. Body mass index (BMI) is a cardiovascular risk factor that has been also linked to CNS diseases, however it is unknown whether a relationship exists between IJV nar- rowing and BMI. The objectives were to assess the relationship between IJV cross-sectional areas (CSA) and BMI in healthy individuals (HI) and multiple sclerosis (MS) patients. A total of 388 subjects (194 age- and sex- matched HI and MS patients) received mag- netic resonance venography and structural brain magnetic resonance imaging at 3T. Region of interest analysis was performed using a semiautomated contouring-threshold- ing technique to determine the minimum CSA of the IJVs at C2/C3, C5/C6, and C7/T1 cervical levels. Partial correlation analyses were used to determine the associations. Increased BMI was related to increased IJV CSA at lower cer- vical levels (r=0.240, P<0.0001 at C5/C6 and r=0.293, P<0.0001 at C7/T1) in both MS patients and HI. Both MS and HI, showed asso- ciations between increased BMI and IJV CSA measures, particularly at lower cervical loca- tions, in individual group analyses. No differ- ences in association between BMI and IJV CSA were observed between HI and MS patients. Relationship between IJV CSA and BMI were not significant at upper cervical locations in the studied groups. Increased BMI is associat- ed with IJV CSA widening, rather than narrow- ing, at lower cervical levels in both MS patients and HI. This finding warrants further investi- gation, but indicates that BMI can obscure interpretation of IJV CSA narrowing. Introduction Blood is supplied to the brain and spinal cord by two sets of branches from the dorsal aorta.1 The vertebral arteries arise from the subclavian arteries, while the internal carotid arteries branch from the common carotid arteries.1 Deoxygenated blood is drained from the brain and spinal cord by the venous sys- tem, particularly the internal jugular veins (IJVs), which connect the sinuses to the vena cava.2,3 The cerebral venous system is consid- ered most important contributor for mainte- nance of adequate brain perfusion, in order to meet the metabolic needs necessary for nor- mal cerebral function.2 Venous drainage from the cerebral hemispheres consists of two sys- tems: the superficial, which drains blood from the cortex and superficial white matter by cor- tical veins, and is collected by the dural sinus- es;4 and the deep venous system, which con- tains approximately 70% of the total blood vol- ume, and incorporates small veins and venules for the majority of its composition.4 In contrast to the symmetric arterial system, the venous system is asymmetric and highly heteroge- neous.4 IJV morphology has previously been investigated with respect to aging and gender differences in healthy individuals (HI),5,6 in addition to a number of central nervous system (CNS) diseases, including multiple sclerosis (MS), Alzheimer’s disease and Parkinson’s disease.4 Numerous recent studies have focused on morphological and hemodynamic venous jugular flow abnormalities in MS patients and HIs.4,7-11 However, it is unknown at this time whether the IJV narrowing has any pathological significance, or is just a normal physiologic variant. Body mass index (BMI) is a standard meas- ure of degree of obesity. It is also a cardiovas- cular risk factor that has been linked to CNS diseases.12-15 We hypothesized that, as a result of obesity, we would find a reduced IJV cross- sectional area (CSA) due to venous constric- tion in subjects with large BMIs. Venous nar- rowing can be caused either directly due to intraluminal defects or hypoplasia, or as a result of blockages such as venous thrombosis.13,16 As BMI is linked with increased risk of CNS diseases, we expected to find more pronounced narrowing in a cohort of MS patients when compared with HIs. We were also interested to explore the cervical level at which CSA reduction would impact these asso- ciations. Therefore, we examined the relation- ship between the IJV CSA at three different cervical levels in healthy and diseased subjects with a spectrum of body mass indices. Materials and Methods Subjects This prospective, single-center, cross-sec- tional study included 388 subjects, with 194 consecutive HIs with no evidence of neurolog- ical disease and 194 consecutive relapsing remitting (RR) MS patients being enrolled (matching 1:1). Inclusion criteria included completion of magnetic resonance imaging (MRI) screening to ensure no MRI-prohibitive medical history. Cardiovascular risk factors were collected from all participants in-person by a trained interviewer with cross-examina- tion of medical records. All participants were assessed with a structured environmental questionnaire containing information about medical history (illnesses, surgeries, medica- tions, etc.), as well as cardiovascular risks, including history of hypertension, smoking, or heart disease (which was defined to include congestive heart failure, heart attack, arrhyth- mia, valvular disease, heart murmurs, enlarged heart, heart surgeries, palpitations, or any other category that would necessitate medical therapy). Height and weight were assessed to determine BMI. Physical and neu- rological examination were obtained in all study particpants. All subjects were required to meet the health screen requirements on phys- ical examination and history of known vascu- lar abnormalities also precluded enrollment in Correspondence: Robert Zivadinov, Department of Neurology, School of Medicine and Biomedical Sciences, Buffalo Neuroimaging Analysis Center, 100 High St., Buffalo, NY 14203, USA. Tel. 716.859.3579 - Fax: 716.859.4005. E-mail: rzivadinov@bnac.net Key words: healthy individuals, multiple sclero- sis, internal jugular veins, cross-sectional area, body mass index, magnetic resonance imaging, magnetic resonance venography. Conflict of interests: the authors declare no potential conflict of interests. Funding: RZ received funding for consultancy from Teva Pharmaceuticals, Biogen Idec., EMD Serono, Novartis, Sanofi-Genzyme. Received for publication: 29 July 2014. Revision received: 28 October 2014. Accepted for publication: 20 November 2014. This work is licensed under a Creative Commons Attribution 3.0 License (by-nc 3.0). ©Copyright C. Magnano et al., 2014 Licensee PAGEPress, Italy Veins and Lymphatics 2014; 3:4632 doi:10.4081/vl.2014.4632 No n c om me rci al us e o nly Article [page 90] [Veins and Lymphatics 2014; 3:4632] the study. HIs were recruited among hospital personnel and local advertisement respon- dents, while the MS patients were enrolled at the Center specialized for demyelinating dis- eases. All study experiments were performed in accordance with the relevant guidelines and regulations. The study was approved by the local Institutional Review Board, and informed consent was obtained from all subjects. Image acquisition All subjects were examined on a GE 3.0T Signa Excite HD 12.0 Twin Speed 8-channel scanner (General Electric, GE, Milwaukee, WI, USA) with a maximum slew rate of 150T/m/s and maximum gradient amplitude in each orthogonal plane. A 2-dimensional magnetic resonance venography (MRV) sequence was acquired for all IJV CSA measurements. The MRV was acquired with 150, 1.5mm-thick slices using a 320¥192 matrix (frequency x phase) with a 22.0 cm field of view (FOV) and a phase field of view (pFOV) of 75% for a resolution of .69¥1.15¥1.5 mm3. Additional imaging parameters included echo time (TE)/repeti- tion time (TR)/flip angle (FA) of 4.3 ms/14 ms/70°, and a bandwidth (BW) of 31.25 kHz, for a total acquisition time of 5:19 min. MRV was acquired in a true (non-obliqued) axial orientation with one average, and no parallel imaging techniques were employed. A 2-dimensional fluid-attenuated inver- sion-recovery (FLAIR) sequence was acquired for assessment of T2 hyperintense lesion pathology. FLAIR scans were 3-mm thick slices with no gap, TE/TI/TR=120/2100/ 8500 ms, flip angle=90°; with a 256¥256 matrix and a 25.6 cm FOV for an in-plane res- olution of 1x1 mm2 with a phase FOV of 75% and one average. Image analyses Cross-sectional area analyses IJV assessment was performed using CSA region of interest (ROI) analysis on the 2D MRV with the Java Image Manipulation Tool (JIM) version 5.0 (http://www.xinapse.com) at specific cervical locations blinded to the subjects’ status. Briefly, the sequence was viewed orthogonally to assess which slices corresponded to the desired anatomical cov- erage, namely C2-C3, C4, C5-C6, and C7-T1. Within each of these locations, the operator determined the slice on which the IJV came to a minimum, and then used the ROI Toolkit to select the right and left IJVs. Most com- monly, this was accomplished using the Contour ROI tool, using the automated Preview Contours tool to best select its edges. When necessary, the operator manual- ly adjusted the ROI boundary. Reproducibility was assessed using two operators performing CSA analysis on a set of 25 MRVs twice, with analyses a minimum of 2 weeks apart. Operators were blinded to each other’s ROI assessments, as well as to their own prior set of ROIs. Intra- and inter-operator repro- ducibility was assessed using the intra-class correlation (ICC), with corresponding P- and q-values. T2 hyperintense lesion determination T2-weighted hyperintense lesion number and volume were assessed using a semiauto- mated edge detection contouring/threshold- ing technique on FLAIR images.17 Statistical analysis Statistical analyses were performed using the Statistical Package for Social Sciences (IBM Inc, version 21.0). The demographic and clinical differences between genders were tested using Student’s t-test and chi-square tests. BMI and CSA measures were compared using partial correlation analyses. Group com- parisons were calculated using Student’s t- test. Due to multiple comparisons, only a nom- inal P-value<0.01, was considered statistically significant using two-tailed tests. Table 1. Demographic and clinical characteristics of healthy individuals and multiple sclerosis patients. Total (N=388) HI (N=194) MS (N=194) P-value Age° 42.6 (15.8) 44 43.0 (17.5) 46 42.2 (13.9) 43 0.629** Sex (M/F) 126/262 63/131 63/131 1.00** BMI 26.8 (5.7) 25.8 26.8 (5.7) 25.8 26.8 (5.8) 25.8 0.938** Heart disease 51/264 (16.2%) 20/142 (12.3) 31/122 (20.3) 0.074** Hypertension 57/263 (17.8%) 19/150 (11.2) 38/113 (25.2) 0.001* Smoking 132/205 (39.2%) 58/122 (32.2) 74/83 (47.1) 0.006* Number of subjects with 246/121 (67) 65/119 (35.3) 181/2 (98.9) <0.0001* T2° hyperintense lesions Number of T2° 15.4 (20.5) 7 2.8 (7.1) 0 28.1 (21.8) 22 <0.0001* hyperintense lesions Volume of T2° 5.79 (11.5) 0.581 0.248 (1.13) 0 11.4 (14.2) 5.84 <0.0001* hyperintense lesions (mL) Age° at onset N/A N/A 31.0 (12.8) 30.0 N/A Disease duration in years N/A N/A 12.0 (9.4) 10.0 N/A EDSS N/A N/A 2.5 (1.3) 2.0 N/A HI, healthy individuals; MS, multiple sclerosis; BMI, body mass index; EDSS- expanded disability status scale. P-values were calculated using Student’s t-test and chi-square tests: *P-values less than 0.01 considered significant; **P-values less than 0.05 were considered trends. °Age and T2 lesion characteristics are presented as mean (standard deviation) median. Categorical variables (cardiovascular risk factors) are #Yes/Total # (%). Table 2. Internal jugular vein cross-sectional area values and standard deviations in healthy individuals and multiple sclerosis patients across multiple cervical locations. All subjects HI MS P-value C7/T1 115.9 (73.2) 118.0 (79.3) 113.8 (66.6) 0.575 C5/C6 95.3 (58.5) 97.4 (60.2) 93.2 (56.7) 0.473 C2/C3 66.1 (29.4) 66.7 (31.4) 65.5 (27.2) 0.691 HI, healthy individuals; MS, multiple sclerosis. The cross-sectional area is expressed in millimeter square. Values reported are mean (stan- dard deviation). P-values were calculated using Student’s t-test and chi-square tests. Table 3. Association of internal jugular vein cross-sectional area and body mass index in healthy individuals and multiple sclerosis patients across multiple cervical locations. All subjects HI MS Age vs BMI 0.169 (0.002)* 0.062 (0.416)** 0.262 (0.001)* C7/T1 0.293 (0.000)* 0.294 (0.000)* 0.296 (0.000)* C5/C6 0.240 (0.000)* 0.247 (0.001)* 0.234 (0.002)* C2/C3 0.045 (0.411)** 0.078 (0.324)** 0.009 (0.909)** HI, healthy individuals; MS, multiple sclerosis; BMI, body mass index. Values reported are partial correlations (P-value). *P-values less than 0.01 considered significant; **P-values less than 0.05 were considered trends. No n c om me rci al us e o nly Article [Veins and Lymphatics 2014; 3:4632] [page 91] Results Demographic characteristics Demographic characteristics are presented in Table 1. HI and MS subjects were age- and sex-matched. As expected, significant differ- ences were found between HIs and MS sub- jects in terms of cardiovascular risk factors, smoking, and number and volume of T2 hyper- intense lesions. BMI was not significantly dif- ferent between the study groups. The MS patients were on disease-modifying treatment including interferon b 1a, glatiramer acetate and natalizumab. Reproducibility of the cross- sectional area measurement Inter- and intra-operator reproducibility was found to be highly significant with strong ICC values and corresponding P-values (ICC>0.69 for inter-operator with P<0.001, and ICC>0.84 for intra-operator, with P<0.001 at all levels and for all operators). Internal jugular vein cross-sectional area morphology IJV CSAs was greater at lower cervical lev- els, ranging from a mean of 66.1 mm2 at C2/C3 to115.9 mm2 at C7/T1. Breakdown at each level is shown in Table 2. Cross-sectional area correlations with body-mass index As shown in Table 3, greater IJV CSA was strongly correlated with increased BMI (r≥0.234, P≤0.002 for all) at lower cervical lev- els (C5/C6 and C7/T1), whereas this associa- tion was not detected at upper cervical levels (C2/C3 nor C4). The association was signifi- cant in all subjects, as well as individually in HI and MS patients groups. There were no differ- ences between the study groups, as the associ- ations were similar in terms of strength and significance, irrespective of disease status (Tables 2 and 3; Figure 1). Age interaction with cross-section- al area association with body-mass index As shown in Table 3, BMI was associated with age in all subjects (r=0.169, P=0.002) and in MS patients (r=0.262, P=0.001). BMI was not associated with age in HI (r=0.062, P=0.416). However, the BMI and IJV CSA asso- ciation was found to be age independent in partial correlation analysis, across all groups (data not shown). Figure 1. Associations between body mass index (BMI) and cross-sectional area at levels C7/T1 (A, B, C), C5/C6 (D, E, F), and C2/C3 (G, H, I). No n c om me rci al us e o nly Article [page 92] [Veins and Lymphatics 2014; 3:4632] Discussion We investigated the association of IJV CSA on MRV with BMI in MS patients and HIs, and found a relationship between the two at the lower cervical levels, independent of any age effects. Findings were similar in both HIs and MS patients, suggesting that this relationship is independent of the disease state. While our initial hypothesis was that IJV narrowing would be associated with increased BMI, actually the results showed the opposite; namely, that as the BMI increased, so did the IJV CSA. These findings suggest that the more obese a subject is, rather than narrowing, their IJV CSA is actually enlarging. This could be due to the fact that, assuming a constant vol- ume of blood to pump, that more obese sub- jects will thus have lower flow rates, although our study was limited to only structural and did not include functional outcomes. As subjects with larger BMIs tend to be more sedentary and less mobile, their oxygen demand will decrease, and thus both their oxygen supply via arterial blood, as well as deoxygenated clearance via the venous system, will decrease, leading to reduced flow rates. While our hypothesis was that the location of vascular assessment would play a role in IJV CSA, this was only true to a point: C5/C6 and C7/T1 had a similar relationship with BMI, whereas C2/C3 did not. We suspect that this may be due to the fact that there is a high degree of heterogeneity at upper cervical levels (C2-C3), as evidenced by the increased preva- lence of collaterals. Since the correlations between IJV CSA and BMI seem to be indica- tive of total flow at lower levels (where the vast majority of venous flow is drained through the IJVs), it is possible that the exclusion of addi- tional venous collateral assessment could be confounding our results at upper cervical lev- els. Therefore further exploration is warranted regarding this issue. Age and BMI were associated across the entire cohort and in the MS patients, but not in the HIs. However, we speculate that the fact that BMI and CSA relationship was age inde- pendent in HI, suggests that the age depend- ence of BMI in MS patients may be due to decreased level of activity, rather than strictly age, and would warrant further study. While we also investigated differences in association between IJV CSA and BMI between MS patients and HI, none was observed, con- sistent with other groups’ findings.18-20 This suggests that CSA and BMI measures are unrelated to the disease status. Any differ- ences are most likely functional (i.e. flow-relat- ed) rather than structural (i.e. due to morphol- ogy). This study was limited in scope to struc- tural assessment of the IJVs; flow quantifica- tion can provide additional information, as other groups are currently investigating. Additionally, our study had several other lim- itations. The focus on the IJV CSA neglected any collateral flow; future work should examine col- lateral vein measures, particularly at upper cer- vical locations. It would be also interesting to examine the level of activity, in order to explore how this affects the relationship between IJV CSA and BMI in MS and HIs. This work only examined the minimum CSA at each cervical location, and an automated analysis of the CSA at each slice would offer a more volumetric approach. Moreover, only RR MS patients were enrolled in the study, in order to allow age- matching with HI. 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