Multiple sclerosis,an unlikely cause of chronic cerebrospinal venous insufficiency: retrospective analysis of catheter venography

Introduction

The aim of this study was to evaluate a potential role for multiple sclerosis (MS) in the development of venous malformations. It has recently been revealed that MS, a chronic disease of the central nervous system, is often associated with chronic cerebrospinal venous insufficiency. Chronic cerebrospinal venous insufficiency is a unique venous pathology, which is comprised of stenoses and occlusions in extracranial veins draining the brain and spinal cord. ^{1 9} The discovery of chronic cerebrospinal venous insufficiency has shed new light on a potential pathogenesis of MS.^10-12 Presently, however, it remains unknown if a relationship exists between the two pathologies and, importantly, if chronic cerebrospinal venous insufficiency is a causal factor for MS or a product of MS. Even so, one could expect that if MS is the cause of chronic cerebrospinal venous insufficiency, then patients with an extended history of the disease would present with a more severe venous pathology.

Patients and methods

This survey was part of a clinical trial on endovascular treatments for chronic cerebrospinal venous insufficiency. The entire study was designed to assess safety and efficacy of endovascular procedures performed to alleviate venous outflow blockages in the main veins draining the central nervous system. The study was approved by the Bioethical Committee of the Regional Silesian Board of Physicians in Katowice, Poland (approval number 7/2010). The study was registered at ClinicalTrials.gov, identifier NCT01264848.

All patients provided written consent to undergo the procedures and tests. A total of 353 MS patients were evaluated who, previously, using Doppler sonography and magnetic resonance venography, had been diagnosed with chronic cerebrospinal venous insufficiency. The patients’ ages ranged from 15 to 70 years, with a median age of 43 years. The patients had suffered from MS for 0.5–41 years, with a median duration of the disease of 10 years. Catheter venography was performed under mild sedation and local anaesthesia. The details of the venographic protocol can be found in our previous paper. ⁴ The following anatomical structures were evaluated: the internal jugular veins, the brachiocephalic veins and the azygous vein. The following venographic flow patterns were categorized into four grades and were regarded as abnormal:

To evaluate correlations between the venous outflow pathology and the duration of the disease, the degree of venous abnormalities was measured in three ways:

All clinical data (age, duration of the disease) were obtained from the history of the patients. The scoring of venous lesions using the above scale was performed by one of the authors who was not performing the venography, and this assessment was done exclusively basing on the movies recorded during the venography procedures.

Statistical analysis involved the evaluation of correlations between the duration of MS history and the degree and number of venous lesions. To assess the strength of these correlations, Spearman and Kendall's tau correlation coefficients were calculated. A correlation coefficient value below 0.4 was considered to represent a weak correlation. Also, statistical significances of the coefficients were calculated. The significance of the P values was set at P > 0.05.

Results

We obtained weak correlations between the severity of chronic cerebrospinal venous insufficiency measured by the number and degree of venous lesions and the duration of MS. For the cumulated scores of venous lesions, Spearman and Kendall's tau correlation coefficients were 0.03 and 0.02, respectively; for maximal scores of venous lesions, the coefficients were 0.06 and 0.05, while the coefficients for the number of diseased veins were 0.007 and 0.006, respectively. Further statistical analysis did not reveal any significance (P > 0.05) of these correlations. Consequently, the analysis did not yield any data supporting the idea that MS is the cause of chronic cerebrospinal venous insufficiency. The details of the data are presented in Figures 1–3.

OPEN IN VIEWER

Figure 1

Duration of MS compared with cumulated scores of venous lesions; P values for correlation coefficients are >0.05 (Spearman's rank coefficient test = 0.63, Spearman's permutation test = 0.63, Kendall tau rank coefficient test = 0.59, Kendall tau permutation test = 0.63)

OPEN IN VIEWER

Figure 2

Duration of MS compared with maximal scores of venous lesions; P values for correlation coefficients are >0.05 (Spearman's rank coefficient = 0.27, Spearman's permutation test = 0.28, Kendall tau rank coefficient test = 0.19, Kendall tau permutation test = 0.27)

OPEN IN VIEWER

Figure 3

Duration of MS compared to number of diseased veins; P values for correlation coefficients are >0.05 (Spearman's rank coefficient test = 0.90, Spearman's permutation test = 0.91, Kendall tau rank coefficient test = 0.87, Kendall tau permutation test = 0.91)

Discussion

In this study using catheter venography for the assessment of chronic cerebrospinal venous insufficiency, there were no correlations observed between the duration of MS and the severity of venous pathology. Thus, the results were in contrast to the idea of a neurological pathology being the primary cause for the development of the vascular lesions.

The use of catheter venography, which at the moment has been regarded as gold standard for the assessment of vascular pathologies, can be seen as the strong point of our study. However, it has been weakened by our scale for the grading of chronic cerebrospinal venous insufficiency, ⁴ which is not yet widely accepted. Also, there were additional limitations to our study. It should be noted that our study has only been an indirect evaluation of a hypothetical clinical course of MS based on an analysis of a big cohort. Also, we were unable to rule out a potential selection bias (i.e. our patient cohort did not represent the authentic random sample of MS patients). Moreover, the sensitivity of diagnostics and the grading of chronic cerebrospinal venous insufficiency could potentially contain errors, especially in the cases of the azygous vein lesions. However, a relatively large number of evaluated patients have potentially contributed to the minimization of some of the above-presented biases.

Vascular specialists, as stated in the Consensus Document of the International Union of Phlebology on the diagnosis and treatment of venous malformations, have interpreted chronic cerebrospinal venous insufficiency as vascular malformations of congenital origin. ¹³ On the contrary, the neurological community has been rather sceptical about the interpretation from the vascular specialists. There have been published reports that deny the existence of chronic cerebrospinal venous insufficiency,^14,15 but these studies appear to be improperly designed. ¹⁶

Alternative studies were published that tried to resolve the dilemma between the primary vs. secondary nature of chronic cerebrospinal venous insufficiency by studying patients with clinically isolated syndrome (CIS).

In a study by Yamout et al., ¹⁷ the authors had found that the patients with CIS, a neurological syndrome that does not meet the criteria of MS, but can precede MS, have low prevalence of chronic cerebrospinal venous insufficiency (9%), while 92% of clinically overt MS patients present with venous abnormalities. Therefore, the data from Yamout et al. support the secondary nature of chronic cerebrospinal venous insufficiency and assumes that chronic cerebrospinal venous insufficiency may develop due to the action of proinflammatory agents released by a diseased brain or brain atrophy. However, Yamout et al. have assessed a number of patients: 11 patients have CIS and 13 have late-stage MS. ¹⁷ In addition, the venographic criteria of chronic cerebrospinal venous insufficiency chosen by Yamout et al. appear to be debatable. Similarly, Baracchini et al. assessed 50 patients with CIS by Doppler sonography and found chronic cerebrospinal venous insufficiency flow patterns in 16% of the patients, while less severe sonographic abnormalities are even more common (52% of the patients). ¹⁸ Also the authors explained that the venous pathology is secondary to MS. Although the studies contained weak arguments, the results cannot be ignored; however, the results could be interpreted differently. It has been known that only 30–70% of the CIS cases progress to MS. ¹⁹ Thus, it is possible that only patients with clinically silent chronic cerebrospinal venous insufficiency could progress into MS. In addition, it is known that many healthy individuals can demonstrate disturbances of venous outflow through the internal jugular veins, ²⁰ leading to the unlikely possibility that cerebral atrophy is the cause of chronic cerebrospinal venous insufficiency.

In our study, we attempted to resolve the problem of primary vs. secondary nature of chronic cerebrospinal venous insufficiency by an alternate method. The endovascular treatments for chronic cerebrospinal venous insufficiency were preceded by the detailed assessment of the treated veins primarily by means of catheter venography. This preprocedural evaluation, in addition to obvious clinical information, provides additional data that can be used to better understand the phenomenon of venous malformations in MS. Our analysis focused on the correlations between the duration of MS and the characteristics of venous lesions. Statistical analysis of the lesion parameters could potentially answer the following question: can inflammation or other processes associated with MS influence the severity of chronic cerebrospinal venous insufficiency (i.e. is chronic cerebrospinal venous insufficiency a product of MS). If this result was observed, then one can expect more severe and numerous lesions in the patients with a longer history of the disease; however, no correlation was observed between the duration of the history of MS and the degree of chronic cerebrospinal venous insufficiency. Consequently, the results of our survey indicated that the venous malformations were most likely congenital and that MS did not appear to have a significant impact on the degree and progression of the venous pathology.

However, the possibility that a neurological process could play a role in the progression of chronic cerebrospinal venous insufficiency cannot be completely excluded, even if our analysis did not confirm such a scenario (e.g. due to the limitation of our diagnostic methods). It should be expected that a vasoactive substance (e.g. endothelin-1 ^{21 24} or another vasoconstrictor) rather than a proinflammatory substance could be a causal factor. It could be possible that a vasoactive agent would act on a previously susceptible segment of blood vessel (i.e. on a preclinical malformed venous valve; the most common location of chronic cerebrospinal venous insufficiency pathology). For example, it has been known that in aortic valve stenosis, endothelin-1, a potent vasoconstrictor, plays a role in the progression of the disease.^25,26 Alternatively, one could hypothesize that inflammatory and neurodegenerative processes within nervous parenchyma and the impairment of venous outflow should act together to result in clinically overt MS. This hypothetical scenario would explain the phenomenon why many healthy individuals that present with chronic cerebrospinal venous insufficiency have no obvious clinical consequences. Undoubtedly, these uncertainties should be revealed by ongoing studies.