In normal circumstances, almost 80% of cerebral blood volume is located in venous structures; despite this, cerebral venous thrombosis (CVT) is much less prevalent than ischaemic stroke, representing only 0.5% to 1% of cases of cerebrovascular disease.1 Its incidence is estimated between 3 and 4 cases per million population, with higher rates in neonates and young children (7 cases per million).2

The main features differentiating it from arterial disease include its predominance among younger patients and women, with the latter being linked to specific aetiological aspects associated with female sex, such as pregnancy, puerperium, and the use of oral contraceptives (OC).3–5

Another characteristic trait of venous cerebrovascular disease is the great anatomical variability of the venous system, with imprecise venous drainage, especially in the superficial system. Cerebral veins and dural sinuses lack valves or tunica layers, which affords them great compensatory capacity in the event of thrombosis. Furthermore, the presence of multiple anastomoses between cortical veins facilitates collateral circulation in thrombosis of the superficial system.

All these peculiarities of the venous system result in significant heterogeneity in the clinical presentation of CVT, which will depend on the localisation, extension, and rapidness of onset, as well as on the effectiveness of collateral circulation.6,7 Thus, extensive involvement, which especially affects the deep venous system, is associated with higher risk of a poor progression, whereas focal involvement of the superficial system may lead to paucisymptomatic forms.8

The low incidence of this disease also makes it difficult to perform epidemiological studies and largely hinders the performance of randomised clinical trials that might clarify current uncertainties associated with such important aspects as therapeutic management.9 Therefore, more information is still needed on the reality of this entity in each territory.

The main aim of the MOTIVATE study (abbreviation for the project’s Spanish name “management of cerebral venous thrombosis in Spain”) is to perform a descriptive analysis of the clinical characteristics of patients with CVT in different Spanish centres, and to reveal the most important aspects of its diagnosis and treatment in the Spanish setting. As secondary objective, we aimed to identify the most relevant prognostic factors in our series.

We performed a retrospective, descriptive, multicentre study in Spain, including 11 centres from the following autonomous communities: Andalusia (Hospital Torrecárdenas), Aragon (Hospital Clínico Lozano Blesa and Hospital Miguel Servet), Asturias (Hospital Central de Asturias), the Basque Country (Hospital de Donostia), Catalonia (Hospital de la Santa Creu i Sant Pau, Hospital Clínic Barcelona, and Hospital Dr. Josep Trueta), and the region of Madrid (Hospital Clínico San Carlos, Hospital de La Princesa, and Hospital Ramón y Cajal).

We included a total of 256 patients. Fig. 1 shows the distribution of data from the different centres.

Figure 1.

Participation of the different centres in the study.

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Neuroimaging diagnosis of CVT

Regarding diagnostic tests, 236 patients (92%) underwent a simple CT scan. CT scans and MRI studies with venography were performed in 107 (42%) and 201 (78.5%) of cases, respectively. Only 36 patients (14%) underwent arteriography. Radiological signs indicative of CVT were identified in 60% of CT scans and 43% of MRI studies. Table 2 shows a summary of the data from radiological diagnostic studies. Regarding anatomical location, we identified involvement of 2 or more sinuses or veins in 66.4% of patients, with the superior longitudinal sinus (SLS, 12.5%) and the transverse sinus (TS, 11%) being the most frequently affected (Fig. 2).

Table 2.

Diagnostic variables in the study population.

	%
Neuroimaging diagnostic studies
Simple head CT scan	92.0
Contrast head CT scan	56.0
CT venography	42.0
MRI venography	78.5
Arteriography	14.0
Radiological signs in head CT scan
Empty delta sign	28.5
Hyperdensity of the affected sinus	22.0
Hyperdensity of cortical veins	2.0
Oedema	2.0
Haemorrhage	13.0
Venous infarction	6.6
Multiple signs	17.5
No relevant signs	36.0
Radiological signs in brain MRI
Lack of signal in the affected sinus	23.0
Hyperintensity of the affected sinus	19.0
Oedema	0.0
Haemorrhage	2.0
Venous infarction	1.3
Multiple signs	33.0
No relevant signs	21.5
Radiological signs in arteriography
Absence of intramural sinus/vein/defect	9.8
Thrombosis of the deep system	1.2
Venous congestion	0.8
Multiple signs	2.3
Thrombosis localisation
Superior longitudinal sinus	12.5
Transverse sinus	10.9
Cavernous sinus	3.5
Straight sinus	2.0
Cortical vein	3.9
Jugular vein	0.8
2 or more sinuses or veins	66.4

Figure 2.

Frequency of involvement of cerebral sinuses and veins in the study population.

Adapted from Mawet J, Crassard I, Bousser M.G. Thromboses veineuses cérébrales. EMC (Elsevier Masson SAS, Paris), Traité de Médecine Akos, 5-0885, 2010.

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CVT is very probably the least understood cerebrovascular disease. This is largely due to its low prevalence, as a result of which the available data are limited, and are mainly based on small studies from single centres or individual countries. To date, our study presents the largest patient sample from Spain; among previous studies, we may highlight the International Study on Cerebral Vein and Dural Sinus Thrombosis (ISCVT),10 a prospective observational study that included 624 patients from 21 countries and 89 centres, providing highly valuable epidemiological information and establishing differences between the different populations studied. These differences are aetiologically significant with regard to countries of lower socioeconomic levels, according to the observations of other authors.11,12

The first noteworthy finding from our study is the similar percentage of men and women affected by this condition, contrasting with the findings described to date, which show a clear predominance of female patients, especially at younger ages. According to Lanksta et al.,13 the risk of CVT is 3.7 times greater in women aged 15 to 24 years than in those aged between 25 and 34 years. This percentage is supported by other studies that have identified a greater risk in young women.14 Therefore, a possible explanation for our findings may be the mean age of our sample, which was close to 50 years, long after childbearing age, which is associated with conditions predisposing to CVT.15–17

In our study population, the most frequently detected risk factors were smoking, overweight, and the use of OC. The risk factors described in the literature have gradually changed in recent years. Previously, infectious causes were more frequent, whereas thrombophilia, neoplasms, and the use of OC are more frequently described today.18,19 Furthermore, risk increases proportionally in these patients in the event of overweight and obesity.20 Smoking, which was not assessed in the ISCVT, is very significant in our study, with almost 25% of patients being smokers.

The most frequent forms of presentation were acute (55%) and subacute (32%). These data are similar to those of the VENOST study, which included 1144 patients from Turkey.21 From a pathophysiological perspective, this type of presentation, which is disguised in some cases, may be attributed to the progressive growth of the thrombus, enabling collateral circulation. Regarding the clinical picture, headache was the most frequent symptom at onset, with focal symptoms presenting in a slightly higher percentage than in other studies.21 Epileptic seizures (33%) and encephalopathy (55 patients [21.5%]) were also frequent, though at slightly lower rates than those reported in the ISCVT (40% and 36% respectively).10 Mental symptoms as the form of presentation are usually more frequent in older patients, with headache being the least frequently reported in this age group.22

The prognostic value of the anatomical location of CVT is well-known, as symptom severity depends on the affected vessel and progression time.7 In our series, the SLS was the structure most frequently affected in isolation, followed by the TS; the majority of patients presented multiple involvement. Whereas rates of involvement of the SLS and TS were similar to those described in the literature, the involvement of multiple sinuses was less frequent.23 The anatomical preference for the SLS may be explained by the turbulent blood flow resulting from the drainage of superficial cortical veins, which would be intensified in the lower part by the presence of fibrous walls.24

Regarding the neuroimaging diagnosis of this condition, both CT and MRI are able to detect the direct and indirect signs of CVT. Simple non-contrast CT scans are usually the initial examination performed in patients with suspected CVT, although in up to 25% to 30% of cases it does not yield relevant findings.25 In our series, the great majority of patients initially underwent a simple CT scan, and somewhat more than half were administered a contrast agent (56%). MRI was performed in 78.5% of cases, probably due to suspicion after a simple or contrast CT scan, to confirm diagnosis or to better characterise CVT and its complications, in line with the results of other authors.26 Among the radiological findings, the most common was the empty delta sign, detected in almost one-third of patients, followed by hypodensity of the venous sinus; for both findings, the prevalence observed was similar to that reported in the literature (30%).27 However, CT detected no specific sign in more than one-third of patients in our study, with findings classified as normal, similarly to the results of other authors ( 25%–30% )25,26; this percentage decreased when brain MRI studies were performed.28 In our series, venous infarction was detected in only 6.6% of patients with CT, and in 3 cases with MRI; however, haemorrhagic lesions were detected in 33 patients with CT.

A noteworthy finding in our series is the high number of cases with a delayed diagnosis, due to both the lack of perception of severity and the lack of initial diagnostic suspicion. Thus, only a third of patients consulted a physician during the first 2 hours, and almost half were diagnosed beyond the first 24 hours. These data illustrate the diagnostic challenge of this condition, and the risk of underdiagnosis.29,30 In this line, determination of D-dimer level before neuroimaging in patients with suspected CVT may be useful, except in those with isolated headache or with long symptom progression times (> 1 week), which are associated with false negatives.30,31

With regard to treatment, the guidelines recommend early anticoagulant therapy; however, there is no consensus regarding the type and duration of antithrombotic therapy. In our series, 34% of patients received LMWH at therapeutic doses, and 26% received UFH. Once the acute phase is resolved, oral anticoagulants are indicated in the absence of any contraindication.32 In our series, it is striking that only 21% of patients were subsequently treated with dicoumarol anticoagulants, assuming that the remaining patients continued receiving other antithrombotic therapies. In terms of treatment duration, a 3-month period is considered sufficient if CVT is associated with a transient risk factor; in other circumstances, with greater risk of recurrence, the duration of anticoagulation may be 6 to 12 months, or even indefinite.33 In our study, indefinite treatment durations were indicated in 23% of patients due to thrombophilic alterations; in similar percentages of patients, treatment was maintained for 3–6 to 12 months.

There is controversy regarding cases of CVT with venous infarction and a haemorrhagic component, which may be exacerbated by anticoagulant treatment. Few studies have been performed that clarify this question, although a meta-analysis of 2 small randomised studies observed a 13% absolute reduction in mortality, without an increase in the appearance of new haemorrhagic lesions; these results were not statistically significant.34 Despite this, the conclusions were similar to the results observed in clinical practice: an improvement associated with heparin treatment. In the prospective cohort of the ISCVT,10 with previous intracranial bleeding in almost 40% of cases, 83% of patients received heparin without poorer prognosis.

Currently, the role of endovascular treatment in CVT is poorly defined. In our study, only 13 patients received endovascular treatment. The main reasons that may explain its limited use are the inherent risk of this treatment, and the doubts regarding criteria for indication, which have been growing since the publication of a clinical trial that did not find a benefit. Therefore, such techniques are reserved for cases of neurological impairment with poor prognosis under medical treatment.35 This lack of a benefit, contrary to the findings reported in the context of arterial ischaemia, may be due to the technical difficulty of achieving persistent venous recanalisation, especially in the superficial system.

In our study, overall mortality and the rate of disability at 3 months were lower than those described by other authors.10 The prognosis of CVT has improved over the last decades due to 2 factors: a decrease in infectious pathology and an increase in the diagnostic accuracy of current neuroimaging techniques, enabling earlier diagnosis and treatment. However, special emphasis has been placed on subtle sequelae. Some studies have reported that up to one-third of patients with CVT did not return to work, especially among women and patients with parenchymal lesions.

Regarding factors associated with mortality, we observed a statistically significant association with older age, ophthalmoparesis, and encephalopathy, as well as involvement of the cavernous sinus and of multiple sinuses simultaneously. Factors associated with poorer prognosis (mRS score > 3 at 3 months) were again age, variables associated with increased intracranial pressure, and venous infarction. In a German multicentre study performed in neurocritical care units, such factors as clinical impairment at admission, midline shift, and age predicted poorer prognosis.36 In this line, clinical scales of CVT severity have been published to predict prognosis, such as that designed by Barboza et al.,37 which showed an accuracy of almost 92% in predicting mortality at 30 days and 85% for predicting mRS scores > 2.

Our study presents some relevant limitations. The first is its retrospective character, which entails a significant risk of losing data due to the inability to obtain all variables in all cases. The second would be the lack of centralised assessment of neuroimaging studies, which makes it difficult to obtain information of greater quality and interest. Another limitation is the participation of centres of different levels of care; although this enables a broader perspective of the management of this disease in the Spanish setting, it also increases the heterogeneity of the treated cases.

The MOTIVATE study is the largest multicentre study performed in Spain, with the participation of hospitals from all corners of the country. It includes a large patient sample, despite the low incidence of this condition, and provides relatively recent data for a prolonged period of time. We therefore believe that the study provides an approximate and representative image of the actual situation of CVT in Spain in recent years.

The management of CVT in Spain presents significant variability from the diagnostic and therapeutic perspectives, as well as delays in seeking medical care, on the part of patients, and in diagnosis, by physicians. Our results identify favourable prognostic data but considerable areas for improvement, and suggest the need for greater homogeneity in the management of this severe but treatable condition. Prognostic markers enabling identification of patients at higher risk should be better defined in a national, multicentre prospective registry of CVT, with a view to improving the management of this condition based on experience obtained in real clinical practice.

This study has not received financing from any sources.

The authors have no conflicts of interest to declare.