Prevalence and outcome of headache in tuberculous meningitis
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* Sanjeev Kumar
* Rajesh Verma
* Ravindra K. Garg
* Hardeep S. Malhotra
* Praveen K. Sharma

## Abstract

**Objective:** To evaluate headache severity, and its correlation with clinical, cerebrospinal fluid, and neuroimaging parameters of tuberculous meningitis (TBM) patients, and its impact on outcome.

**Methods:** This prospective observational study was conducted at King George’s Medical University, Lucknow, India between October 2012 and March 2014. Ninety-five newly diagnosed TBM patients underwent detailed clinical, laboratory, and neuroimaging evaluation. A numeric rating scale was used to assess the headache severity, and patients were grouped into mild, moderate, severe, and intolerable groups. Patient outcome was evaluated at 6-months follow up.

**Results:** Holocranial stabbing type headache (*p*=0.002), modified Barthel index ≤12 (p<0.001), diplopia (*p*=0.055), seizures (p<0.001), visual impairment (*p*=0.024), cranial nerve palsy (*p*=0.002), meningeal signs (*p*=0.016), definite cases of TBM (*p*=0.001), British Medical Research Council stage III (p<0.001), and CSF protein >2.5 g/l (p<0.001) were significantly associated with severity of headache. Neuroradiological features significantly associated with severity of headache were meningeal enhancement (*p*=0.015), basal exudates (p<0.001), and hydrocephalus (*p*=0.003). Eleven out of 15 patients who died had intolerable headache at admission. Significant predictors of poor outcome in severe and intolerable headache groups were CSF protein>2.5g/L, cranial nerve palsies, paraparesis, and infarcts. Patients of the mild and moderate headache group were headache free at 6 months follow up with good outcome.

**Conclusion:** Severity of headache was associated with multiple clinical, CSF protein, and radiological factors. As intolerable and severe headache had an unfavorable impact on outcome, we could prognosticate the TBM patients on the basis of headache severity.

Tuberculosis is a major public health concern worldwide, and India is in one of the high endemic zones. The incidence of CNS tuberculosis is dependent on the prevalence of tuberculosis in the general population.1 Tuberculous meningitis (TBM) is the most common manifestation of CNS tuberculosis. It causes death, or serious disabilities in up to 51% of affected patients.2 The various manifestations and complications of TBM such as convulsion, cranial nerve palsy, delayed treatment, stroke, low Glasgow coma scale score, vision loss, and hydrocephalus were associated with poor outcome.2-5 Headache is one of the common symptoms in TBM. Headache incidence was found in most of series as ranging from 50-100% in TBM patients.3-7 Headache in chronic meningitis like TBM can be acute, subacute, or chronic. Headaches in these patients are due to involvement of the meninges and other inflammatory changes that produces hydrocephalus and stroke. These inflammatory changes may be irreversible, such as communicating hydrocephalus.5 These changes are the source of headache during the disease process, and may occur even after resolution of infection (post meningitic headache). In many developing and poor countries, there is poor availability of advanced imaging techniques, such as MRI, which provide minute details of changes in brain parenchyma as well as the meninges. Headache is closely associated with these changes. Therefore, severity of headache can be used as an indirect measure of these changes in the brain. In this prospective observational study, we assessed the predictive factors of severity of headache at presentation and during the course of illness. We also evaluated the impact of severity of headache on the outcome of the disease.

## Methods

We conducted this prospective observational study between October 2012 and March 2014 in the Department of Neurology, King George’s Medical University, Lucknow, Uttar Pradesh, India. Our institution is situated in a high endemic zone of tuberculosis, which covers more than 100 million of the population of North India. The Institutional ethics committee approved the study protocol. We obtained written informed consent from all patients, or from their legal guardians, before enrolling in the study. We used the international classification of headache disorder II for the classification of headache. We conducted the study according to the principles of the Helsinki Declaration.

### Inclusion criteria

Ninety-five new cases of TBM were included in the study. The presence of headache was the prerequisite for enrolment. These patients presented with signs and symptoms (combination of headache, fever, vomiting, neck rigidity, convulsion, or focal neurological deficit) and cerebrospinal fluid abnormalities (mononuclear cell pleocytosis, low glucose level, raised protein level) suggestive of TBM. Neuroimaging abnormalities like meningeal enhancement, basal exudates, hydrocephalus, tuberculoma, and infarction alone or in combination helped in the diagnosis of TBM. The diagnosis of TBM was made according to the consensus criteria as given by Marais et al.8 The patients were divided into definite, probable, and possible TBM as per this criterion.8 Patients were classified according to the British Medical Research Council (BMRC) stage criteria.9 Patients with stage I disease had a Glasgow Coma Scale score of 15 with no focal neurological signs; patients with stage II had signs of meningeal irritation with slight or no clouding of sensorium and minor neurological deficit (like cranial nerve palsies) or no deficit (Glasgow coma scale score 11-14), and patients with stage III had severe clouding of sensorium, convulsions, focal neurological deficit, and involuntary movements (Glasgow coma scale score less than 10).9

### Exclusion criteria

Patients with altered sensorium, HIV positive, or other causes for meningitis were excluded from the study.

### Laboratory investigations

A detailed clinical evaluation was carried out in all patients. The laboratory tests, including complete blood count, erythrocytes sedimentation rate, blood glucose, blood urea nitrogen, serum creatinine, electrolytes, liver function test, chest x-ray, and enzyme-linked immunosorbent assay for (HIV) were performed. The CSF microscopy and biochemical analysis were also performed. The CSF sediments were stained and cultured (Lowenstein-Jensen media) by standard methods for detection of mycobacteria. The CSF specimens were also tested for mycobacterial tuberculosis DNA by polymerase chain reaction (PCR).

### Headache severity assessment

A numeric rating scale (NRS) was used to assess the severity of headache. The NRS score range from zero to 10. Headache severity was categorized according to the number given by patients for their headache. Headache was categorized as no pain, mild, moderate, severe, and intolerable when scores were 0, 1-3, 4-6, 7-9, and 10.10 Headache was evaluated by administration of a headache questionnaire at the time of admission and during the follow up.

### Radiological assessment

A brain MRI with gadolinium contrast was performed in all patients with a Signa Excite 1.5 Tesla instrument (General Electric Medical Systems, Milwaukee, WI, USA). Two experienced neuroradiologists, unaware of treatment and patient outcome reviewed the images. The abnormal neuroimaging features noted were meningeal enhancement, basal exudates, tuberculoma, hydrocephalus (communicating or non-communicating), and infarcts.

### Treatment

All enrolled patients were treated according to the World Health Organization antituberculous regimen.11 Patients received 2 months of daily oral rifampicin (10 mg/kilogram), isoniazid (5 mg/kilogram), pyrazinamide (25 mg/kilogram), and intramuscular streptomycin (20 mg/kilogram; maximum, 1 g/day), followed by 7 months of rifampicin and isoniazid at the same daily doses.11 All patients received dexamethasone for 8 weeks. Patients were given 0.4 mg/kilogram body weight of intravenous dexamethasone per day, and then tapered off by 0.1 mg/kilogram every week. This was followed by oral treatment for 4 weeks, starting at a total of 4 mg/day and decreasing by one mg every week.12 Oral pyridoxine 20- 40 mg/day was given to all patients. In addition, 20% mannitol (1 gm/kg body weight/day in 4 to 6 divided doses; titrated to response) was given to patients with features of raised intracranial pressure. Antiepileptic drugs were used in patients who had seizures.

### Follow up

Patients were followed for a period of 6 months after initiation of treatment. Headache severity was assessed at the first, third, and at the end of the sixth month follow up using the NRS scale. Assessment of disability as per modified Barthel index (MBI) was carried out at baseline and at the end of the first, third, and sixth month of follow up. An MBI >12 at the end of 6 months was regarded as a good outcome, and ≤12 considered a poor outcome.

### Statistical analysis

The Statistical Package for Social Sciences, version 16 for windows (SPSS, Chicago IL, USA) and Microsoft Excel were used for statistical analysis. Predictors for headache severity were identified using univariate and multivariate analysis. Univariate analysis was performed using Chi-square test for categorical data. Relative risks with 95% confidence interval were calculated. For multivariate analysis, binary logistic regression was performed to assess the impact of individual predictors of headache severity. Statistical significance was defined at *p*<0.05, and the statistical analysis was two-tailed. The Kaplan-Meier survival curves for the length of time until occurrence of the poor outcome were calculated for the moderate and severe headache groups. The differences between the 2 groups were compared using the Log rank test.

## Results

During the study period, 124 patients meeting the criteria of TBM were admitted to our department, out of which 95 eligible patients were enrolled in the study. Reasons for exclusion of the other 29 patients are as shown in **Figure 1**.

![Figure 1](http://nsj.org.sa/https://nsj.org.sa/content/nsj/21/2/138/F1.medium.gif)

[Figure 1](http://nsj.org.sa/content/21/2/138/F1)

Figure 1 
Flow diagram of study participants among tuberculous meningitis patients assessed for headache severity.

### Baseline characteristics

The male:female ratio was 0.8. The mean age was 32±13.9 years, and the mean duration of symptoms was 78±54.8 days. Most of the patients had holocranial and throbbing type headaches. Other baseline details are summarized in **Table 1**. Headache was mild in 22 (23.2%), moderate in 22 (23.2%), severe in 35 (36.8%), and intolerable in 16 (16.8%). Most patients had a throbbing (46, 48.4%) headache, followed by sharp (20, 21.05%), stabbing (18, 18.95%), and tight band like (11, 11.6%). The most frequent location of headache was holocranial (57, 60%), followed by frontotemporal (16, 16.8%), frontal (13, 13.6%), fronto-parieto-temporal (5, 5.3%) and occipital (4, 4.2%) (**Table 2**).

View this table:
[Table 1](http://nsj.org.sa/content/21/2/138/T1)

Table 1 
Baseline characteristics among 95 tuberculous meningitis patients assessed for headache severity.

View this table:
[Table 2](http://nsj.org.sa/content/21/2/138/T2)

Table 2 
Character, location, and lateralization of headache in patients with tuberculous meningitis.

### Headache after 6 months

All patients with mild headaches became headache free at 6-month follow up. Out of 22 patients with moderate headache, only one still had headache, which was mild at the end of follow up. In the severe headache group, 5 (14.85%) became headache free, 4 (11.4%) died, and 26 (74.3%) had mild headache at the end of 6-months follow up. Out of 16 patients with intolerable type headaches, 11 (68.75%) died, 3 (18.75%) had mild headache, and 2 (12.5%) became headache free at end of follow up.

### Death or disability at 6 months

Fifteen (15.8%) patients died by 6 months follow up. In the severe headache group, 4 patients (11.4%) died. Out of 16 patients with intolerable type headaches, 11 (68.75%) died. Out of 80 patients who survived, 72 patients had good outcome (MBI >12), and only 8 patients had poor outcome (MBI ≤12).

### Predictors of severity of headache

On univariate analysis, holocranial throbbing type headache (*p*=0.002), modified Barthel index <12 (*p*<0.001), diplopia (*p*=0.055), seizures (*p*<0.001), visual impairment (*p*=0.024), cranial nerve palsy (*p*=0.002), meningeal signs (*p*=0.016), definite cases of TBM (*p*<0.001), advanced stage of TBM (*p*<0.001), and CSF protein >2.5 g/l (*p*<0.001) were associated with severity of headache. Neuroradiological features significantly associated with severity of headache were meningeal enhancement (*p*=0.015), basal exudates (*p*<0.001), and hydrocephalus (*p*=0.003) (**Table 3**). On binary logistic regression analysis, seizure (*p*=0.029), CSF protein >2.5g/L (*p*=0.027) and basal exudates (*p*=0.017) were significant predictors of headache severity. These predictors had high sensitivity (98%), specificity (93.2%), and positive predictive values (94.3%), for prediction of severe headache.

View this table:
[Table 3](http://nsj.org.sa/content/21/2/138/T3)

Table 3 
Significant predictors of headache severity on univariate analysis in tuberculous meningitis (TBM) patients.

### Outcome of tubercular meningitis after 6-months

On univariate analysis, factors associated with poor outcome were stabbing headache (*p*=0.006), cranial nerve involvement (*p*=0.009), hemiparesis (*p*<0.001), paraparesis (*p*<0.001), CSF protein >250 mg/dl (*p*=0.005), advanced stage (stage III) (*p*<0.001), and MBI <12 (*p*<0.001). On neuroimaging, infarct (*p*<0.001) was associated with poor outcome. On binary logistic regression analysis, cranial nerve involvement (*p*=0.003), paraparesis (*p*=0.006), CSF protein >250mg/ dl (*p*=0.025), and infarct (*p*=0.001) were associated with poor outcome.

The Kaplan-Meier survival curves for the length of time until occurrence of the poor outcome were calculated for the moderate and severe headache groups. The difference between the 2 groups was compared using the Log rank test. Results indicated a significant difference between the time to reach poor outcome between the 2 groups (log rank test *p*=0.004) (**Figure 2**).

![Figure 2](http://nsj.org.sa/https://nsj.org.sa/content/nsj/21/2/138/F2.medium.gif)

[Figure 2](http://nsj.org.sa/content/21/2/138/F2)

Figure 2 
Kaplan Meier survival curves in tuberculous meningitis patients with headache observed at the time of inclusion in the study.

## Discussion

In our study, all patients fulfilled the criteria for headache applied to lymphocytic meningitis.13 Headache severity was assessed according to the numeric rating scale.

Headache from infectious diseases originate mainly from meningeal inflammatory reactions, as the meninges are richly innervated by trigeminal nerves. The pathophysiology of the origin of headache in infectious disease is not well understood. Intracranial hypertension syndrome, chemical meningeal irritation, and direct activation of pain-producing structures through stimulation of the trigeminovascular system are all considered in the pathogenic mechanism of headache.14

After rupture of Rich foci in the subarachnoid space, tubercular bacilli spread into all potential spaces including the interpeduncular fossa, suprasellar, and prepontine cistern, leading to formation of exudates. These exudates spread along the meningeal covering of cranial nerves and blood vessels in subarachnoid spaces, which creates obstruction in the flow of CSF at the tentorial opening, causing hydrocephalus and increased intracranial pressure. The increased intracranial pressure causes stretching of the meninges (richly innervated by trigeminal nerves), and thus produces headache. Cytokines play a central role in the neuropathogenesis15,16 of tubercular granuloma17 formation, altered blood-brain barrier permeability, and CSF leukocytosis.18,19 Microglia and astrocytes in the brain produce different cytokines in response to bacterial infections. Tumor necrosis factor (TNF)-a, interleukin (IL) -6, IL-ß, CCL2, CCL5, and CXCL1020 are important cytokines associated with generation of pain,21 and inflammation.

In our study, we found a significant correlation between neuroimaging features and severity of headache. Forty-two (44.2%) patients had hydrocephalus, out of which 30 (71.4%) patients had severe (57.1%), and intolerable (14.3%) headache. Meningeal enhancement and basal exudates, which are markers of inflammation, are also associated with severity of headache. Out of 42 patients who had meningeal enhancement, 30 patients belong to the severe and intolerable category. Basal exudates were present in 38 patients, in which 34 (89.5%) had severe and intolerable headache.

In TBM, the basal exudates are usually most pronounced around the circle of Willis, and they produce a vasculitis like syndrome. Inflammatory changes in the vessel wall may be seen, and the lumen of these vessels may be narrowed or occluded by thrombus formation. The vessels most severely involved are those located at the base of the brain, which include the internal carotid artery, proximal middle cerebral artery, and perforating vessels. The most common site of infarction is around the Sylvian fissure and basal ganglia.

Infarction in tuberculous meningitis is because of vasculitic changes in the small arteries of the vertebrobasilar system and middle cerebral artery. Encircling of these vessels by exudates contributes to vasculitic changes and results in infarct.22 The basal ganglion, and the areas around the Sylvian fissure are the most common sites of infarction.16 Vasculitic changes in the brain are associated with headache. In our study, out of 13 patients who had infarct, 4 patients had severe, and 4 had intolerable headache.

Increased total leukocyte count (TLC), and protein in CSF is associated with a disrupted blood-brain barrier and is a marker of the inflammatory reaction. In our study, increased CSF protein, and TLC were significantly associated with severer headache.

Headache is a common symptom of tuberculous meningitis and is a component of the meningitis triad (fever, headache, and meningeal sign). Headache severity is influenced by many factors in tubercular meningitis like fever, seizure, meningeal sign, increased intracranial pressure, hydrocephalus, basal exudates, meningeal enhancement, and vasculitic changes. Some of these inflammatory changes in the brain parenchyma, as well as in the meninges, result in permanent fibrotic changes and these changes could be the generator of headache during the disease process as well as even after resolution of infection (post meningitic headache). In our study, meningeal enhancement, basal exudates, and hydrocephalus were significantly associated with severity of headache. Out of 51 patients with intolerable and severe headache, only 7 (19.4%) became headache free at the end of 6 months. These findings indicate a severe inflammatory reaction and permanent changes in the brain that produces episodic headache in the intolerable and severe headache group. Therefore, in patients of suspected tubercular meningitis, severity of headache can be used as marker of severe inflammatory changes in the brain if advanced neuroimaging techniques are not available. The mild and moderate headache group was associated with good outcome and most of the patients became headache free during 6-month follow up. One important limitation of our study was patients with TBM who presented to us with altered sensorium were excluded as they could not provide a proper account of their headache. This lead to the exclusion of 22 patients.

In conclusion, headache severity in patients with TBM is an important clinical tool for assessment of inflammatory changes in the brain in the absence of neuroimaging facilities, especially in poor countries, and these changes are associated with poor outcome. Patients with TBM with intolerable and severe headache are at increased risk of poor outcome; therefore, they should be monitored more carefully to avoid adverse clinical outcome. In our study, 30 patients had mild intensity headache at the end of 6-month follow up. Therefore, these patients should be followed for at least 3-months after completion of treatment for signs of post meningitic headache.

## Footnotes

*   Disclosure
    
    The authors declare no conflicting interests, support or funding from any drug company.

*   Received October 25, 2015.
*   Accepted January 13, 2016.


*   Copyright: © Neurosciences

Neurosciences is an Open Access journal and articles published are distributed under the terms of the Creative Commons Attribution-NonCommercial License (CC BY-NC). Readers may copy, distribute, and display the work for non-commercial purposes with the proper citation of the original work.

## References

1.  Garg RK (1999) Tuberculosis of the central nervous system. Postgrad Med J 75, 133–140.
    
    

2.  Hosoglu S, Geyik MF, Balik I, Aygen B, Erol S, Aygencel TG, et al. (2002) Predictors of outcome in patients with tuberculous meningitis. Int J Tuberc Lung Dis 6, 64–70.
    
    

3.  Sinha MK, Garg RK, Anuradha Hk, Agarwal A, Singh MK, Verma R, et al. (2010) Vision impairment in tuberculous meningitis: Predictors and prognosis. J Neurol Sci 290, 27–32.
    
    

4.  Anuradha HK, Garg RK, Agarwal A, Sinha MK, Verma R, Singh MK, et al. (2010) Predictors of stroke in patients of tuberculous meningitis and its effect on the outcome. QJM 103, 671–678.
    
    

5.  Raut T, Garg RK, Jain A, Verma R, Singh MK, Malhotra HS, et al. (2013) Hydrocephalus in tuberculous meningitis: Incidence, its predictive factors and impact on the prognosis. J Infect 66, 330–337.
    
    

6.  Singh B, Garg RK, Singh MK, Verma R, Malhotra HS, Jain A, et al. (2012) Computed tomography angiography in patients with tuberculous meningitis. J Infect 64, 565–572.
    
    

7.  Thwaites G, Fisher M, Hemingway C, Scott G, Solomon T, Innes J (2009) British Infection Society British Infection Society guidelines for the diagnosis and treatment of tuberculosis of the central nervous system in adults and children. J Infect 59, 167–187.
    
    

8.  Marais S, Thwaites G, Schoeman JF, Török ME, Misra UK, Prasad K, et al. (2010) Tuberculous meningitis: a uniform case definition for use in clinical research. Lancet Infect Dis 10, 803–812.
    
    

9.  British Medical Research Council (1948) Streptomycin treatment of tuberculous meningitis. BMJ 1, 582–596.
    
    

10. Breivik H, Borchgrevink PC, Allen SM, Rosseland LA, Romundstad L, Hals EK, et al. (2008) Assessment of pain. Br J Anaesth 101, 17–24.
    
    

11. World Health Organization (2010) Treatment of tuberculosis: guidelines (WHO, Geneva (CH)), 4th ed, Available from: [http://whqlibdoc.who.int/publications/2010/9789241547833_eng.pdf](http://whqlibdoc.who.int/publications/2010/9789241547833_eng.pdf). Accessed 17 October 2012.
    
    

12. Thwaites GE, Nguyen DB, Nguyen HD, Hoang TQ, Do TT, Nguyen TC, et al. (2004) Dexamethasone for the treatment of tuberculous meningitis in adolescents and adults. N Engl J Med 351, 1741–1751.
    
    

13. Headache Classification Committee of the International Headache Society (2004) Classification and diagnostic criteria for headache disorders, cranial neuralgias, and facial pain. Cephalalgia 24, 155–156.
    
    

14. Strassman AM, Raymond SA (1997) On the origin of headaches. Endeavour 21, 97–100.
    
    

15. Mastroianni CM, Paoletti F, Lichtner M, D’Agostino C, Vullo V, Delia S (1997) Cerebrospinal fluid cytokines in patients with tuberculous meningitis. Clin Immunol Immunopathol 84, 171–176.
    
    

16. Thwaites GE, Simmons CP, Than Ha Quyen N, Thi Hong Chau T, Phuong Mai P, Thi Dung N, et al. (2003) Pathophysiology and prognosis in vietnamese adults with tuberculous meningitis. J Infect Dis 188, 1105–1115.
    
    

17. Kindler V, Sappino AP, Grau GE, Piguet PF, Vassalli P (1989) The inducing role of tumor necrosis factor in the development of bactericidal granulomas during BCG infection. Cell 56, 731–740.
    
    

18. Sáez-Llorens X, Ramilo O, Mustafa MM, Mertsola J, McCracken GH Jr. (1990) Molecular pathophysiology of bacterial meningitis: current concepts and therapeutic implications. J Pediatr 116, 671–684.
    
    

19. Saukkonen K, Sande S, Cioffe C, Wolpe S, Sherry B, Cerami A, et al. (1990) The role of cytokines in the generation of inflammation and tissue damage in experimental gram-positive meningitis. J Exp Med 171, 439–448.
    
    

20. Rock RB, Hu S, Gekker G, Sheng WS, May B, Kapur V, et al. (2005) Mycobacterium tuberculosis-induced cytokine and chemokine expression by human microglia and astrocytes: effects of dexamethasone. J Infect Dis 192, 2054–2058.
    
    

21. Clark IA, Jacobson LS (1998) Do babesiosis and malaria share a common disease process? Ann Trop Med Parasitol 92, 483–488.
    
    

22. Misra UK, Kalita J, Maurya PK (2011) Stroke in tuberculous meningitis. J Neurol Sci 303, 22–30.