Volume 9, Issue 2 (March & April 2018 2018)                   BCN 2018, 9(2): 73-86 | Back to browse issues page


XML Print


Download citation:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:

Saberi A, Roudbary S, Ghayeghran A, Kazemi S, Hosseininezhad M. Diagnosis of Meningitis Caused by Pathogenic Microorganisms Using Magnetic Resonance Imaging: A Systematic Review. BCN 2018; 9 (2) :73-86
URL: http://bcn.iums.ac.ir/article-1-1060-en.html
1- Neurosciences Research Center, Department of Neurology, Pouursina Hospital, School of Medicine, Guilan University of Medical Sciences, Rasht, Iran.
2- Department of Neurology, Poursina Hospital, School of Medicine, Guilan University of Medical Sciences, Rasht, Iran.
3- Deputy of Research and Technology, Guilan University of Medical Sciences, Rasht, Iran.
Full-Text [PDF 1698 kb]       |   Abstract (HTML) 
Full-Text:  
1. Introduction
Bacterial meningitis as a Central Nervous System (CNS) infection is a life-threatening disease. Pyogenic meningitis has a substantial risk of neurologic squeal leading to poor prognosis (Abe, Takayama, Yamashita, Noguchi, & Sagoh, 2002). In some instances, in spite of successful use of antibiotics, major neurologic complications occur (Jan et al., 2003). Meningitis is not frequent (1% of primary hospital admissions and 2% of nosocomially acquired infections), but it requires prompt diagnosis and specific treatment because of its high mortality and morbidity (Griffin, 1997; Kanamalla, Ibarra, & Jinkins, 2000; Johnson, 2000). Different pathogens cause CNS infection and bacterial meningitis. Overall, Streptococcus pneumoniae is the most prevalent cause and the others, including Neisseria meningitidis, group B Streptococcus and Listeria monocytogenes have lower frequencies in order (Leedom & Underman, 2000; Schuchat et al., 1999).
Diagnosis of meningitis is based on clinical and laboratory findings like Cerebral Spinal Fluid (CSF) analysis as a gold standard method (Lummel et al., 2016). In this regard, nothing could replace CSF analysis. And even if in some cases, it could be difficult to obtain cerebrospinal fluid, it is always possible and necessary to retrieve these samples by other means such as radio- or ultrasound-guided lumbar puncture. But to save the time and when another paraclinical method is available, it is useful to start treatment and save the patients’ life. Although antibiotic treatment changes the pattern of CSF, delaying in treatment will result in high rate of mortality and morbidity. 
Different Magnetic Resonance Imaging (MRI) modalities with respect to different sequences include sequences of Fluid Attenuated Inversion Recovery (FLAIR), Diffusion-Weighted Imaging (DWI), and T1-weighted enhanced with gadolinium. They are invaluable imaging techniques for diagnosis of complications of meningitis such as empyema, abscess, vasculitis, and infarction. Nowadays MRI has been suggested for diagnosis of meningitis itself even without any complication. Of course the determined sensitivities in different studies are very variable. Lummel et al. believed that the different severity of inflammation and the etiology of meningitis would result in different sensitivity of MRI in diagnosis of meningitis (Lummel et al., 2016).
The clinical usefulness of selective tissue suppression using inversion recovery pulse sequences has been extensively documented in the literature. Recently, Fluid Attenuated Inversion Recovery (FLAIR) MR, Diffusion Weighted Imaging (DWI) and Diffusion Tensor Imaging (DTI) techniques have been advocated for imaging patients with acute meningitis (Melhem et al., 1997). The nullification of the high signal of CSF in FLAIR occurs by the inversion recovery pulse which comes an inversion time. The elevation in protein and cellular concentration decrease T1 relaxation time of CSF, thus changing its null point. This leads to hyperintensity in the affected CSF, which can easily be detected by FLAIR (Adams & Melhem, 1999).
Reduced water diffusion in DWI appears as increased signal intensity and in its related Apparent Diffusion Coefficient (ADC) maps as decreased signal intensity (Noguchi et al., 1999; Guo, Provenzale, Cruz, & Petrella, 2001), like what appears in intracerebral abscess (Kim et al., 1998; Noguchi et al., 1999). There are different theories which explain the hypersignality of the CSF space seen by DWI in meningitis which are described as following (Abe et al., 2002). Diffusion Tensor Imaging (DTI) is one of the MRI modalities which shows the disturbance of white matter integrity based on the change in diffusion anisotropy. Although expensive, it can be used along with other non-contrast MRI modalities in assessing meningitis, because the periventricular white matter seems to be influenced by change in CSF composition (Malik et al., 2008). In this study, we will discuss Fluid Attenuated Inversion Recovery (FLAIR) MR, Diffusion Weighted Imaging (DWI) and Diffusion Tensor Imaging (DTI) techniques in diagnosis of acute meningitis.
2. Methods
2.1. Search strategy

Preferred Reporting Items for Systematic reviews and Meta-Analysis (PRISMA) was our guideline in this review (Moher et al., 2009). Searching was carried out in databases of PubMed, Scopus, and Web of Science. There was not any language, type of document and initial time limitation, and the articles published until March 2017 were studied. The keywords searched in the PubMed, Scopus, and Web of Science databases included “meningitis,” “magnetic resonance imaging,” “MR imaging,” and “MRI”. The search terms with similar meanings were combined using the OR logic, and the search terms were coupled using the AND logic.
The exclusion criteria were articles on: MRI with contrast (Gadolinium); Animal model; Presence of the focal lesion in the brain such as cerebritis, abscess, encephalitis, and so on; Immonocompromised host such as HIV+ (Human Immunodeficiency Virus) OR VDRL + (The Venereal Disease Research Laboratory test); Patients after surgery; Pachymeningitis; Meningoencephalitis; Cerebral malaria; and Meningitis of tuberculosis. In order to select the appropriate articles we assessed the abstracts of the searched articles or only their titles. If necessary, the full text of articles were reviewed, too. Reviewing was performed by two reviewers. After full assessment of the articles, the eligible articles were included in study. 
2.2. Assessing the quality of articles
The STARD (Standards for Reporting of Diagnostic Accuracy) was used in this review, which is a quality standard for diagnosis of the completeness and transparency of studies (Scales et al., 2008)
2.3. Methods of data extraction
After screening available resources and databases, the selected articles were reviewed to extract their data uniformly.
3. Results
After assessing the titles and abstracts of the articles and deleting duplicate articles, 3836 articles were remained. After omitting 3809 unrelated papers, 25 full texts were reviewed in term of eligibility. Considering the exclusion criteria during studying of their full texts, 6 articles were remained in this review. PRISMA Flow Diagram of this review summarizes the article acquisition (Figure 1). The selected articles (n=6) included three review articles and three original papers which their characteristics are listed in Table 1.


4. Discussion
4.1. Fluid Attenuation Inversion Recovery (FLAIR)

Some authors believe that FALIR is a sensitive technique for detecting elevation of CSF protein and cellular content. In meningitis, elevations in protein and cellular concentrations decrease Tl relaxation time of CSF. Thus, changing its null point. This leads to hyperintensity in the affected CSF, which is easily detected on FLAIR (Adams & Melhem, 1999; Hazany et al., 2014). Some other authors found that high level protein conditions, as a non-specific finding for meningitis, might be seen in several other diseases and even in normal conditions such as slow arterial flow, disruption of blood-brain barrier, paramagnetic effects of supplemental O2 administration and also deposition of free radicals (Maeda et al., 2003; Taoka et al., 2001; Lee et al., 2002). Hughes et al. (2010) showed that in inflammatory condition the CSF in the Subarachnoid Spaces (SAS) can be of higher signal intensity than ventricular fluid, because of leaky capillaries which increase the level of proteins in that fluid (Hughes et al., 2010). However it is quite a non-specific sign and similar signal alteration can be caused in the other conditions such as carcinomatous meningitis, subarachnoid hemorrhage, oxygen and some drugs administration such as propofol (Castillo, 2004).
Another interesting finding of meningitis on FLAIR and T2 weighted sequences is hypointensity of subcortical white matter underlying intense meningeal inflammation (Lee et al., 2002) by unknown reason. Disordered oxygen free radical transport is the probable mechanism which can explain this signal alteration. It is also a non-specific finding (Hughes et al., 2010)
4.2. FLAIR vs. contrast enhanced T1 weighted MRI
Also FLAIR image of meningitis has been introduced superior to contrast enhanced T1 weighted MRI. SAS enhancement by contrast administered T1-weighted MRI in meningitis sometimes is difficult to be differentiated from normal prominent enhancing vascular structures. Non-contrast enhanced FLAIR can make such differentiation and resolve this problem. Additionally sometimes the swelling of the brain or widening of the extra-axial CSF spaces may be evident in meningitis which can be evident by non-contrast MRI sequences (Castillo et al., 1994; Hughes et al., 2010). Also, it is helpful in the condition in which the contrast cannot be used like glomerular filtration rate of lower than 30 mL/min/1.73 m3.
4.3. Post-contrast T1WI and post-contrast FLAIR
Although our research is about non-contrast MRI modalities but it is interesting to mention the study by Ferreira et al. which compared post-contrast T1WI and post-contrast FLAIR images. Some investigators (Mathews et al., 1999) believed that post-contrast FLAIR imaging is more sensitive in detecting SAS diseases than T1WI post gadolinium and vice versa (Kamran, Bener, Alper, & Bakshi, 2004; Galassi et al., 2005). Advocates of the post-contrast FLAIR mention these main advantages: In FLAIR sequence with contrast, vessels enhancement with slow-flowing blood does not appear. But enhancement of vessels is visible on T1-weighted with contrast which is similar to meningeal enhancement; Gadolinium enhancement of the SAS is better visible by FLAIR compared with T1 weight sequence (Figure 2) (Singer et al., 1998; Mathews et al., 1999; Mamourian et al., 2000; Jackson & Hayman, 2000)
4.4. SPIR and fat suppression FLAIR
Fat suppression SPIR (Spectral Inversion Recovery) and subtraction FLAIR imaging (Jackson et al., 1998; Jackson et al., 1999) deliver better fat suppression rather than T1-weighted (T1-W) sequence, since the selected inversion time relates to the null point (T1 recovery time) of fat rather than the precessional frequency (Westbrook, Kaut Roth, & Talbot, 2005). It was documented in one study by McKinney et al. that sensitivity and specificity of the sequences of non-contrast SPIR/FLAIR imaging in the initial scan of patients with proven meningitis were 71% and 75%, respectively (Figure 3 a, b) (McKinney, Palmer, Short, Lucato, & Truwit,, 2006)
4.5. Diffusion Weighted Imaging (DWI)
DWI is a MRI sequence which has been introduced as a valuable tool for the diagnosis of acute meningitis and its complications (Noguchi et al., 1999; Guo et al., 2001). In this sequence, pus in the ventricles, especially lateral ventricles and in the cortical sulci appears hyperintense with high sensitivity (Rana, Albayram, Lin, & Yousem, 2002; Fujikawa, Tsuchiya, Honya, & Nitatori, 2006; Han et al., 2007). In a case of bacterial meningitis presented by Abe et al., MRI of the brain was normal in a T2-weighted sequence (T2WI), but suggested possible hyperintense lesions along the convexities in DWI (Figure 4). Four days after admission, follow-up DWI confirmed hyperintense lesions both along the convexities and Sylvian fissure, and also in the third and the fourth ventricle; T2WI continued to appear normal. Enhancement by gadolinium contrast administration highlighted the meningeal exudate as well as the lesions throughout the convexities and Sylvian fissure that were seen by DWI (Abe et al., 2002).
DWI is highly sensitive in acute ischemic infarction. Considering the macro- and micro-infarction due to septic emboli and or vasculitis as complication of the bacterial meningitis which is evident in nearly 20% of patients (Lummel et al., 2016), another advantage of this sequence of MRI could be also its value in prognostic approach. 
Thus, Abe et al. described two theories for visualized hyperintensity in DWI: The contents of purulent meningitis is responsible for the high signal intensity; and Small-vessel vasculitis with cortical infarcts would seem as the basis for the patient’s hyperintense lesions in DWI (Abe et al., 2002).
For confirmation of these two theories, Ebisu et al. (1996) and Desprechins et al. (1999) reported patients with brain abscess who showed high signal intensity in the abscess cavity in DWI. To better understand these findings, Ebisu subsequently obtained DWI of purulent contents aspirated from the abscess. Again high signal intensity was evident, leading the authors to conclude that abscess contents were responsible for the high signal intensity in DWI in vivo. These findings are probably related to restriction of water molecules movement in a viscous compound, including proteins, inflammatory cells, and infection microorganism. Additionally, water molecules can be limited in their translational movement by binding to carboxyl, hydroxyl, and amino groups on surfaces of macromolecules in the abscess (Rusakov & Kullmann, 1998).
In autopsy cases of tuberculosis and Haemophilus meningitis, cerebral arteriopathy has been attributed to purulent leptomeningeal exudates (Lyons & Leeds, 1967; Yamashima et al., 1985; Greitz, 1964), particularly at the base of brain but also spreading along sulci of the convexity in proximity to which become inflamed (Yamashima et al., 1985; Greitz, 1964). Accordingly the MRI findings in the case presented by Abe et al. may represent purulent leptomeningeal exudates similar in character to the highly intense lesions seen with DWI in patients with brain abscess. In fact, DWI showed diminishing signal changes as CSF findings improved. These findings may strongly support this possibility. Somewhat less likely in their case is a possibility that highly intense lesions in DWI may reflect ischemia, as seen in acute infarction. Greitz first reported narrowing of the arteries at the base of the brain in tuberculous meningitis (Greitz, 1964). Subsequently, Lyons and Leeds described occurrence of purulent meningitis associated with vasospasm, stenosis, and occlusion (Lyons & Leeds, 1967) probably related to the inflammation of vessel walls (Yamashima  et al., 1985). Vasculitis predominately affecting small vessels can produce small areas of active ischemic change not visible in conventional MRIs but detectable by DWI (Yuh et al., 1998). In Abe et al. case, follow-up MRI showed infarct-like lesions in T2WI that correlated with the highly intense lesions seen by DWI. Thus, small-vessel vasculitis with cortical infarcts would seem relatively unlikely as the basis for this patient’s hyperintense lesions in DWI (Abe et al., 2002)
Lummel et al. determined the sensitivity of DWI and FLAIR for detecting meningitis, 67.6% and 79.6%, respectively. Table 2 presents the presence and anatomical location of signal changes in the different MRI sequences. Sulcal abnormities in DWI and FLAIR were evident in 18 out of 71(25.4%) patients and 11 out of 49(22.4%) patients, respectively and cortical abnormities in 9 out of 71(12.7%) patients and 7 out of 49(14.3%) patients, respectively (Figure 5). Hyperintense signals of FLAIR sequences within the sulcal and or intraventricular space in meningitis may be due to protein-enrichment of the CSF. Areas with diffusion restriction within the CSF spaces in DWI were interpreted as pus. Also there is similar frequency (near 50%) of FLAIR and DWI sequences abnormalities in meningitis and similar sensitivity for its diagnosis (Lummel et al., 2014).
Another interesting finding in Lummel et al. study was the specificity of DWI with respect to the causative pathogen. So that, the patients with streptococcal meningitis showed restriction pattern in ventricles and sulci more frequent than patients with other types of meningitis (85.3% vs. 32.4%) (P<0.0001) (Lummel et al., 2014). Whereas in the other studies it was claimed that simple magnetic resonance imaging is usually nonspecific for the pathogens, because of the similarity of the brain response to different bacterial species (Hazany et al., 2014).
4.6. Diffusion Tensor Imaging (DTI)
Diffusion Tensor Imaging (DTI) is one of the MRI modalities which assesses the integrity of brain structure using diffusion anisotropy. Malik et al. in a study determined the change in periventricular white matter signal due to damage of its structure and integrity in bacterial meningitis by DTI (Figure 6) (Malik et al., 2008). Also they studied the outcome of patients by this technique of MRI by determining the FA (fraction of anisotropy) values of periventricular white matter at the time of base and follow-up study (Tables 3 and 4). 


The FA in periventricular white matter decreases in meningitis due to the vulnerability of this anatomic location to change of CSF composition which appears normal in other routine MRI sequences. This change may be the result of inflammation of vessels which make them prone to thrombosis and consequently producing ischemic infarct and decreased blood perfusion in that area. Also, periventricular neuronal and glial injury may occur due to the release of free radicals and proteases, and toxic cytokines in response to inflammation (Nau & Bruck, 2002). Also decreased FA values were obvious on follow-up study in some patients. This could be the result of oligodendroglial cells damage and deficient myelination process. 
They assessed the valuable role of DTI in determining outcome in meningitis. They suggested the morbidity and mortality of neonatal meningitis can be estimated by determining FA values in periventricular white matter. But mean diffusivity (MD) value lacked any role in determining the outcome of meningitis (Malik et al., 2008). So the use of DTI in meningitis may have a prognostic value.
FLAIR and DWI-MR imaging are potentially useful to diagnose the conditions such as bacterial meningitis that SAS or CSF contain high cellular or protein materials. Also it can be used in emergent condition in which bacterial meningitis is highly suspicious and the other diagnostic tools are not available or feasible. CSF analysis is the gold standard of diagnosis of meningitis and it is necessary to be done as soon as possible by every aiding tools such as radio- or ultrasound-guided lumbar puncture. But because of the life threatening nature of meningitis and in order to save the time, every available tool is justified to save the patients’ life. Regarding this fact, FLAIR and DWI sequences of brain MRI can help the physician to diagnose meningitis. In order to better clarity this systematic review, we need a meta-analysis.
Acknowledgements
This research did not receive any specific grant from funding agencies in the public, commercial, or not-for-profit sectors.
Conflict of Interest
The authors had no conflicts of interest. 


References
Type of Study: Review | Subject: Clinical Neuroscience
Received: 2017/10/29 | Accepted: 2017/12/18 | Published: 2018/03/3

References
1. Abe, M., Takayama, Y., Yamashita, H., Noguchi, M., & Sagoh, T. (2002). Purulent meningitis with unusual diffusion-weighted MRI findings. European Journal of Radiology, 44(1), 1–4. doi: 10.1016/s0720-048x(01)00471-5 [DOI:10.1016/S0720-048X(01)00471-5]
2. Adams, J. G., & Melhem, E. R. (1999). Clinical usefulness of T2-weighted fluid-attenuated inversion recovery MR imaging of the CNS. American Journal of Roentgenology, 172(2), 529–36. doi: 10.2214/ajr.172.2.9930818 [DOI:10.2214/ajr.172.2.9930818]
3. Castillo, M. (1994). Magnetic resonance imaging of meningitis and its complications. Topics in Magnetic Resonance Imaging, 7(1), 53-8. doi: 10.1097/00002142-199400610-00008 [DOI:10.1097/00002142-199400610-00008]
4. Castillo, M. (2004). Imaging of meningitis. Seminars in Roentgenology, 39(4), 458–64. doi: 10.1016/j.ro.2004.06.009 [DOI:10.1016/j.ro.2004.06.009]
5. Desprechins, B., Stadnik, T., Koerts, G., Shabana, W., Breucq, C., & Osteaux, M. (1999). Use of diffusion-weighted MR imaging in differential diagnosis between intracerebral necrotic tumors and cerebral abscesses. American Journal of Neuroradiology, 20(7), 1252-7. [PMID]
6. Ebisu, T., Tanaka, C., Umeda, M., Kitamura, M., Naruse, S., Higuchi, T., et al. (1996). Discrimination of brain abscess from necrotic or cystic tumors by diffusion-weighted echo planar imaging. Magnetic Resonance Imaging, 14(9), 1113–6. doi: 10.1016/s0730-725x(96)00237-8 [DOI:10.1016/S0730-725X(96)00237-8]
7. Ferreira, N. P. D. F., Otta, G. M., do Amaral, L. L. F., & da Rocha, A. J. (2005). Imaging aspects of pyogenic infections of the central nervous system. Topics in Magnetic Resonance Imaging, 16(2), 145–54. doi: 10.1097/01.rmr.0000189107.55275.f6 [DOI:10.1097/01.rmr.0000189107.55275.f6]
8. Fujikawa, A., Tsuchiya, K., Honya, K., & Nitatori, T. (2006). Comparison of MRI sequences to detect ventriculitis. American Journal of Roentgenology, 187(4), 1048–53. doi: 10.2214/ajr.04.1923 [DOI:10.2214/AJR.04.1923]
9. Galassi, W., Phuttharak, W., Hesselink, J. R., Healy, J. F., Dietrich, R. B., & Imbesi, S. G. (2005). Intracranial meningeal disease: comparison of contrast-enhanced MR imaging with fluid-attenuated inversion recovery and fat-suppressed T1-weighted sequences. American Journal of Neuroradiology, 26(3), 553-9. [PMID]
10. Greitz, T. (1964). Angiography in tuberculous meningitis. Acta Radiologica. Diagnosis, 2(5), 369–78. doi: 10.1177/028418516400200501 [DOI:10.1177/028418516400200501]
11. Griffin, D. E. (1997). Approach to patient with infection of central nervous system (p. 1377). In: S. L. Gorbach., J. G. Barlett., N. R. Blacklow (Eds.), Infectious Disease, 2. Philadelphia: WB Saunders.
12. Guo, A. C., Provenzale, J. M., Cruz Jr., L. C. H., & Petrella, J. R. (2001). Cerebral abscesses: Investigation using apparent diffusion coefficient maps. Neuroradiology, 43(5), 370–4. doi: 10.1007/s002340000519 [DOI:10.1007/s002340000519]
13. Han, K. T., Choi, D. S., Ryoo, J. W., Cho, J. M., Jeon, K. N., Bae, K. S., et al. (2007). Diffusion-weighted MR imaging of pyogenic intraventricular empyema. Neuroradiology, 49(10), 813–8. doi: 10.1007/s00234-007-0264-7 [DOI:10.1007/s00234-007-0264-7]
14. Hazany, S., Go, J. L., & Law, M. (2014). Magnetic resonance imaging of infectious meningitis and ventriculitis in adults. Topics in Magnetic Resonance Imaging, 23(5), 315–25. doi: 10.1097/rmr.0000000000000034 [DOI:10.1097/RMR.0000000000000034]
15. Hughes, D. C., Raghavan, A., Mordekar, S. R., Griffiths, P. D., & Connolly, D. J. A. (2010). Role of imaging in the diagnosis of acute bacterial meningitis and its complications. Postgraduate Medical Journal, 86(1018), 478–85. doi: 10.1136/pgmj.2010.097022 [DOI:10.1136/pgmj.2010.097022]
16. Jackson, A., Sheppard, S., Johnson, A. C., Annesley, D., Laitt, R. D., & Kassner, A. (1999). Combined fat-and water-suppressed MR imaging of orbital tumors. American journal of neuroradiology, 20(10), 1963-9. PMID: 10588126 [PMID]
17. Jackson, A., Sheppard, S., Laitt, R. D., Kassner, A., & Moriarty, D. (1998). Optic neuritis: MR imaging with combined fat- and water-suppression techniques. Radiology, 206(1), 57–63. doi: 10.1148/radiology.206.1.9423652 [DOI:10.1148/radiology.206.1.9423652]
18. Jackson, E. F., & Hayman, L. A. (2000). Meningeal enhancement on fast FLAIR images. Radiology, 215(3), 922–4. doi: 10.1148/radiology.215.3.r00ap45922 [DOI:10.1148/radiology.215.3.r00ap45922]
19. Jan, W., Zimmerman, R. A., Bilaniuk, L. T., Hunter, J. V., Simon, E. M., & Haselgrove, J. (2003). Diffusion-weighted imaging in acute bacterial meningitis in infancy. Neuroradiology, 45(9), 634–9. doi: 10.1007/s00234-003-1035-8 [DOI:10.1007/s00234-003-1035-8]
20. Johnson A. B. (2000). Intracranial infections (p. 767). In: W. W. Orrison (Ed.), Neuroimaging. Philadelphia: WB Saunders.
21. Kamran, S., Bener, A. B., Alper, D., & Bakshi, R. (2004). Role of fluid-attenuated inversion recovery in the diagnosis of meningitis: comparison with contrast-enhanced magnetic resonance imaging. Journal of Computer Assisted Tomography, 28(1), 68-72. PMID: 14716235 [DOI:10.1097/00004728-200401000-00011] [PMID]
22. Kanamalla, U. S., Ibarra, R. A., & Jinkins, J. R. (2000). Imaging of cranial meningitis and ventriculitis. Neuroimaging Clinics of North America, 10(2), 309-331. PMID: 10775954 [PMID]
23. Kim, Y. J., Chang, K. H., Song, I. C., Kim, H. D., Seong, S. O., Kim, Y. H., et al. (1998). Brain abscess and necrotic or cystic brain tumor: Discrimination with signal intensity on diffusion-weighted MR imaging. American Journal of Roentgenology, 171(6), 1487–90. doi: 10.2214/ajr.171.6.9843275 [DOI:10.2214/ajr.171.6.9843275]
24. Lee, J. H., Na, D. G., Choi, K. H., Kim, K. J., Ryoo, J. W., Lee, S. Y., et al. (2002). Subcortical low intensity on MR images of meningitis, viral encephalitis, and leptomeningeal metastasis. American Journal of Neuroradiology, 23(4), 535-42. PMID: 11950641 [PMID]
25. Leedom, J. M., & Underman, A. E. (2000). Epidemiology of central nervous system infections. Neuroimaging Clinics of North America, 10(2), 297-308. PMID: 10775953 [PMID]
26. Lummel, N., Koch, M., Klein, M., Pfister, H. W., Brückmann, H., & Linn, J. (2014). Spectrum and prevalence of pathological intracranial magnetic resonance imaging findings in acute bacterial meningitis. Clinical Neuroradiology, 26(2), 159–67. doi: 10.1007/s00062-014-0339-x [DOI:10.1007/s00062-014-0339-x]
27. Lyons, E. L., & Leeds, N. E. (1967). The angiographic demonstration of arterial vascular disease in purulent meningitis. Radiology, 88(5), 935–8. doi: 10.1148/88.5.935 [DOI:10.1148/88.5.935]
28. Maeda, M., Yagishita, A., Yamamoto, T., Sakuma, H., & Takeda, K. (2003). Abnormal hyperintensity within the subarachnoid space evaluated by fluid-attenuated inversion-recovery MR imaging: a spectrum of central nervous system diseases. European Radiology, 13(S06), L192–201. doi: 10.1007/s00330-003-1877-
29. Malik, G. K., Trivedi, R., Gupta, A., Singh, R., Prasad, K. N., & Gupta, R. K. (2008). Quantitative DTI assessment of periventricular white matter changes in neonatal meningitis. Brain and Development, 30(5), 334–41. doi: 10.1016/j.braindev.2007.10.002 [DOI:10.1016/j.braindev.2007.10.002]
30. Mamourian, A. C., Hoopes, P. J., & Lewis, L. D. (2000). Visualization of intravenously administered contrast material in the CSF on fluid-attenuatedInversion-recovery MR images: An in vitro and animal-model investigation. American Journal of Neuroradiology, 21(1), 105-11. PMID: 10669233 [PMID]
31. Mathews, V. P., Caldemeyer, K. S., Lowe, M. J., Greenspan, S. L., Weber, D. M., & Ulmer, J. L. (1999). Brain: Gadolinium-enhanced fast fluid-attenuated inversion-recovery MR imaging. Radiology, 211(1), 257–63. doi: 10.1148/radiology.211.1.r99mr25257 [DOI:10.1148/radiology.211.1.r99mr25257]
32. McKinney, A., Palmer, C., Short, J., Lucato, L., & Truwit, C. (2006). Utility of fat-suppressed FLAIR and subtraction imaging in detecting meningeal abnormalities. Neuroradiology, 48(12), 881–5. doi: 10.1007/s00234-006-0145-5 [DOI:10.1007/s00234-006-0145-5]
33. Melhem, E. R., Jara, H., & Eustace, S. (1997). Fluid-attenuated inversion recovery MR imaging: Identification of protein concentration thresholds for CSF hyperintensity. American Journal of Roentgenology, 169(3), 859–62. doi: 10.2214/ajr.169.3.9275912 [DOI:10.2214/ajr.169.3.9275912]
34. Moher, D., Liberati, A., Tetzlaff, J., & Altman, D. G. (2009). Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement. Journal of Clinical Epidemiology, 62(10), 1006–12. doi: 10.1016/j.jclinepi.2009.06.005 [DOI:10.1016/j.jclinepi.2009.06.005]
35. Nau, R., & Brück, W. (2002). Neuronal injury in bacterial meningitis: mechanisms and implications for therapy. Trends in Neurosciences, 25(1), 38–45. doi: 10.1016/s0166-2236(00)02024-5 [DOI:10.1016/S0166-2236(00)02024-5]
36. Noguchi, K., Watanabe, N., Nagayoshi, T., Kanazawa, T., Toyoshima, S., Shimizu, M., et al. (1999). Role of diffusion-weighted echo-planar MRI in distinguishing between brain abscess and tumour: A preliminary report. Neuroradiology, 41(3), 171-4. doi: 10.1007/s002340050726 [DOI:10.1007/s002340050726]
37. Noguchi, K., Watanabe, N., Nagayoshi, T., Kanazawa, T., Toyoshima, S., Shimizu, M., et al. (1999). Role of diffusion-weighted echo-planar MRI in distinguishing between brain abscess and tumour: A preliminary report. Neuroradiology, 41(3), 171–4. doi: 10.1007/s002340050726 [DOI:10.1007/s002340050726]
38. Rana, S., Albayram, S., Lin, D. D., & Yousem, D. M. (2002). Diffusion-weighted imaging and apparent diffusion coefficient maps in a case of intracerebral abscess with ventricular extension. American Journal of Neuroradiology, 23(1), 109-12. PMID: 11827882 [PMID]
39. Rusakov, D. A., & Kullmann, D. M. (1998). Geometric and viscous components of the tortuosity of the extracellular space in the brain. Proceedings of the National Academy of Sciences, 95(15), 8975–80. doi: 10.1073/pnas.95.15.8975 [DOI:10.1073/pnas.95.15.8975]
40. Scales, C. D., Dahm, P., Sultan, S., Campbell Scherer, D., & Devereaux, P. J. (2008). How to use an article about a diagnostic test. The Journal of Urology, 180(2), 469–76. doi: 10.1016/j.juro.2008.04.026 [DOI:10.1016/j.juro.2008.04.026]
41. Schuchat, A., Robinson, K., Wenger, J. D., Harrison, L. H., Farley, M., Reingold, A. L., et al. (1997). Bacterial meningitis in the United States in 1995. New England Journal of Medicine, 337(14), 970–6. doi: 10.1056/nejm199710023371404 [DOI:10.1056/NEJM199710023371404]
42. Singer, M. B., Atlas, S. W., & Drayer, B. P. (1998). Subarachnoid space disease: Diagnosis with fluid-attenuated inversion-recovery MR imaging and comparison with gadolinium-enhanced spin-echo MR imaging--blinded reader study. Radiology, 208(2), 417–22. doi: 10.1148/radiology.208.2.9680570 [DOI:10.1148/radiology.208.2.9680570]
43. Taoka, T., Yuh, W. T. C., White, M. L., Quets, J. P., Maley, J. E., & Ueda, T. (2001). Sulcal hyperintensity on fluid-attenuated inversion recovery MR images in patients without apparent cerebrospinal fluid abnormality. American Journal of Roentgenology, 176(2), 519–24. doi: 10.2214/ajr.176.2.1760519 [DOI:10.2214/ajr.176.2.1760519]
44. Westbrook, C., Kaut Roth, C., & Talbot, J. (2005). MRI in practice. Hoboken, NJ: Wiley-Blackwell.
45. Yamashima, T., Kashihara, K., Ikeda, K., Kubota, T., & Yamamoto, S. (1985). Three phases of cerebral arteriopathy in meningitis: Vasospasm and vasodilatation followed by organic stenosis. Neurosurgery, 16(4), 546–53. doi: 10.1227/00006123-198504000-00018 [DOI:10.1227/00006123-198504000-00018]
46. Yuh, W. T., Ueda, T., & Maley, J. E. (1998). Perfusion and diffusion imaging: A potential tool for improved diagnosis of CNS vasculitis. American Journal of Neuroradiology, 20(1), 87-89.

Add your comments about this article : Your username or Email:
CAPTCHA

Send email to the article author


Rights and permissions
Creative Commons License This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

© 2024 CC BY-NC 4.0 | Basic and Clinical Neuroscience

Designed & Developed by : Yektaweb