|Year : 2016 | Volume
| Issue : 2 | Page : 101-106
A correlative study of magnetic resonance imaging and biochemical findings of neuroinfections in human immunodeficiency virus-infected patients
N Ravi, Archana Netto, Santoshkumar P Uppinal, BR Nagaraj
Department of Radio diagnosis, Bangalore Medical College and Research Institute, Bengaluru, Karnataka, India
|Date of Web Publication||8-Aug-2016|
Department of Radio-diagnosis, Bangalore Medical College and Research Institute, Fort, K.R. Road, Bengaluru - 560 002, Karnataka
Source of Support: None, Conflict of Interest: None
Context: Neuroinfections are one of the most common complications in human immunodeficiency virus (HIV)-infected patients. The neurological complications arise from the HIV infection itself or from secondary opportunistic infections and neoplasm. Neurological manifestations cause significant morbidity and mortality in HIV-infected patients. Aims: The aims of the study were to assess the magnetic resonance imaging (MRI) features of the central nervous system infections in patients with HIV and to correlate the imaging features with biochemical markers of various neuroinfections in HIV patients to get a better diagnostic probability wherever possible. Settings and Design: HIV patients with suspected neuroinfections were included in the study. The CD4 count, the cerebrospinal fluid analysis reports and other serological investigations were taken. The various MRI sequences were then taken and assessed. Materials and Methods: All HIV-infected patients who were suspected to have neuroinfection who were referred for MRI imaging to the Department of Radio-diagnosis, Bangalore Medical College and Research Institute, from the attached hospitals were assessed. Statistical Analysis Used: Documented observations were compiled using SPSS-16.5 software (IBM). Univariate analysis was carried out for data interpretation. Multiple variables were assessed with Pearson's method. Results: In this study, majority were men with a male to female ratio of 5:1 and most falling in the age group of 20-40 years. Out of 50 patients in our study, 48 patients were proven to have some or the other neuroinfections, either purely biochemically or by considering the radiological and clinical criterion and only in 2 patients the exact diagnosis could not be made and were empirically treated with antitubercular treatment. Conclusion: This study tried to correlate the various neuroinfections in HIV-infected patients with their respective biochemical markers and CD4 counts. Neuroinfections are common complications in HIV-infected patients with the distribution of infection related to the CD4 count.
Keywords: CD4 counts; human immunodeficiency virus; magnetic resonance imaging; neuroinfections
|How to cite this article:|
Ravi N, Netto A, Uppinal SP, Nagaraj B R. A correlative study of magnetic resonance imaging and biochemical findings of neuroinfections in human immunodeficiency virus-infected patients. West Afr J Radiol 2016;23:101-6
|How to cite this URL:|
Ravi N, Netto A, Uppinal SP, Nagaraj B R. A correlative study of magnetic resonance imaging and biochemical findings of neuroinfections in human immunodeficiency virus-infected patients. West Afr J Radiol [serial online] 2016 [cited 2022 Aug 17];23:101-6. Available from: https://www.wajradiology.org/text.asp?2016/23/2/101/187968
| Introduction|| |
According to the Joint United Nations Program on human immunodeficiency virus/acquired immune deficiency syndrome (HIV/AIDS), an estimated 35 million people were infected with HIV infections at the end of 2014.  Up to 60% of AIDS patient had neurological disease, and in the era before the use of antiretroviral therapy, neurological disease was the first manifestation of symptomatic HIV infection in 10-20% of patients. , Neurological manifestations cause significant morbidity and mortality in HIV-infected patients. Next to Sub-Saharan Africa, India has the second largest burden of HIV-related pathologies. 
The neurological complications arise from the HIV infection itself or from secondary opportunistic infections and neoplasm. The opportunistic infections are varied and include central nervous system (CNS) tuberculosis (TB), cryptococcal infection, and other fungal infections such as Candida, Aspergillus, CNS cytomegalovirus (CMV) infections, CNS toxoplasmosis, neurosyphilis, progressive multifocal leukoencephalopathy (PML), and bacterial intracranial infections. Those arising from the HIV itself are AIDS dementia complex.
Neoplasms includes central nervous system lymphoma
Although there is considerable overlap between the imaging characteristics of different entities, some findings are found to be very suggestive of a particular disease and imaging modalities, mainly magnetic resonance imaging (MRI) play an important role in the diagnosis and follow-up of AIDS patient.  There are various biochemical and radiological tests which can be used to evaluate neuroinfections. However, the serological tests and the cerebrospinal fluid (CSF) analysis results are not helpful many a time, and even the imaging studies are not commonly diagnostic. Hence, empirical management is more often prescribed to patients.
| Materials and Methods|| |
Source of data
All HIV-infected patients suspected to have neuroinfection and referred for MRI to the Department of Radio-diagnosis, Bangalore Medical College and Research Institute, from various attached hospitals were included in the study.
The study was a prospective study conducted over 1 year from January 2015 to December 2015.
- All adult HIV patients with suspected neuroinfections
- All pediatric and obstetric HIV patients with suspected neuroinfections.
- All patients in whom MRI is contraindicated
- All patients who are unstable
- Nonconsenting patients
- All neurological disorders unrelated to HIV.
| Methods|| |
The subjects being assessed were serologically diagnosed as having HIV either by enzyme-linked immunosorbent assay, Western blot, or by polymerase chain reaction (PCR) where ever indicated. The CD4 counts of the patients were then taken.
After getting an informed consent for the investigation and when the patient was stable enough to undergo the MR procedure, MRI was carried out. The routine T1, T2, fluid-attenuated inversion recovery, gradient recalled echo susceptibility-weighted imaging, and diffusion-weighted imaging sequences were taken. Contrast-enhanced MRI was done where ever possible. Magnetic resonance spectroscopy was also done wherever possible.
The lesions found on MRI were then segregated into intra-axial lesions and extra-axial lesions.
The intra- and extra-axial lesions were again divided into focal or diffuse
The focal lesions included white matter lesions, mass lesions, and others.
The diffuse abnormality included atrophy and white matter lesions.
The extra-axial lesions were divided into meningitis or collections
The MRI findings were assessed by radiologists.
The various microbiological and pathological tests were reviewed, which included:
Ethical Committee clearance was obtained.
- CSF analysis - routine, antigen and antibody assays, PCR, and others
- Serological tests - antigen and antibody assays and other markers.
| Results|| |
The results of the study are shown in [Table 1] [Table 2] [Table 3] [Table 4] [Table 5].
|Table 1: Central nervous system tuberculosis - the CD4 count, imaging findings, and biochemical markers |
Click here to view
|Table 2: Central nervous system toxoplasmosis - the CD4 count, imaging findings, and biochemical markers |
Click here to view
|Table 3: Progressive multifocal leukoencephalopathy - the CD4 count, imaging findings, and biochemical markers |
Click here to view
|Table 4: AIDS dementia complex/HIV encephalopathy - the CD4 count, imaging findings, and biochemical markers |
Click here to view
|Table 5: Others - the CD4 count, imaging findings, and biochemical markers |
Click here to view
In this study, majority were men with a male to female ratio of 5:1 and most falling in the age group of 20-40 years. Out of 50 patients, 39 were between the age group of 20 and 40 years, four were between 5 and 20 years, and rest of the seven patients between 40 and 60 years. None of the patients were above 65 and below 5 years. Out of 50 patients in our study, 48 patients were proven to have some or the other infections, either purely biochemically or by a considering the radiological and clinical criteria and only in two patients, the exact diagnosis could not be made and was empirically treated with antitubercular treatment.
The possible reasons for the disproportionate distribution in sex ration predominating in men could be that men had higher association with other risk factors, especially alcoholism and smoking, and had more incidence of promiscuous behavior in comparison to females.
Of the 48 patients, 29 patients, i.e., 60.4% were diagnosed to have TB, forming the bulk of the neuroinfection diagnosed. The second most common infection was toxoplasmosis, with seven patients being diagnosed with the infection, i.e., 14.6%. Other neuroinfections diagnosed in the study were PML and apparent diffusion coefficient (ADC) with four cases each, i.e., 8.3%, cryptococcosis with two patients, i.e., 4.2% and bacterial meningitis and CMV infections with one patient each.
Of the 29 patients with TB, 19 patients were seen to have tuberculomas, i.e., ring-enhancing lesions. Majority of them, i.e., 18 of them had CSF acid-fast bacilli (AFB) positive and 17 patients had CD4 counts between 50 and 200 cells/mm 3 . Six patients had meningitis either patchy or leptomeningitis. Two of the patients had infarcts secondary to vasculitis and one patient had hydrocephalus. Excluding three patients, rest of the patients had CSF-AFB positive while the remaining were diagnosed with CSF culture and TB.
The second most common infection was toxoplasmosis with seven patients, out of which five of them had CD4 counts <50, five of them had serum immunoglobulin positive, and five patients had multiple ring-enhancing lesions. The next most common infections were PML and ADC with four patients each and with typical MRI features and with CD4 counts between 50 and 200 cells/mm 3 .
| Discussion|| |
HIV is a neurotropic virus and enters the CNS early in the course of infection. , Neurological manifestations are common in HIV infections. They occur in all stages of HIV infection - early or late. Opportunistic infections constitute 70-80% and the remaining 20-30% are due to direct HIV infection.  The type of neurological involvement depends on the stage of immune dysfunction. Like in late stages, severe disorders such as cryptococcal meningitis, TBM, and CMV encephalitis are common.  The neurological complications arise from the HIV infection itself or from secondary opportunistic infections and neoplasm.
AIDS dementia complex AIDS dementia complex is a neurodegenerative disease characterized by progressive cognitive and motor impairment and atrophic changes involving the brain. Approximately 15-20% of these patients develop AIDS dementia complex. On MR images, a diffuse cerebral atrophy with symmetric, patchy, or confluent areas of T1 and T2 prolongation is seen within the periventricular and deep white matter. CSF analysis should exclude infectious agents other than HIV. Proton (1H) MR spectroscopy reveals decreased N-acetylaspartate and elevated peaks of in choline and myoinositol. 
CNS-TB is an AIDS-defining illness, can result from reactivation of a previous infection or from a primary, newly acquired infection. Imaging features in one study, hydrocephalus was seen in 51% and meningeal enhancement in 45% of patients with CNS-TB.  The hydrocephalus results primarily from obstruction of the basal cistern by inflammatory exudate. In addition, cerebral abscesses and tuberculomas may be seen.  Tuberculomas occurred in 24% of patients in a study by Whiteman et al.  The majority of tuberculomas are supratentorial and may be solitary or multiple; however, they can also be found in subdural, epidural, and subarachnoid spaces.  Tuberculomas are hypointense on T2-weighted MR images in the early stages; as they mature, they develop a hypointense center surrounded by an isointense capsule, which corresponds to solid caseation necrosis [Figure 1] and [Figure 2]. They may further progress to abscess formation with a hyperintense center. At MR spectroscopy, they demonstrate prominent lipid and lactate peaks, but no amino acid peak, unlike bacterial abscesses. 
|Figure 1: T2 fluid-attenuated inversion recovery axial image showing a ring-enhancing lesion in the right frontal lobe proven to be a tuberculoma|
Click here to view
|Figure 2: T1 axial image showing dual enhancement proven to be tubercular meningitis|
Click here to view
PML is a progressive demyelinating disorder that results from a viral infection of the myelin-producing oligodendrocyte, caused by John Cunningham virus. Majority of patients with PML are believed to be infected with the John Cunningham virus in childhood or early adolescence; the virus remains latent in the CNS unless reactivated in the setting of immunodeficiency. Imaging features in patients with PML, On MR images, there are typically multifocal, asymmetric areas of T1 and T2 prolongation in the periventricular and subcortical white matter [Figure 3]. In one study, 50% of the long-term survivors had enhancement of PML lesions at MRI, compared with only 8.9% of the short-term survivors. In these cases, the enhancement was described as faint and peripheral. 
|Figure 3: T2 fluid-attenuated inversion recovery axial image showing asymmetric subcortical white matter hyperintensities proven to be progressive multifocal leukoencephalopathy|
Click here to view
Toxoplasmosis, the most common mass lesion in patients with AIDS, is caused by the ubiquitous parasite, Toxoplasma gondii. , At MRI with T2-weighted sequences, toxoplasmosis lesions are typically hypo- to iso-intense and are surrounded by high-signal-intensity vasogenic edema [Figure 4]. Hemorrhage may be seen occasionally, a finding that can help differentiate toxoplasmosis from lymphoma, which typically does not hemorrhage before treatment.  Postcontrast MRI reveals multiple nodular lesions or ring-enhancing lesions, occasionally, a small eccentric nodule.
|Figure 4: T2 axial image showing a heterogeneous hyperintense lesion in the right occipital lobe proven to toxoplasmosis|
Click here to view
CMV is a very common herpes virus that does not produce clinical disease in most people with an intact immune system. Imaging features imaging findings of CNS involvement in patients with CMV infection are frequently nonspecific.
Cryptococcus neoformans is an encapsulated, ubiquitous yeast-like fungus found in soil contaminated by bird excreta. Infection with C. neoformans is the most common fungal infection of the CNS.  On imaging features, the radiologic manifestations of cryptococcosis are varied and frequently minimal. The imaging findings may consist of meningoencephalitis, interventricular or intraparenchymal cryptococcomas [Figure 5], gelatinous pseudocysts, or hydrocephalus. Assays for CSF and serum cryptococcal antigen, however, are highly sensitive and specific four. India ink test is performed but is less sensitive and specific.
|Figure 5: T2 fluid-attenuated inversion recovery axial images showing multiple ring-enhancing lesions in bilateral cerebral hemispheres proven to be cryptococcosis|
Click here to view
| Conclusion|| |
Many of the HIV patients had overlapping clinical symptoms of neuroinfections, who were subjected in biochemical investigations and MRI for narrowing down the differentials. Although routine CSF was helpful in a few, many of the patients required further biochemical investigations and MRI. Many of the MRI features overlapped which were then differentiated with the biochemical markers. In our study, 25 patients had ring enhancing lesions which were biochemically proven to have TB, toxoplasmosis, or cryptoccosus. In two of the patients in whom the MRI showed nonspecific signal intensity changes, even the initial biochemical markers were inconclusive and further, the patients were noncompliant with further investigations which was the limitation of the study.
We would like to acknowledge the staff of the Department of Radiology, Department of Neurology, and ART Center, Bangalore Medical College and Research Centre.
Financial support and sponsorship
Staff Department of Radio-diagnosis, Bangalore Medical College and Research Institute, Bengaluru, Karnataka, India.
Conflicts of interest
There are no conflicts of interest.
| References|| |
World Health Organization, Joint United Nations Programme on HIV/AIDS. AIDS Epidemic Update: July 2014. Geneva, Switzerland: World Health Organization; 2014.
Levy RM, Bredesen DE, Rosenblum ML. Neurological manifestations of the acquired immunodeficiency syndrome (AIDS): Experience at UCSF and review of the literature. J Neurosurg 1985;62:475-95.
de la Monte SM, Ho DD, Schooley RT, Hirsch MS, Richardson EP Jr. Subacute encephalomyelitis of AIDS and its relation to HTLV-III infection. Neurology 1987;37:562-9.
Shankar SK, Mahadevan A, Satishchandra P, Kumar RU, Yasha TC, Santosh V, et al.
Neuropathology of HIV/AIDS with an overview of the Indian scene. Indian J Med Res 2005;121:468-88.
Thurnher MM, Thurnher SA, Schindler E. CNS involvement in AIDS: Spectrum of CT and MR findings. Eur Radiol 1997;7:1091-7.
Gray F, Scaravilli F, Everall I, Chretien F, An S, Boche D, et al.
Neuropathology of early HIV-1 infection. Brain Pathol 1996;6:1-15.
An SF, Giometto B, Scaravilli F. HIV-1 DNA in brains in AIDS and pre-AIDS: Correlation with the stage of disease. Ann Neurol 1996;40:611-7.
Laubenberger J, Häussinger D, Bayer S, Thielemann S, Schneider B, Mundinger A, et al.
HIV-related metabolic abnormalities in the brain: Depiction with proton MR spectroscopy with short echo times. Radiology 1996;199:805-10.
Villoria MF, de la Torre J, Fortea F, Munoz L, Hernandez T, Alarcón JJ. Intracranial tuberculosis in AIDS: CT and MRI findings. Neuroradiology 1992;34:11-4.
Whiteman M, Espinoza L, Post MJ, Bell MD, Falcone S. Central nervous system tuberculosis in HIV-infected patients: Clinical and radiographic findings. AJNR Am J Neuroradiol 1995;16:1319-27.
Gupta RK, Vatsal DK, Husain N, Chawla S, Prasad KN, Roy R, et al.
Differentiation of tuberculous from pyogenic brain abscesses with in vivo
proton MR spectroscopy and magnetization transfer MR imaging. AJNR Am J Neuroradiol 2001;22:1503-9.
Berger JR, Levy RM, Flomenhoft D, Dobbs M. Predictive factors for prolonged survival in acquired immunodeficiency syndrome-associated progressive multifocal leukoencephalopathy. Ann Neurol 1998;44:341-9.
Levy RM, Mills CM, Posin JP, Moore SG, Rosenblum ML, Bredesen DE. The efficacy and clinical impact of brain imaging in neurologically symptomatic AIDS patients: A prospective CT/MRI study. J Acquir Immune Defic Syndr 1990;3:461-71.
Cornford ME, Holden JK, Boyd MC, Berry K, Vinters HV. Neuropathology of the acquired immune deficiency syndrome (AIDS): Report of 39 autopsies from Vancouver, British Columbia. Can J Neurol Sci 1992;19:442-52.
Trenkwalder P, Trenkwalder C, Feiden W, Vogl TJ, Einhäupl KM, Lydtin H. Toxoplasmosis with early intracerebral hemorrhage in a patient with the acquired immunodeficiency syndrome. Neurology 1992;42:436-8.
Sabetta JR, Andriole VT. Cryptococcal infection of the central nervous system. Med Clin North Am 1985;69:333-44.
[Figure 1], [Figure 2], [Figure 3], [Figure 4], [Figure 5]
[Table 1], [Table 2], [Table 3], [Table 4], [Table 5]