key: cord-034714-6e37yylk authors: Alleg, Manel; Solis, Morgane; Baloglu, Seyyid; Cotton, François; Kerschen, Philippe; Bourre, Bertrand; Ahle, Guido; Pruvo, Jean-Pierre; Leclerc, Xavier; Vermersch, Patrick; Papeix, Caroline; Maillart, Élisabeth; Houillier, Caroline; Chabrot, Cécile Moluçon; Claise, Béatrice; Malak, Sandra; Martin-Blondel, Guillaume; Bonneville, Fabrice; Caulier, Alexis; Marolleau, Jean-Pierre; Bonnefoy, Jérôme Tamburini; Agape, Philippe; Kennel, Céline; Roussel, Xavier; Chauchet, Adrien; De Seze, Jérôme; Fafi-Kremer, Samira; Kremer, Stéphane title: Progressive multifocal leukoencephalopathy: MRI findings in HIV-infected patients are closer to rituximab- than natalizumab-associated PML date: 2020-11-06 journal: Eur Radiol DOI: 10.1007/s00330-020-07362-y sha: doc_id: 34714 cord_uid: 6e37yylk OBJECTIVES: To compare brain MRI findings in progressive multifocal leukoencephalopathy (PML) associated to rituximab and natalizumab treatments and HIV infection. MATERIALS AND METHODS: In this retrospective, multicentric study, we analyzed brain MRI exams from 72 patients diagnosed with definite PML: 32 after natalizumab treatment, 20 after rituximab treatment, and 20 HIV patients. We compared T2- or FLAIR-weighted images, diffusion-weighted images, T2*-weighted images, and contrast enhancement features, as well as lesion distribution, especially gray matter involvement. RESULTS: The three PML entities affect U-fibers associated with low signal intensities on T2*-weighted sequences. Natalizumab-associated PML showed a punctuate microcystic appearance in or in the vicinity of the main PML lesions, a potential involvement of the cortex, and contrast enhancement. HIV and rituximab-associated PML showed only mild contrast enhancement, punctuate appearance, and cortical involvement. The CD4/CD8 ratio showed a trend to be higher in the natalizumab group, possibly mirroring a more efficient immune response. CONCLUSION: Imaging features of rituximab-associated PML are different from those of natalizumab-associated PML and are closer to those observed in HIV-associated PML. KEY POINTS: • Nowadays, PML is emerging as a complication of new effective therapies based on monoclonal antibodies. • Natalizumab-associated PML shows more inflammatory signs, a perivascular distribution “the milky way,” and more cortex involvement than rituximab- and HIV-associated PML. • MRI differences are probably related to higher levels of immunosuppression in HIV patients and those under rituximab therapy. Progressive multifocal leukoencephalopathy (PML) is a rare demyelinating disease of the central nervous system caused by reactivation of the JC polyomavirus (JCV). JCV is a ubiquitous polyomavirus, present in nearly 80% of the adult population [1] . Primary infection is asymptomatic and leads to viral persistence in infected hosts in different sites such as bone marrow and kidneys. JCV reactivation is triggered by a decrease in immunity [2] , more particularly in cell-mediated immunity [3] . PML incidence increased notably during the 1980s with the HIV pandemic supporting the hypothesis of the essential role played by cell-mediated immunity [1, 4] . Nowadays, PML is emerging as a complication of new effective immunosuppressive and immunomodulatory drugs [5] . Natalizumab is used as a treatment for multiple sclerosis (MS) and is associated with an increased risk of PML, estimated at 1/100 to 1/10,000 based on three identified risk factors (treatment duration longer than 24 months, anti-JCV antibody index, and prior administration of immunosuppressive therapies) [6] . Anti-JCV antibody levels in serum are indeed used to stratify PML risk in anti-JCV antibody-positive MS patients [6] . Natalizumab is a monoclonal antibody targeting the alpha-4 integrin that inhibits transmigration of T cells, including CD8 T cells, to and in the central nervous system, which can explain in part its role in PML through a decrease of immune control of JCV in the brain [1] . Two other characteristics are that natalizumab forces the migration of hematopoietic stem cells from the bone marrow in which JCV may be persistent and the upward regulation of B cell maturation factors that promote JCV growth [7] . Rituximab, an anti-CD20 monoclonal antibody targeting B cell activity and currently used for hematological malignancies and autoimmune disorders, is also associated with a moderately increased risk of PML estimated at 1/32,000 [8] . Rituximab acts by depleting B cells and modifying T cell activity, all of which supports a role of rituximab in PML development [9] . Knowledge of the MRI pattern of PML is essential when this diagnosis is suspected, especially in populations considered at risk, because the prognosis remains poor and is based on early treatment [10] , which consists exclusively so far in restoring the immune system. In the classic form widely described in the HIV population, PML manifests itself as white matter (WM) lesions affecting the U-shaped subcortical fibers with a decreased signal on T1weighted sequences and an increased signal on T2-weighted sequences. On diffusion-weighted images (DWI), the signal is generally increased with restricted diffusion on borders corresponding to active demyelination. Low signal on magnetic susceptibility sequences in U-fibers adjacent to the WM lesions of PML has been recently described and appears in relation to intracellular accumulation of iron in macrophages and glial cells during myelin degeneration [15] . Those lesions are often not enhanced and have little or no mass effect [11] . Previous studies have shown differences in the MRI pattern with natalizumab-associated PML (Table 1) . Indeed, with natalizumab, there are various inflammatory signs such as contrast enhancement and small punctuations in or adjacent to lesions with an increased signal on T2-weighted images and a perivascular distribution called "the milky way" [2, 16, 17] . The lesions have ill-defined boundaries towards WM and sharp boundaries towards gray matter (GM), with cortical GM more frequently involved [18] . A hypothesis to explain these results would be the difference in the level of immunosuppression induced by HIV and natalizumab. In this study, we first aimed to compare the MRI presentation of rituximab-associated PML to natalizumab or HIVassociated PML, and also analyze biological parameters to assess if the differences in MRI could be the consequence of different immunosuppression levels. This retrospective study was approved by our institutional review board. Inclusion criteria were (1) a "definite" PML diagnosis according to the American Academy of Neurology criteria [19] including clinical and imaging-compatible features and detection of JCV DNA in the cerebrospinal fluid or in brain tissue by polymerase chain reaction (PCR) or immunohistochemistry; (2) HIV-infected patients or patients treated with immunomodulatory or immunosuppressive drugs such as natalizumab or rituximab, possibly in association with other drugs and whatever the initial illness; and (3) consent was provided for in the hospital's charter. Exclusion criteria were patients diagnosed with PML from other causes than HIV infection or associated with other drugs than natalizumab or rituximab and those under 18 years of age. The occurrence of Immune Reconstitution Inflammatory Syndrome (IRIS) or an opportunistic infection was not a cause for exclusion. Classical demographic data such as gender, age at the time of diagnosis, and underlying illness were collected, as well as CD4 and CD8 numbers. Between 2008 and 2018, 87 patients from 16 centers in France and Luxembourg were retrospectively identified (Fig. 1 ). Of these 87 patients, 72 fulfilled all the inclusion criteria and were therefore included: 32 patients had relapsing-remitting MS and were treated with natalizumab, 20 patients were treated with rituximab (16 had a hematopoietic malignancy, 2 an autoimmune disorder, and 2 an immune deficiency), and 20 patients had an HIV infection. All patients underwent a multisequence MRI protocol. Due to the study's multicenter design, the explorations were carried out with diverging sequences, magnetic fields strength, acquisition parameters and parameters related to spatial resolution. We chose to define the first brain MRI performed at suspicion of PML as the reference examination for all comparisons. All MRIs were unblinded and reviewed by a junior radiologist (a trainee) with the assistance of an experienced senior neuroradiologist. To compare PML lesions, we described the location (frontal lobe, parietal lobe, occipital lobe, temporal lobe, basal ganglia, supra-or infratentorial or both), involvement of cortex and/or deep GM, distribution (unilobar involving a single lobe, multilobar involving more than one contiguous lobe, widespread involving more than two contiguous lobes or noncontiguous lobes or bilaterality), boundaries (sharp towards WM and GM, ill-defined towards WM and GM), lesion characteristics (aspect on T2-weighted images defined as homogeneous or microcystic corresponding to small lesions in or adjacent to the main PML lesions with an increased signal called the milky way; the presence or absence of a hyposignal on T2*/SWI/SWAN-weighted images, signal on DWI, and Statistical analysis was performed using R software, version 3.1, via the GMRC Shiny Stat application of the Strasbourg University Hospital (2017) and using the XLSTAT software in its Addinsoft 2016 version. We compared the MRI findings between the three groups using the chi-square test and between the NAT/RITUX, NAT/HIV, and RITUX/HIV groups using the chi-square test with Holm correction. We compared biological data between the three groups using the Shapiro test and between the NAT/RITUX, NAT/HIV, and RITUX/HIV groups using the Student t test with Holm correction. Median patient age (for all groups) was 49.0 years (range, . In the patient groups, the median age was 42.62 years for the natalizumab group (range, 26-53), 61.5 years for the rituximab group (range, 40-76) and 46.9 for the HIV group (range, 26-64). Forty men (55.6%) and 32 women (44.4%) were included in the study: 14 men (43.8%) and 18 women (56.2%) in the natalizumab group, 10 men and 10 women (50% each) in the rituximab group, and 16 men (80%) and 4 women (20%) in the HIV group. The imaging results are summarized in Table 2 and Table 3 . There was a statistically significant difference in supratentorial involvement between the three groups (78.1% in the natalizumab group, 85% in the rituximab group, and 40% in the HIV group (p = 0.003), especially when comparing the natalizumab group vs the HIV group (p = 0.0269) and the rituximab group vs the HIV group (p = 0.0269) with fewer supratentorial lesion locations in cases of PML occurring in an AIDS context. Concerning GM involvement, there was a significant difference between the three groups for the cortex (p < 0.001) and for the basal ganglia (p = 0.025). Post hoc analysis was only contributive for cortex involvement and showed a difference between the natalizumab group vs the HIV/rituximab groups with more cortex involvement in cases of PML that occurred under natalizumab treatment than the other two groups (p = 0.0036 for natalizumab vs rituximab and p = 0.0084 for natalizumab vs HIV). Analysis of the edges towards both WM and GM (Fig. 2 ) showed significant differences between groups. Indeed, lesions were more frequently clearly defined towards GM and ill-defined towards WM in the natalizumab group with no significant difference between the rituximab and HIV groups. The milky way aspect on T2-or FLAIR-weighted images ( Fig. 2) was significantly different between the three groups (p = 0.02) and more often seen in the natalizumab group vs the rituximab group (51.6% for natalizumab and 5% for rituximab [p = 0.005]). On DWI, the vast majority of PML lesions had an increased signal (90.9% for natalizumab, 89.5% for rituximab and 100% for HIV). We isolated cases with a peripheral signal in restriction of diffusion (corresponding to a decrease of the signal on ADC mapping), called the demyelination front. For this parameter, we observed a significant difference between natalizumab/rituximab (22.7% for natalizumab, 63.2% for rituximab [p = 0.0426]) and natalizumab/HIV (22.7% for natalizumab, 84.2% for HIV, [p < 0.001]) but none between the rituximab and HIV groups. (Fig. 3) . Lesions with a peripheral contrast enhancement showed a significant difference between the three groups (p = 0.003) and tended Fig. 1 Flow chart illustrating the patient selection and inclusion process. PML = progressive multifocal leukoencephalopathy, AAN = American Academy of Neurology to predominate in the rituximab group (45% in the rituximab group vs 19.4% in the natalizumab group and 10% in the HIV group). Lesions with micronodular enhancement were significantly different between the three groups (p = 0.003), with more cases in the natalizumab group versus the rituximab group (p = 0.0187). There was no difference between natalizumab and HIV groups even if there were more lesions of this type in the natalizumab group (51.6% vs 20% in the HIV group). Finally, for distant enhancement, there was a difference between the three groups (p < 0.001), specifically between natalizumab and rituximab (p = 0.0134) and the natalizumab and HIV (p = 0.0358) groups, with more of this type of enhancement in the natalizumab group (Fig. 4) . Non-enhanced lesions were significantly different between the three groups (p = 0.015), higher in the HIV groups with 80%. CD4/CD8 data were available for 10 patients in the natalizumab group, 12 in the rituximab group, and 15 in the HIV group (Fig. 5) This study aims to describe the MRI characteristics of PML associated with rituximab and natalizumab and in HIV infection while comparing imaging findings with the level of immunosuppression. We therefore compared CD4/CD8 ratios and found lower ratios in HIV-related PML compared to other groups, as well as a lower CD4/CD8 ratio in the rituximab group compared to the natalizumab group. This suggests that immunosuppression in rituximab is not as severe as in HIV-PM but still stronger than in natalizumab-PML. One of the characteristics of PML under natalizumab described in previous studies [2, 22] is the description of inflammatory signs such as microcystic lesions on T2-weighted images giving a Milky Way appearance [20, 23] . We found significantly more Milky Way lesions in the natalizumab group compared to the rituximab group but no significant difference between the natalizumab and HIV groups, even if they tended to predominate in the natalizumab group. The other "inflammatory" sign usually attributed to natalizumab-PML is contrast enhancement, estimated at 35 to 40% of patients in the literature [2] . In the present study, it accounted for 61.3% of the natalizumab group. A difference was observed between the three groups, especially when the enhancement was micronodular, similar to the Milky Way perivascular distribution predominating in the natalizumab group compared to the rituximab and HIV groups. By inducing a lower degree of immunosuppression compared to HIV, natalizumab-associated PML has more inflammatory signs. This could be due to the mode of action of this drug, which is a more selective immunomodulating agent [17] . We found more supratentorial involvement in drug-related PML than in the HIV-associated form where the brainstem and cerebellum are more likely to be affected. Cortical involvement and the typical aspect of the edges (sharp towards GM and ill-defined towards WM) are found preferentially in the natalizumab group, as also found in previous studies [18, 22] . There is no obvious explanation for these characteristics in relation to a difference in the level of immunosuppression. The proportion of hyposignal seen on T2*-or SWANweighted images at the cortical-subcortical junction adjacent to PML lesions (Fig. 6 ) did not differ between PML groups, in agreement with other studies [15, 21, 24] ; this sign seems nonspecific in PML for the underlying cause of immunosuppression. A demyelination front on diffusion-weighted images is often found with PML in the HIV group and in the rituximab group but more rarely in the natalizumab group. If the demyelination front is related to the active nature of the disease, we can hypothesize that the PML associated with rituximab is more like HIV-PML than natalizumab-PML, possibly due to closer immunosuppression levels [25] . The main limitations of this study are its retrospective and unblinded design as well as the limited number of patients analyzed with complete clinical, biological, and available imaging data. This is explained by the relative rarity of PML even in large referral centers. Secondly, due to the multicenter design of the study, the explorations were performed on different MRIs, both 1.5 T and 3 T and with nonstandardized protocols, and there were some inevitable variations in MRI acquisition parameters between patients [26] . Regarding the demographic data, we note that the age of the patients differs according to the group, with a tendency to younger patients in HIV and natalizumab groups. This may constitute a selection bias and is explained by the epidemiological data of the pathology studied, with MS and HIV affecting younger people compared to hematological malignancies. Fig. 3 In several cases of natalizumab-associated PML showing in (a) on FLAIR-weighted images, we can see GM and especially cortical involvement of the left parietal lobe adjacent to the WM lesion. The left thalamus is also the site of a demyelinating lesion. In b, we observe on T2-weighted images the Milky Way aspect with microcystic lesions with an increased signal. In c, clear sharp edges towards GM and ill-defined edges towards WM of the demyelinating lesions. In d, e, and f, brain MRI from a patient with natalizumab-associated PML showing in (d) a demyelinating right frontal lesion on FLAIR-weighted image with (e) contrast micronodular enhancement in the lesion and (f) remotely in the right temporal lobe. Finally, we can see an increased signal on diffusion-weighted images (h) with no rim in restriction on ADC mapping (g) MRI interpretation was made difficult by the coexistence of inflammatory lesions in the natalizumab group related to MS as well as by the coexistence of opportunistic infections (notably cerebral toxoplasmosis for three patients in the HIV group) and the occurrence of immune reconstitution inflammatory syndrome (in three Fig. 4 An example of a HIV-PML case with an infratentorial right cerebellar demyelinating lesion on a. In b, no contrast enhancement of this lesion. Diffusion-weighted images and ADC mapping of a patient showing an increased signal on diffusion (c) with a rim of demyelination in restriction of diffusion (d) Fig. 5 Box diagram of the extent of the CD4/CD8 ratio of patients by group patients in the HIV group after initiation of antiretroviral therapy). Concerning inclusion criteria, the vast majority of patients in the natalizumab group had already received immunosuppressive treatments before natalizumab treatment was initiated, as had those in the rituximab group, who often had several treatments acting on immunity before or at the same time as rituximab. However, in the present study, we did not make any distinction in the groups according to these possible treatments. Their impact on the MRI pattern of PML lesions is therefore not excluded. Two other factors may have come into play in the MRI pattern of PML under rituximab that we did not consider: first, the initial disease of the patient, which could be responsible for the development of PML, especially in the case of hematopoietic malignancies [27] . Secondly, the rigorous MRI follow-up of patients in the natalizumab group made it possible to detect PML at an earlier stage than in the HIV and rituximab groups. Adequate assessment of the quantitative and functional aspects of the global immune response is still a challenge in immunocompromised patients. In HIV-infected patients, the CD4/CD8 ratio is considered to be a good marker of the remaining immune response but may not be as relevant in other immunosuppressed groups such as patients treated with natalizumab or rituximab, irrespective of the underlying disease. The CD4/CD8 ratio does not incorporate the full level of immunosuppression-due to the diversity and complexity of the immune system; in our study, it indirectly and partially reflects the patient's immune status. Imaging features of rituximab-associated PML generally look more similar to those of the classically described PML with HIV than those related to natalizumab. Those similarities may be explained by a higher level of immunosuppression in HIV patients and patients treated with rituximab compared to patients treated with natalizumab. Statistics and biometry Nicolas Tuzin kindly provided statistical advice for this manuscript. Informed consent Written informed consent was not required for this study because patient consent was provided for in the hospital's charter. Ethical approval Institutional Review Board approval was obtained. • prospective • observational • multicenter study Progressive multi-focal leucoencephalopathydriven from rarity to clinical mainstream by iatrogenic immunodeficiency The chameleon of neuroinflammation: magnetic resonance imaging characteristics of natalizumab-associated progressive multifocal leukoencephalopathy Progressive multifocal leukoencephalopathy and immune reconstitution inflammatory syndrome (IRIS) Human polyomavirus reactivation: disease pathogenesis and treatment approaches Anti-JC virus antibodies: implications for PML risk stratification Stratification and monitoring of natalizumab-associated progressive multifocal leukoencephalopathy risk: recommendations from an expert group Pathogenesis of progressive multifocal leukoencephalopathy and risks associated with treatments for multiple sclerosis: a decade of lessons learned Progressive multifocal leukoencephalopathy and monoclonal antibodies: a review Progressive multifocal leukoencephalopathy secondary to rituximab-induced immunosuppression and the presence of John Cunningham virus: a case report and literature review Outcome and survival of asymptomatic PML in natalizumab-treated MS patients Imaging manifestations of progressive multifocal leukoencephalopathy Common and uncommon imaging findings in progressive multifocal leukoencephalopathy (PML) with differential diagnostic considerations Magnetic resonance imaging pattern in natalizumab-associated progressive multifocal leukoencephalopathy Immune reconstitution inflammatory syndrome unmasking or worsening AIDS-related progressive multifocal leukoencephalopathy: a literature review. Front Immunol 8:577 Low signal intensity in U-fiber identified by susceptibility-weighted imaging in two cases of progressive multifocal leukoencephalopathy Natalizumabassociated progressive multifocal leukoencephalopathy in patients with multiple sclerosis: lessons from 28 cases Inflammatory natalizumab-associated PML: baseline characteristics, lesion evolution and relation with PML-IRIS MRI pattern in asymptomatic natalizumab-associated PML PML diagnostic criteria: consensus statement from the AAN Neuroinfectious Disease Section Punctate lesion pattern suggestive of perivascular inflammation in acute natalizumab-associated progressive multifocal leukoencephalopathy: productive JC virus infection or preclinical PML-IRIS manifestation? Brain magnetic susceptibility changes in patients with natalizumab-associated progressive multifocal leukoencephalopathy Neuroimaging of natalizumab complications in multiple sclerosis: PML and other associated entities Punctate pattern: a promising imaging marker for the diagnosis of natalizumabassociated PML Susceptibility-weighted MR imaging hypointense rim in progressive multifocal Leukoencephalopathy: the end point of neuroinflammation and a potential outcome predictor Progressive multifocal leukoencephalopathy: diffusion-weighted imaging and pathological correlations Imaging working Group of the Observatoire Français de la Sclérose en plaques. OFSEP, a nationwide cohort of people with multiple sclerosis: consensus minimal MRI protocol Progressive multifocal leukoencephalopathy and anti-CD20 monoclonal antibodies: what do we know after 20 years of rituximab Publisher's note Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations Acknowledgments French Network for Ocular and CNS Lymphoma (LOC) and Nord-Est Neuro-Oncoly (NENO) Organisation.Funding The authors state that this work has not received any funding. Guarantor The scientific guarantor of this publication is Stephane Kremer. The authors of this manuscript declare no relationships with any companies whose products or services may be related to the subject matter of the article.