Your search keyword '"Jimenez Sanchez, S"' showing total 12 results

1. Study of interferences in B-hCG assay. A case report

Author

Sancho Fitos, E., Rosillo Coronado, M., Rodríguez Torres, A., Ouriach Makrini, S., Jiménez Sánchez, S., Alcázar García, L., García Cano, A., Arribas Gómez, I., Cortés Gómez, A., Caja Guayerbas, L., Martínez Cid, L., Olivares Romero, S., and Orejas Rodríguez-Marqués, P.

Published

2024

2. Valorization of steam-exploded wheat straw through a biorefinery approach: Bioethanol and bio-oil co-production

Author

Tomás-Pejó, E., Fermoso, J., Herrador, E., Hernando, H., Jiménez-Sánchez, S., Ballesteros, M., González-Fernández, C., and Serrano, D.P.

Published

2017

3. NMOSD and MS prevalence in the Indigenous populations of Australia and New Zealand

Author

Bukhari, W., Khalilidehkordi, E., Mason, D.F., Barnett, M.H., Taylor, B.V., Fabis-Pedrini, M., Kermode, A.G., Subramanian, S., Waters, P., Broadley, S.A., Abernethy, D., Bhuta, S., Blum, S., Boggild, M., Boundy, K., Brew, B.J., Brilot, F., Brownlee, W.J., Bundell, C.S., Butzkueven, H., Carroll, W.M., Chen, C., Clarke, L., Coulthard, A., Dale, R.C., Das, C., Dear, K., Fulcher, D., Gillis, D., Hawke, S., Heard, R., Henderson, A.P.D., Heshmat, S., Hodgkinson, S., Jimenez Sanchez, S., Kilpatrick, T.J., King, J., Kneebone, C., Kornberg, A.J., Lechner-Scott, J., Lin, M-W, Lynch, C., Macdonell, R.A.L., Marriott, M.P., McCombe, P.A., O’Gorman, C., Parratt, J.D.E., Pender, M.P., Pereira, J., Pollard, J.D., Prain, K.M., Ramanathan, S., Reddell, S.W., Shaw, C., Silvestrini, R.A., Slee, M., Spies, J., Stankovich, J., Sutton, I., Vincent, A., Vucic, S., Walsh, M., Willoughby, E., Wong, R.C., Woodhall, M., Yiu, E.M., Bukhari, W., Khalilidehkordi, E., Mason, D.F., Barnett, M.H., Taylor, B.V., Fabis-Pedrini, M., Kermode, A.G., Subramanian, S., Waters, P., Broadley, S.A., Abernethy, D., Bhuta, S., Blum, S., Boggild, M., Boundy, K., Brew, B.J., Brilot, F., Brownlee, W.J., Bundell, C.S., Butzkueven, H., Carroll, W.M., Chen, C., Clarke, L., Coulthard, A., Dale, R.C., Das, C., Dear, K., Fulcher, D., Gillis, D., Hawke, S., Heard, R., Henderson, A.P.D., Heshmat, S., Hodgkinson, S., Jimenez Sanchez, S., Kilpatrick, T.J., King, J., Kneebone, C., Kornberg, A.J., Lechner-Scott, J., Lin, M-W, Lynch, C., Macdonell, R.A.L., Marriott, M.P., McCombe, P.A., O’Gorman, C., Parratt, J.D.E., Pender, M.P., Pereira, J., Pollard, J.D., Prain, K.M., Ramanathan, S., Reddell, S.W., Shaw, C., Silvestrini, R.A., Slee, M., Spies, J., Stankovich, J., Sutton, I., Vincent, A., Vucic, S., Walsh, M., Willoughby, E., Wong, R.C., Woodhall, M., and Yiu, E.M.

Abstract

Background We studied the prevalence of neuromyelitis optica spectrum disorder (NMOSD) and multiple sclerosis (MS) in Indigenous populations of Australia and New Zealand with the aim of assessing potential differences. Methods Cases of possible NMOSD and MS were collected from Australia and New Zealand. Clinical details, MR imaging, and serologic results were used to apply 2015 IPND diagnostic criteria for NMOSD and 2010 McDonald criteria for MS. Frequencies of self-determined ethnic ancestry were calculated for confirmed NMOSD, suspected NMOSD, and MS. Prevalence rates for NMOSD and MS according to ancestry were compared. Results There were 75 cases with NMOSD, 89 with suspected NMSOD, and 101 with MS. NMOSD cases were more likely to have Asian, Indigenous, or Other ancestry compared to suspected NMOSD or MS. There were no differences in the clinical phenotype of NMOSD seen in Indigenous compared to European ancestry populations. Per 100,000, the prevalence estimate for NMOSD in people with Māori ancestry was 1.50 (95% CI 0.52–2.49) which was similar to those with Asian ancestry 1.57 (95% CI 1.15–1.98). NMOSD prevalence in Australian Aboriginal and Torres Strait Islander populations was 0.38 (95% CI 0.00–0.80) per 100,000. Conclusion The prevalence of NMOSD in the Māori population is similar to South East Asian countries, reflecting their historical origins. The prevalence of MS in this group is intermediate between those with South East Asian and European ancestry living in New Zealand. Both NMOSD and particularly MS appear to be uncommon in the Indigenous populations of Australia.

Published

2021

4. MRI Patterns Distinguish AQP4 Antibody Positive Neuromyelitis Optica Spectrum Disorder From Multiple Sclerosis

Author

Clarke, L, Arnett, S, Bukhari, W, Khalilidehkordi, E, Jimenez Sanchez, S, O'Gorman, C, Sun, J, Prain, KM, Woodhall, M, Silvestrini, R, Bundell, CS, Abernethy, DA, Bhuta, S, Blum, S, Boggild, M, Boundy, K, Brew, BJ, Brownlee, W, Butzkueven, H, Carroll, WM, Chen, C, Coulthard, A, Dale, RC, Das, C, Fabis-Pedrini, MJ, Gillis, D, Hawke, S, Heard, R, Henderson, APD, Heshmat, S, Hodgkinson, S, Kilpatrick, TJ, King, J, Kneebone, C, Kornberg, AJ, Lechner-Scott, J, Lin, MW, Lynch, C, Macdonell, RAL, Mason, DF, McCombe, PA, Pereira, J, Pollard, JD, Ramanathan, S, Reddel, SW, Shaw, Cameron, Spies, JM, Stankovich, J, Sutton, I, Vucic, S, Walsh, M, Wong, RC, Yiu, EM, Barnett, MH, Kermode, AGK, Marriott, MP, Parratt, JDE, Slee, M, Taylor, BV, Willoughby, E, Brilot, F, Vincent, A, Waters, P, Broadley, SA, Clarke, L, Arnett, S, Bukhari, W, Khalilidehkordi, E, Jimenez Sanchez, S, O'Gorman, C, Sun, J, Prain, KM, Woodhall, M, Silvestrini, R, Bundell, CS, Abernethy, DA, Bhuta, S, Blum, S, Boggild, M, Boundy, K, Brew, BJ, Brownlee, W, Butzkueven, H, Carroll, WM, Chen, C, Coulthard, A, Dale, RC, Das, C, Fabis-Pedrini, MJ, Gillis, D, Hawke, S, Heard, R, Henderson, APD, Heshmat, S, Hodgkinson, S, Kilpatrick, TJ, King, J, Kneebone, C, Kornberg, AJ, Lechner-Scott, J, Lin, MW, Lynch, C, Macdonell, RAL, Mason, DF, McCombe, PA, Pereira, J, Pollard, JD, Ramanathan, S, Reddel, SW, Shaw, Cameron, Spies, JM, Stankovich, J, Sutton, I, Vucic, S, Walsh, M, Wong, RC, Yiu, EM, Barnett, MH, Kermode, AGK, Marriott, MP, Parratt, JDE, Slee, M, Taylor, BV, Willoughby, E, Brilot, F, Vincent, A, Waters, P, and Broadley, SA

Abstract

Neuromyelitis optica spectrum disorder (NMOSD) and multiple sclerosis (MS) are inflammatory diseases of the CNS. Overlap in the clinical and MRI features of NMOSD and MS means that distinguishing these conditions can be difficult. With the aim of evaluating the diagnostic utility of MRI features in distinguishing NMOSD from MS, we have conducted a cross-sectional analysis of imaging data and developed predictive models to distinguish the two conditions. NMOSD and MS MRI lesions were identified and defined through a literature search. Aquaporin-4 (AQP4) antibody positive NMOSD cases and age- and sex-matched MS cases were collected. MRI of orbits, brain and spine were reported by at least two blinded reviewers. MRI brain or spine was available for 166/168 (99%) of cases. Longitudinally extensive (OR = 203), “bright spotty” (OR = 93.8), whole (axial; OR = 57.8) or gadolinium (Gd) enhancing (OR = 28.6) spinal cord lesions, bilateral (OR = 31.3) or Gd-enhancing (OR = 15.4) optic nerve lesions, and nucleus tractus solitarius (OR = 19.2), periaqueductal (OR = 16.8) or hypothalamic (OR = 7.2) brain lesions were associated with NMOSD. Ovoid (OR = 0.029), Dawson's fingers (OR = 0.031), pyramidal corpus callosum (OR = 0.058), periventricular (OR = 0.136), temporal lobe (OR = 0.137) and T1 black holes (OR = 0.154) brain lesions were associated with MS. A score-based algorithm and a decision tree determined by machine learning accurately predicted more than 85% of both diagnoses using first available imaging alone. We have confirmed NMOSD and MS specific MRI features and combined these in predictive models that can accurately identify more than 85% of cases as either AQP4 seropositive NMOSD or MS

Published

2021

5. Relapse Patterns in NMOSD: Evidence for Earlier Occurrence of Optic Neuritis and Possible Seasonal Variation

Author

Khalilidehkordi, E, Clarke, L, Arnett, S, Bukhari, W, Jimenez Sanchez, S, O'Gorman, C, Sun, J, Prain, KM, Woodhall, M, Silvestrini, R, Bundell, CS, Abernethy, D, Bhuta, S, Blum, S, Boggild, M, Boundy, K, Brew, BJ, Brown, M, Brownlee, W, Butzkueven, H, Carroll, WM, Chen, C, Coulthard, A, Dale, RC, Das, C, Fabis-Pedrini, MJ, Fulcher, D, Gillis, D, Hawke, S, Heard, R, Henderson, APD, Heshmat, S, Hodgkinson, S, Kilpatrick, TJ, King, J, Kneebone, C, Kornberg, AJ, Lechner-Scott, J, Lin, MW, Lynch, C, Macdonell, RAL, Mason, DF, McCombe, PA, Pereira, J, Pollard, JD, Ramanathan, S, Reddel, SW, Shaw, C, Spies, J, Stankovich, J, Sutton, I, Vucic, S, Walsh, M, Wong, RC, Yiu, EM, Barnett, MH, Kermode, AG, Marriott, MP, Parratt, J, Slee, M, Taylor, BV, Willoughby, E, Brilot, F, Vincent, A, Waters, P, Broadley, SA, Khalilidehkordi, E, Clarke, L, Arnett, S, Bukhari, W, Jimenez Sanchez, S, O'Gorman, C, Sun, J, Prain, KM, Woodhall, M, Silvestrini, R, Bundell, CS, Abernethy, D, Bhuta, S, Blum, S, Boggild, M, Boundy, K, Brew, BJ, Brown, M, Brownlee, W, Butzkueven, H, Carroll, WM, Chen, C, Coulthard, A, Dale, RC, Das, C, Fabis-Pedrini, MJ, Fulcher, D, Gillis, D, Hawke, S, Heard, R, Henderson, APD, Heshmat, S, Hodgkinson, S, Kilpatrick, TJ, King, J, Kneebone, C, Kornberg, AJ, Lechner-Scott, J, Lin, MW, Lynch, C, Macdonell, RAL, Mason, DF, McCombe, PA, Pereira, J, Pollard, JD, Ramanathan, S, Reddel, SW, Shaw, C, Spies, J, Stankovich, J, Sutton, I, Vucic, S, Walsh, M, Wong, RC, Yiu, EM, Barnett, MH, Kermode, AG, Marriott, MP, Parratt, J, Slee, M, Taylor, BV, Willoughby, E, Brilot, F, Vincent, A, Waters, P, and Broadley, SA

Abstract

Neuromyelitis optica spectrum disorders (NMOSD) and multiple sclerosis (MS) show overlap in their clinical features. We performed an analysis of relapses with the aim of determining differences between the two conditions. Cases of NMOSD and age- and sex-matched MS controls were collected from across Australia and New Zealand. Demographic and clinical information, including relapse histories, were recorded using a standard questionnaire. There were 75 cases of NMOSD and 101 MS controls. There were 328 relapses in the NMOSD cases and 375 in MS controls. Spinal cord and optic neuritis attacks were the most common relapses in both NMOSD and MS. Optic neuritis (p < 0.001) and area postrema relapses (P = 0.002) were more common in NMOSD and other brainstem attacks were more common in MS (p < 0.001). Prior to age 30 years, attacks of optic neuritis were more common in NMOSD than transverse myelitis. After 30 this pattern was reversed. Relapses in NMOSD were more likely to be treated with acute immunotherapies and were less likely to recover completely. Analysis by month of relapse in NMOSD showed a trend toward reduced risk of relapse in February to April compared to a peak in November to January (P = 0.065). Optic neuritis and transverse myelitis are the most common types of relapse in NMOSD and MS. Optic neuritis tends to occur more frequently in NMOSD prior to the age of 30, with transverse myelitis being more common thereafter. Relapses in NMOSD were more severe. A seasonal bias for relapses in spring-summer may exist in NMOSD.

Published

2020

6. Incidence and prevalence of NMOSD in Australia and New Zealand

Author

Bukhari, W., Prain, K.M., Waters, P., Woodhall, M., O‘Gorman, C.M., Clarke, L., Silvestrini, R.A., Bundell, C.S., Abernethy, D., Bhuta, S., Blum, S., Boggild, M., Boundy, K., Brew, B.J., Brown, M., Brownlee, W.J., Butzkueven, H., Carroll, W.M., Chen, C., Coulthard, A., Dale, R.C., Das, C., Dear, K., Fabis-Pedrini, M.J., Fulcher, D., Gillis, D., Hawke, S., Heard, R., Henderson, A.P.D., Heshmat, S., Hodgkinson, S., Jimenez-Sanchez, S., Killpatrick, T., King, J., Kneebone, C., Kornberg, A.J., Lechner-Scott, J., Lin, M., Lynch, C., Macdonell, R., Mason, D.F., McCombe, P.A., Pender, M.P., Pereira, J.A., Pollard, J.D., Reddel, S.W., Shaw, C., Spies, J., Stankovich, J., Sutton, I., Vucic, S., Walsh, M., Wong, R.C., Yiu, E.M., Barnett, M.H., Kermode, A.G., Marriott, M.P., Parratt, J.D.E., Slee, M., Taylor, B.V., Willoughby, E., Wilson, R.J., Vincent, A., Broadley, S.A., Bukhari, W., Prain, K.M., Waters, P., Woodhall, M., O‘Gorman, C.M., Clarke, L., Silvestrini, R.A., Bundell, C.S., Abernethy, D., Bhuta, S., Blum, S., Boggild, M., Boundy, K., Brew, B.J., Brown, M., Brownlee, W.J., Butzkueven, H., Carroll, W.M., Chen, C., Coulthard, A., Dale, R.C., Das, C., Dear, K., Fabis-Pedrini, M.J., Fulcher, D., Gillis, D., Hawke, S., Heard, R., Henderson, A.P.D., Heshmat, S., Hodgkinson, S., Jimenez-Sanchez, S., Killpatrick, T., King, J., Kneebone, C., Kornberg, A.J., Lechner-Scott, J., Lin, M., Lynch, C., Macdonell, R., Mason, D.F., McCombe, P.A., Pender, M.P., Pereira, J.A., Pollard, J.D., Reddel, S.W., Shaw, C., Spies, J., Stankovich, J., Sutton, I., Vucic, S., Walsh, M., Wong, R.C., Yiu, E.M., Barnett, M.H., Kermode, A.G., Marriott, M.P., Parratt, J.D.E., Slee, M., Taylor, B.V., Willoughby, E., Wilson, R.J., Vincent, A., and Broadley, S.A.

Abstract

OBJECTIVES: We have undertaken a clinic-based survey of neuromyelitis optica spectrum disorders (NMOSDs) in Australia and New Zealand to establish incidence and prevalence across the region and in populations of differing ancestry. BACKGROUND: NMOSD is a recently defined demyelinating disease of the central nervous system (CNS). The incidence and prevalence of NMOSD in Australia and New Zealand has not been established. METHODS: Centres managing patients with demyelinating disease of the CNS across Australia and New Zealand reported patients with clinical and laboratory features that were suspicious for NMOSD. Testing for aquaporin 4 antibodies was undertaken in all suspected cases. From this group, cases were identified who fulfilled the 2015 Wingerchuk diagnostic criteria for NMOSD. A capture-recapture methodology was used to estimate incidence and prevalence, based on additional laboratory identified cases. RESULTS: NMOSD was confirmed in 81/170 (48%) cases referred. Capture-recapture analysis gave an adjusted incidence estimate of 0.37 (95% CI 0.35 to 0.39) per million per year and a prevalence estimate for NMOSD of 0.70 (95% CI 0.61 to 0.78) per 100 000. NMOSD was three times more common in the Asian population (1.57 (95% CI 1.15 to 1.98) per 100 000) compared with the remainder of the population (0.57 (95% CI 0.50 to 0.65) per 100 000). The latitudinal gradient evident in multiple sclerosis was not seen in NMOSD. CONCLUSIONS: NMOSD incidence and prevalence in Australia and New Zealand are comparable with figures from other populations of largely European ancestry. We found NMOSD to be more common in the population with Asian ancestry.

Published

2017

7. Community screening campaign for Strongyloides stercoralis among Latin American immigrants in Spain

Author

Monge-Maillo, B., Navarro, M., Rodríguez, E., Ramos Rincón, J.M., Chamorro Tojeiro, S., Jiménez Sánchez, S., Casas del Corral, M.J., and López-Vélez, R.

Published

2018

8. The role of alemtuzumab in the development of secondary autoimmunity in multiple Sclerosis: a systematic review.

Author

Jimenez-Sanchez S, Maksoud R, Eaton-Fitch N, Marshall-Gradisnik S, and Broadley SA

Subjects

Humans, Autoimmunity drug effects, Autoimmunity immunology, Autoimmune Diseases chemically induced, Autoimmune Diseases immunology, Immunologic Factors adverse effects, Immunologic Factors therapeutic use, Alemtuzumab adverse effects, Alemtuzumab therapeutic use, Multiple Sclerosis drug therapy, Multiple Sclerosis immunology

Abstract

Background: Secondary autoimmune disease (SAID) in the context of alemtuzumab treatment is one of the main safety concerns that may arise following administration in people with multiple sclerosis (pwMS). Contributing factors underlying this adverse event are not well understood. The purpose of this systematic review was to appraise the literature investigating the role of alemtuzumab in the development of SAID in pwMS following treatment and identify potential biomarkers/ risk factors that may be predictive of onset of this manifestation., Methods: Relevant publications were retrieved from PubMed, Embase, and Web of Science using a three-pronged search strategy containing the following keywords: "multiple sclerosis"; "alemtuzumab"; and "autoimmunity". Studies that fulfilled the specified eligibility criteria and investigated SAID development after alemtuzumab in pwMS were included in the final analysis., Results: 19 papers were included in the final review. Approximately, 47.92% of pwMS treated with alemtuzumab experienced SAID. A variety of biomarkers and risk factors were noted in the development of SAID, with a focus on immunological changes, including: increased homeostatic proliferation and T cell cycling, along with consistently elevated baseline serum IL-21 levels and thyroid autoantibodies. There was no significant association between known human leukocyte antigen (HLA) risk alleles, lymphocyte profile or dynamics and SAID development., Conclusions: While the mechanism underlying SAID following alemtuzumab is not fully understood, potential biomarkers and risk factors that may assist in elucidating mechanisms underlying this phenomenon have been documented in several independent studies. Following immunodepletion from alemtuzumab, an IL-21 driven increase in homeostatic proliferation and T cell cycling may disrupt tolerance mechanisms leading to an increase in the propensity toward alemtuzumab-induced autoimmunity. Further research is necessary to clarify the physiological changes after alemtuzumab therapy that trigger SAID in pwMS., (© 2024. The Author(s).)

Published

2024

9. MRI Patterns Distinguish AQP4 Antibody Positive Neuromyelitis Optica Spectrum Disorder From Multiple Sclerosis.

Author

Clarke L, Arnett S, Bukhari W, Khalilidehkordi E, Jimenez Sanchez S, O'Gorman C, Sun J, Prain KM, Woodhall M, Silvestrini R, Bundell CS, Abernethy DA, Bhuta S, Blum S, Boggild M, Boundy K, Brew BJ, Brownlee W, Butzkueven H, Carroll WM, Chen C, Coulthard A, Dale RC, Das C, Fabis-Pedrini MJ, Gillis D, Hawke S, Heard R, Henderson APD, Heshmat S, Hodgkinson S, Kilpatrick TJ, King J, Kneebone C, Kornberg AJ, Lechner-Scott J, Lin MW, Lynch C, Macdonell RAL, Mason DF, McCombe PA, Pereira J, Pollard JD, Ramanathan S, Reddel SW, Shaw CP, Spies JM, Stankovich J, Sutton I, Vucic S, Walsh M, Wong RC, Yiu EM, Barnett MH, Kermode AGK, Marriott MP, Parratt JDE, Slee M, Taylor BV, Willoughby E, Brilot F, Vincent A, Waters P, and Broadley SA

Abstract

Neuromyelitis optica spectrum disorder (NMOSD) and multiple sclerosis (MS) are inflammatory diseases of the CNS. Overlap in the clinical and MRI features of NMOSD and MS means that distinguishing these conditions can be difficult. With the aim of evaluating the diagnostic utility of MRI features in distinguishing NMOSD from MS, we have conducted a cross-sectional analysis of imaging data and developed predictive models to distinguish the two conditions. NMOSD and MS MRI lesions were identified and defined through a literature search. Aquaporin-4 (AQP4) antibody positive NMOSD cases and age- and sex-matched MS cases were collected. MRI of orbits, brain and spine were reported by at least two blinded reviewers. MRI brain or spine was available for 166/168 (99%) of cases. Longitudinally extensive (OR = 203), "bright spotty" (OR = 93.8), whole (axial; OR = 57.8) or gadolinium (Gd) enhancing (OR = 28.6) spinal cord lesions, bilateral (OR = 31.3) or Gd-enhancing (OR = 15.4) optic nerve lesions, and nucleus tractus solitarius (OR = 19.2), periaqueductal (OR = 16.8) or hypothalamic (OR = 7.2) brain lesions were associated with NMOSD. Ovoid (OR = 0.029), Dawson's fingers (OR = 0.031), pyramidal corpus callosum (OR = 0.058), periventricular (OR = 0.136), temporal lobe (OR = 0.137) and T1 black holes (OR = 0.154) brain lesions were associated with MS. A score-based algorithm and a decision tree determined by machine learning accurately predicted more than 85% of both diagnoses using first available imaging alone. We have confirmed NMOSD and MS specific MRI features and combined these in predictive models that can accurately identify more than 85% of cases as either AQP4 seropositive NMOSD or MS., Competing Interests: MHB has received research support, speaking engagement honoraria, advisory board honoraria and travel sponsorship from Biogen Idec, Merck, Novartis, Roche and Sanofi-Genzyme, and is a consulting neurologist for RxMx and is Research Director of the Sydney Neuroimaging Analysis Centre. MB has received travel sponsorship and honoraria from Sanofi-Genzyme, Teva, Novartis, Biogen Idec and Roche. BB has received honoraria as a board member for GlaxoSmithKline, Biogen Idec, ViiV Healthcare and Merck Serono, has received speaker honoraria from ViiV Healthcare, Boehringer Ingelheim, Abbott, Abbvie, and Biogen Idec; has received travel sponsorship from Abbott and ViiV Healthcare, and has received research support funding from EI Lilly, GlaxoSmithKline, ViiV Healthcare and Merck Serono. FB has received speaker's honoraria from Biogen-Idec and EMD Serono. SAB has received honoraria for attendance at advisory boards and travel sponsorship from Bayer-Schering, Biogen-Idec, Merck-Serono, Novartis, and Sanofi-Genzyme, has received speakers honoraria from Biogen-Idec and Genzyme, is an investigator in clinical trials sponsored by Biogen Idec, Novartis and Genzyme, and was the recipient of an unencumbered research grant from Biogen-Idec. HB has received honoraria for serving on scientific advisory boards for Biogen Idec, Novartis and Sanofi-Genzyme, has received conference travel sponsorship from Novartis and Biogen Idec, has received honoraria for speaking and acting as Chair at educational events organised by Novartis, Biogen Idec, Medscape and Merck Serono, serves on steering committees for trials conducted by Biogen Idec and Novartis, is chair (honorary) of the MSBase Foundation, which has received research support from Merck Serono, Novartis, Biogen Idec, Genzyme Sanofi and CSL Biopharma and has received research support form Merck Serono. WC has been the recipient of travel sponsorship from, and provided advice to, Bayer Schering Pharma, Biogen-Idec, Novartis, Genzyme, Sanofi-Aventis, BioCSL and Merck-Serono. RD has received research funding from the National Health and Medical Research Council, MS Research Australia, Star Scientific Foundation, Pfizer Neuroscience, Tourette Syndrome Association, University of Sydney, and the Petre Foundation and has received honoraria from Biogen-Idec and Bristol-Myers Squibb as an invited speaker. MF-P has received travel sponsorship from Biogen Australia and New Zealand. RH has received honoraria, educational support and clinic funding from Novartis, Biogen Idec, Genzyme and BioCSL. AGKK has received scientific consulting fees and/or lecture honoraria from Bayer, BioCSL, Biogen-Idec, Genzyme, Lgpharma, Merck, Mitsubishi Tanabe Pharma, NeuroScientific Biopharmaceuticals, Novartis, Roche, Sanofi-Aventis, and Teva. TK has received travel sponsorship from Novartis, BioCSL, Novartis, Merck Serono and Biogen Idec, has received speaker honoraria from Biogen Idec, BioCSL, Merck Serono, Teva, Genzyme and Novartis, has received research support from Biogen Idec, Genzyme, GlaxoSmithKline, Bayer-Schering and Merck Serono, and has received scientific consulting fees from GlaxoSmithKline China, Biogen-Idec and Novartis. JK has received remuneration for advisory board activities and presentations from Bayer Healthcare, Biogen Idec, BioCSL, Genzyme and Novartis. CK has received travel support, honoraria and advisory board payments from Biogen Idec, Bayer, Genzyme, Novartis and Serono. JL-S has received unencumbered funding as well as honoraria for presentations and membership on advisory boards from Sanofi Aventis, Biogen Idec, Bayer Health Care, CSL, Genzyme, Merck Serono, Novartis Australia and Teva. RM has received honoraria for attendance at advisory boards and travel sponsorship from Bayer-Schering, Biogen-Idec, CSL, Merck-Serono, Novartis, and Sanofi-Genzyme. MM has received travel sponsorship, honoraria, trial payments, research and clinical support from Bayer Schering, Biogen Idec, BioCSL, Genzyme, Novartis, and Sanofi Aventis Genzyme. DM has received honoraria for attendance at advisory boards from Biogen-Idec and Novartis, and travel sponsorship from Bayer-Schering, Biogen-Idec, and Sanofi-Genzyme. PM has received honoraria or travel sponsorship from Novartis, Sanofi-Aventis and Biogen Idec. JP has received travel sponsorship, honoraria for presentations and membership on advisory boards from Biogen Idec and Novartis and Sanofi Aventis. JDP has received honoraria for seminars or advisory boards from Teva, Biogen, Sanofi-Genzyme, Novartis, Merck, Bayer and research grants or fellowships from Merck, Novartis, Bayer, Biogen, Sanofi-Genzyme, and Teva. SR has received honoraria for advisory consultancy from UCB and speaker's honoraria from Biogen Idec. SWR has received travel sponsorship, honoraria, trial payments, research and clinical support from Aspreva, Baxter, Bayer Schering, Biogen Idec, BioCSL, Genzyme, Novartis, Sanofi Aventis Genzyme and Servier, and is a director of Medical Safety Systems Pty Ltd. CPS has received travel sponsorship from Biogen Idec, Novartis and Bayer-Schering. IS has received remuneration for Advisory Board activities from Biogen, CSL, and Bayer Schering and educational activities with Biogen, CSL and travel sponsorship from Biogen, Novartis and Bayer Schering. JMS has received honoraria for lectures and participation in advisory boards, and travel sponsorship from Novartis, BioCSL, Genzyme, and Biogen Idec. BT has received travel sponsorship from Novartis and Bayer Schering. AV and the University of Oxford hold patents and receive royalties for antibody testing. PW and the University of Oxford hold patents for antibody assays and have received royalties, has received honoraria from Alexion, Biogen Idec F. Hoffmann-La Roche, Retrogenix, UBC and Euroimmun AG, and travel grants from the Guthy-Jackson Charitable Foundation. EW has received honoraria for participation in advisory boards from Biogen-Idec and Novartis, travel sponsorship from Biogen-Idec, Bayer-Schering and Teva and is an investigator in clinical trials funded by Biogen-Idec and Teva. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest., (Copyright © 2021 Clarke, Arnett, Bukhari, Khalilidehkordi, Jimenez Sanchez, O'Gorman, Sun, Prain, Woodhall, Silvestrini, Bundell, Abernethy, Bhuta, Blum, Boggild, Boundy, Brew, Brownlee, Butzkueven, Carroll, Chen, Coulthard, Dale, Das, Fabis-Pedrini, Gillis, Hawke, Heard, Henderson, Heshmat, Hodgkinson, Kilpatrick, King, Kneebone, Kornberg, Lechner-Scott, Lin, Lynch, Macdonell, Mason, McCombe, Pereira, Pollard, Ramanathan, Reddel, Shaw, Spies, Stankovich, Sutton, Vucic, Walsh, Wong, Yiu, Barnett, Kermode, Marriott, Parratt, Slee, Taylor, Willoughby, Brilot, Vincent, Waters and Broadley.)

Published

2021

10. Relapse Patterns in NMOSD: Evidence for Earlier Occurrence of Optic Neuritis and Possible Seasonal Variation.

Author

Khalilidehkordi E, Clarke L, Arnett S, Bukhari W, Jimenez Sanchez S, O'Gorman C, Sun J, Prain KM, Woodhall M, Silvestrini R, Bundell CS, Abernethy D, Bhuta S, Blum S, Boggild M, Boundy K, Brew BJ, Brown M, Brownlee W, Butzkueven H, Carroll WM, Chen C, Coulthard A, Dale RC, Das C, Fabis-Pedrini MJ, Fulcher D, Gillis D, Hawke S, Heard R, Henderson APD, Heshmat S, Hodgkinson S, Kilpatrick TJ, King J, Kneebone C, Kornberg AJ, Lechner-Scott J, Lin MW, Lynch C, Macdonell RAL, Mason DF, McCombe PA, Pereira J, Pollard JD, Ramanathan S, Reddel SW, Shaw C, Spies J, Stankovich J, Sutton I, Vucic S, Walsh M, Wong RC, Yiu EM, Barnett MH, Kermode AG, Marriott MP, Parratt J, Slee M, Taylor BV, Willoughby E, Brilot F, Vincent A, Waters P, and Broadley SA

Abstract

Neuromyelitis optica spectrum disorders (NMOSD) and multiple sclerosis (MS) show overlap in their clinical features. We performed an analysis of relapses with the aim of determining differences between the two conditions. Cases of NMOSD and age- and sex-matched MS controls were collected from across Australia and New Zealand. Demographic and clinical information, including relapse histories, were recorded using a standard questionnaire. There were 75 cases of NMOSD and 101 MS controls. There were 328 relapses in the NMOSD cases and 375 in MS controls. Spinal cord and optic neuritis attacks were the most common relapses in both NMOSD and MS. Optic neuritis ( p < 0.001) and area postrema relapses ( P = 0.002) were more common in NMOSD and other brainstem attacks were more common in MS ( p < 0.001). Prior to age 30 years, attacks of optic neuritis were more common in NMOSD than transverse myelitis. After 30 this pattern was reversed. Relapses in NMOSD were more likely to be treated with acute immunotherapies and were less likely to recover completely. Analysis by month of relapse in NMOSD showed a trend toward reduced risk of relapse in February to April compared to a peak in November to January ( P = 0.065). Optic neuritis and transverse myelitis are the most common types of relapse in NMOSD and MS. Optic neuritis tends to occur more frequently in NMOSD prior to the age of 30, with transverse myelitis being more common thereafter. Relapses in NMOSD were more severe. A seasonal bias for relapses in spring-summer may exist in NMOSD., (Copyright © 2020 Khalilidehkordi, Clarke, Arnett, Bukhari, Jimenez Sanchez, O'Gorman, Sun, Prain, Woodhall, Silvestrini, Bundell, Abernethy, Bhuta, Blum, Boggild, Boundy, Brew, Brown, Brownlee, Butzkueven, Carroll, Chen, Coulthard, Dale, Das, Fabis-Pedrini, Fulcher, Gillis, Hawke, Heard, Henderson, Heshmat, Hodgkinson, Kilpatrick, King, Kneebone, Kornberg, Lechner-Scott, Lin, Lynch, Macdonell, Mason, McCombe, Pereira, Pollard, Ramanathan, Reddel, Shaw, Spies, Stankovich, Sutton, Vucic, Walsh, Wong, Yiu, Barnett, Kermode, Marriott, Parratt, Slee, Taylor, Willoughby, Brilot, Vincent, Waters and Broadley.)

Published

2020

11. The clinical profile of NMOSD in Australia and New Zealand.

Author

Bukhari W, Clarke L, O'Gorman C, Khalilidehkordi E, Arnett S, Prain KM, Woodhall M, Silvestrini R, Bundell CS, Ramanathan S, Abernethy D, Bhuta S, Blum S, Boggild M, Boundy K, Brew BJ, Brownlee W, Butzkueven H, Carroll WM, Chen C, Coulthard A, Dale RC, Das C, Dear K, Fabis-Pedrini MJ, Fulcher D, Gillis D, Hawke S, Heard R, Henderson APD, Heshmat S, Hodgkinson S, Jimenez-Sanchez S, Kilpatrick TJ, King J, Kneebone C, Kornberg AJ, Lechner-Scott J, Lin MW, Lynch C, Macdonnell RAL, Mason DF, McCombe PA, Pereira J, Pollard JD, Reddel SW, Shaw C, Spies J, Stankovich J, Sutton I, Vucic S, Walsh M, Wong RC, Yiu EM, Barnett MH, Kermode AG, Marriott MP, Parratt J, Slee M, Taylor BV, Willoughby E, Wilson RJ, Brilot F, Vincent A, Waters P, and Broadley SA

Subjects

Adult, Aged, Australia, Female, Health Surveys, Humans, Male, Middle Aged, Neuromyelitis Optica diagnostic imaging, New Zealand, Young Adult, Neuromyelitis Optica metabolism, Neuromyelitis Optica pathology, Neuromyelitis Optica physiopathology

Abstract

Neuromyelitis optica spectrum disorders (NMOSD) are an inflammation of the central nervous system associated with autoantibodies to aquaporin-4. We have undertaken a clinic-based survey of NMOSD in the Australia and New Zealand populations with the aim of characterising the clinical features and establishing the value of recently revised diagnostic criteria. Cases of possible NMOSD and age and sex-matched controls with multiple sclerosis (MS) were referred from centres across Australia and New Zealand. Cases were classified as NMOSD if they met the 2015 IPND criteria and remained as suspected NMOSD if they did not. Clinical and paraclinical data were compared across the three groups. NMOSD was confirmed in 75 cases and 89 had suspected NMOSD. There were 101 controls with MS. Age at onset, relapse rates and EDSS scores were significantly higher in NMOSD than in MS. Lesions and symptoms referable to the optic nerve were more common in NMOSD whereas brainstem, cerebellar and cerebral lesions were more common in MS. Longitudinally extensive spinal cord lesions were seen in 48/71 (68%) of cases with NMOSD. Elevations of CSF, white cell count and protein were more common in NMOSD. We have confirmed a clinical pattern of NMOSD that has been seen in several geographical regions. We have demonstrated the clinical utility of the current diagnostic criteria. Distinct patterns of disease are evident in NMOSD and MS, but there remains a large number of patients with NMOSD-like features who do not meet the current diagnostic criteria for NMOSD and remain a diagnostic challenge.

Published

2020

12. Incidence and prevalence of NMOSD in Australia and New Zealand.

Author

Bukhari W, Prain KM, Waters P, Woodhall M, O'Gorman CM, Clarke L, Silvestrini RA, Bundell CS, Abernethy D, Bhuta S, Blum S, Boggild M, Boundy K, Brew BJ, Brown M, Brownlee WJ, Butzkueven H, Carroll WM, Chen C, Coulthard A, Dale RC, Das C, Dear K, Fabis-Pedrini MJ, Fulcher D, Gillis D, Hawke S, Heard R, Henderson APD, Heshmat S, Hodgkinson S, Jimenez-Sanchez S, Killpatrick T, King J, Kneebone C, Kornberg AJ, Lechner-Scott J, Lin MW, Lynch C, Macdonell R, Mason DF, McCombe PA, Pender MP, Pereira JA, Pollard JD, Reddel SW, Shaw C, Spies J, Stankovich J, Sutton I, Vucic S, Walsh M, Wong RC, Yiu EM, Barnett MH, Kermode AG, Marriott MP, Parratt JDE, Slee M, Taylor BV, Willoughby E, Wilson RJ, Vincent A, and Broadley SA

Subjects

Adult, Aged, Asian People, Australia epidemiology, Female, Humans, Incidence, Male, Middle Aged, New Zealand epidemiology, Prevalence, Aquaporin 4 immunology, Neuromyelitis Optica epidemiology

Abstract

Objectives: We have undertaken a clinic-based survey of neuromyelitis optica spectrum disorders (NMOSDs) in Australia and New Zealand to establish incidence and prevalence across the region and in populations of differing ancestry., Background: NMOSD is a recently defined demyelinating disease of the central nervous system (CNS). The incidence and prevalence of NMOSD in Australia and New Zealand has not been established., Methods: Centres managing patients with demyelinating disease of the CNS across Australia and New Zealand reported patients with clinical and laboratory features that were suspicious for NMOSD. Testing for aquaporin 4 antibodies was undertaken in all suspected cases. From this group, cases were identified who fulfilled the 2015 Wingerchuk diagnostic criteria for NMOSD. A capture-recapture methodology was used to estimate incidence and prevalence, based on additional laboratory identified cases., Results: NMOSD was confirmed in 81/170 (48%) cases referred. Capture-recapture analysis gave an adjusted incidence estimate of 0.37 (95% CI 0.35 to 0.39) per million per year and a prevalence estimate for NMOSD of 0.70 (95% CI 0.61 to 0.78) per 100 000. NMOSD was three times more common in the Asian population (1.57 (95% CI 1.15 to 1.98) per 100 000) compared with the remainder of the population (0.57 (95% CI 0.50 to 0.65) per 100 000). The latitudinal gradient evident in multiple sclerosis was not seen in NMOSD., Conclusions: NMOSD incidence and prevalence in Australia and New Zealand are comparable with figures from other populations of largely European ancestry. We found NMOSD to be more common in the population with Asian ancestry., Competing Interests: Competing interests: MHB has received honoraria for participation in advisory boards and travel sponsorship from Novartis, BioCSL, Genzyme and Biogen Idec. MBo has received travel sponsorship and honoraria from Sanofi-Genzyme, Teva, Novartis, BiogenIdec and Roche. BJB has received honoraria as a board member for GlaxoSmithKline, Biogen Idec, ViiV Healthcare and Merck Serono, has received speaker honoraria from ViiV Healthcare, Boehringer Ingelheim, Abbott, AbbVie and Biogen Idec, has received travel sponsorship from Abbott and ViiV Healthcare and has received research support funding from EIi Lilly, GlaxoSmithKline, ViiV Healthcare and Merck Serono. SAB has received honoraria for attendance at advisory boards and travel sponsorship from Bayer Schering Pharma, BiogenIdec, Merck Serono, Novartis and Sanofi-Genzyme, has received speaker honoraria from Biogen Idec and Genzyme, is an investigator in clinical trials sponsored by Biogen Idec, Novartis and Genzyme and was the recipient of an unencumbered research grant from Biogen Idec. HB has received honoraria for serving on scientific advisory boards for Biogen Idec, Novartis and Sanofi-Genzyme, has received conference travel sponsorship from Novartis and Biogen Idec, has received honoraria for speaking and acting as Chair at educational events organised by Novartis, Biogen Idec, Medscape and Merck Serono, serves on steering committees for trials conducted by Biogen Idec and Novartis, is chair (honorary) of the MSBase Foundation, which has received research support from Merck Serono, Novartis, Biogen Idec, Genzyme Sanofi and CSL Biopharma and has received research support form Merck Serono. WMC has been the recipient of travel sponsorship from, and provided advice to, Bayer Schering Pharma, BiogenIdec, Novartis, Genzyme, Sanofi-Aventis, BioCSL and Merck Serono. RCD has received research funding from the National Health and Medical Research Council, MS Research Australia, Star Scientific Foundation, Pfizer Neuroscience, Tourette Syndrome Association, University of Sydney and the Petre Foundation and has received honoraria from Biogen Idec and Bristol-Myers Squibb as an invited speaker. MjF-P has received travel sponsorship from Biogen Australia and New Zealand. RH has received honoraria, educational support and clinic funding from Novartis, Biogen Idec, Genzyme and BioCSL. AGK has received scientific consulting fees and/or lecture honoraria from Bayer, BioCSL, BiogenIdec, Genzyme, Merck, Novartis, Sanofi-Aventis and Teva. TJK has received travel sponsorship from Novartis, BioCSL, Novartis, Merck Serono and BiogenIdec, has received speaker honoraria from Biogen Idec, BioCSL, Merck Serono, Teva, Genzyme and Novartis, has received research support from Biogen Idec, Genzyme, GlaxoSmithKline, Bayer Schering Pharma and Merck Serono and has received scientific consulting fees from GlaxoSmithKline China, Biogen Idec and Novartis. JK has received remuneration for advisory board activities and presentations from Bayer Healthcare, Biogen Idec, BioCSL, Genzyme and Novartis. CK has received travel support, honoraria and advisory board payments from Biogen Idec, Bayer,Genzyme, Novartis and Serono. JL-S has received unencumbered funding as well as honoraria for presentations and membership on advisory boards from Sanofi-Aventis, Biogen Idec, Bayer Health Care, CSL, Genzyme, Merck Serono, Novartis Australia and Teva. RALM has received honoraria for attendance at advisory boards and travel sponsorship from Bayer Schering Pharma, Biogen Idec, CSL, Merck Serono, Novartis and Sanofi-Genzyme. MPMa has received travel sponsorship, honoraria, trial payments, research and clinical support from Bayer Schering Pharma, Biogen Idec, BioCSL, Genzyme, Novartis and Sanofi-Aventis Genzyme. DFM has received honoraria for attendance at advisory boards from Biogen Idec and Novartis, and travel sponsorship from Bayer Schering Pharma, Biogen Idec and Sanofi-Genzyme. PAMcC has received honoraria or travel sponsorship from Novartis, Sanofi-Aventis and Biogen Idec. JAP has received travel sponsorship, honoraria for presentations and membership on advisory boards from Biogen Idec and Novartis and Sanofi-Aventis. JDP has received honoraria for seminars or advisory boards from Teva, Biogen, Sanofi-Genzyme, Novartis, Merck, Bayer and research grants or fellowships from Merck, Novartis, Bayer, Biogen, Sanofi-Genzyme and Teva. SWR has received travel sponsorship, honoraria, trial payments, research and clinical support from Aspreva, Baxter, Bayer Schering Pharma, Biogen Idec, BioCSL, Genzyme, Novartis, Sanofi-Aventis Genzyme and Servier, and is a director of Medical Safety Systems Pty Ltd. CPS has received travel sponsorship from Biogen Idec, Novartis and Bayer Schering Pharma. IS has received remuneration for Advisory Board activities from Biogen, CSL and Bayer Schering Pharma and educational activities with Biogen, CSL and travel sponsorship from Biogen, Novartis and Bayer Schering Pharma. MS has received research support from Novartis, Biogen Idec and BioCSL. JSp has received honoraria for lectures and participation in advisory boards, and travel sponsorship from Novartis, BioCSL, Genzyme and Biogen Idec. BVT has received travel sponsorship from Novartis and Bayer Schering Pharma. AV and the University of Oxford hold patents and receive royalties for antibody testing. PW and the University of Oxford hold patents for antibody assays and have received royalties, has received speaker honoraria from Biogen Idec and Euroimmun AG and travel grants from the Guthy-Jackson Charitable Foundation. EW has received honoraria for participation in advisory boards from Biogen Idec and Novartis, travel sponsorship from Biogen Idec, Bayer Schering Pharma and Teva and is an investigator in clinical trials funded by Biogen Idec and Teva. DA, SBh, SBl, KB, MBr, WBr, WBu, CSB, CCM, LC, AC, CD, KD, DF, DG, SHa, APDH, SHe, SHo, SJ-S, AJK, M-WL, CL, CO’G, MPM, CS, RS, JSt, AV, SV, MWa, RJW, RCW, MWo and EMY report no disclosures., (© Article author(s) (or their employer(s) unless otherwise stated in the text of the article) 2017. All rights reserved. No commercial use is permitted unless otherwise expressly granted.)

Published

2017