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Towards Personalized Therapy for Multiple Sclerosis: Prediction of Individual Treatment Response Publisher Pubmed



Kalincik T1, 2 ; Manouchehrinia A3 ; Sobisek L4, 5 ; Jokubaitis V2, 6 ; Spelman T2, 6 ; Horakova D4 ; Havrdova E4 ; Trojano M7 ; Izquierdo G8 ; Lugaresi A9, 10 ; Girard M11 ; Prat A11 ; Duquette P11 ; Grammond P12 Show All Authors
Authors
  1. Kalincik T1, 2
  2. Manouchehrinia A3
  3. Sobisek L4, 5
  4. Jokubaitis V2, 6
  5. Spelman T2, 6
  6. Horakova D4
  7. Havrdova E4
  8. Trojano M7
  9. Izquierdo G8
  10. Lugaresi A9, 10
  11. Girard M11
  12. Prat A11
  13. Duquette P11
  14. Grammond P12
  15. Sola P13
  16. Hupperts R14
  17. Grandmaison F15
  18. Pucci E16
  19. Boz C17
  20. Alroughani R18
  21. Van Pesch V19
  22. Lechnerscott J20
  23. Terzi M21
  24. Bergamaschi R22
  25. Iuliano G23
  26. Granella F24
  27. Spitaleri D25
  28. Shaygannejad V26
  29. Orejaguevara C27
  30. Slee M28
  31. Ampapa R29
  32. Verheul F30
  33. Mccombe P31
  34. Olascoaga J32
  35. Amato MP33
  36. Vucic S34
  37. Hodgkinson S35
  38. Ramotello C36
  39. Flechter S37
  40. Cristiano E38
  41. Rozsa C39
  42. Moore F40
  43. Sanchezmenoyo JL41
  44. Saladino ML42
  45. Barnett M43
  46. Hillert J3
  47. Butzkueven H2, 6, 44
Show Affiliations
Authors Affiliations
  1. 1. CORe, Department of Medicine, University of Melbourne, 300 Grattan St., Melbourne, 3050, Australia
  2. 2. Department of Neurology, Royal Melbourne Hospital, L4 Centre, 300 Grattan St., Parkville, 3050, VIC, Australia
  3. 3. Department of Clinical Neuroscience, Karolinska Institutet, Stockholm, SE-17177, Sweden
  4. 4. Department of Neurology, Center of Clinical Neuroscience, General University Hospital, Charles University in Prague, Katerinska 30, Prague, 12808, Czech Republic
  5. 5. Department of Statistics and Probability, University of Economics in Prague, Winston Churchill Sq. 1938/4, Prague, 13067, Czech Republic
  6. 6. Department of Medicine, University of Melbourne, 300 Grattan St., Melbourne, 3050, Australia
  7. 7. University of Bari, Via Calefati 53, Bari, 70122, Italy
  8. 8. Hospital Universitario Virgen Macarena, Amador de los Rios 48-50. 4a, Sevilla, 41003, Spain
  9. 9. Department of Neuroscience, Imaging and Clinical Sciences, University 'G. d'Annunzio', Via dei Vestini, Chieti, 66100, Italy
  10. 10. Department of Biomedical and Neuromotor Sciences, University of Bologna, Via dei Vestini, Bologna, 66100, Italy
  11. 11. Hopital Notre Dame, 1560 Sherbrooke East, Montreal, H2L 4M1, Canada
  12. 12. Centre de Readaptation Deficience Physique Chaudiere-Appalache, 9500 blvd Centre-Hospitalier, Levis, G6X 0A1, Canada
  13. 13. Nuovo Ospedale Civile Sant'Agostino/Estense, Via Giardini 1355, Modena, 41100, Italy
  14. 14. Zuyderland Ziekenhuis, Walramstraat 23, Sittard, 6131 BK, Netherlands
  15. 15. Neuro Rive-Sud, 4896 boul. Taschereau, Greenfield Park, J4V 2J2, Canada
  16. 16. Azienda Sanitaria Unica Regionale Marche - AV3, Via Santa Lucia 2, Macerata, 62100, Italy
  17. 17. KTU Medical Faculty Farabi Hospital, Karadeniz Technical University, Trabzon, 61080, Turkey
  18. 18. Amiri Hospital, P.O. Box 1661, Qurtoba, 73767, Kuwait
  19. 19. Cliniques Universitaires Saint-Luc, Avenue Hippocrate, 10 UCL10/80, Brussels, BXL 1200, Belgium
  20. 20. University of Newcastle, Lookout Road, Newcastle, 2305, Australia
  21. 21. Ondokuz Mayis University, Medical Faculty, Kurupelit, Samsun, 55160, Turkey
  22. 22. C. Mondino National Neurological Institute, Via Mondino 2, Pavia, 27100, Italy
  23. 23. Ospedali Riuniti di Salerno, Via s. Leonardo, Salerno, 84100, Italy
  24. 24. University of Parma, Via Gramsci, 14, Parma, 43100, Italy
  25. 25. Azienda Ospedaliera di Rilievo Nazionale San Giuseppe Moscati Avellino, Contrada Amoretta, Avellino, 83100, Italy
  26. 26. Isfahan University of Medical Sciences, Soffeh St., Isfahan, 81744, Iran
  27. 27. Hospital Universitario La Paz, Paseo de la Castellana 261, Madrid, 28050, Spain
  28. 28. Flinders Medical Centre, Flinders Drive, Adelaide, 5042, Australia
  29. 29. Nemocnice Jihlava, Vrchlickeho 59, Jihlava, 58633, Czech Republic
  30. 30. Groene Hart ziekenhuis, Bleulandweg 10, Gouda, BB 2800, Netherlands
  31. 31. Royal Brisbane and Women's Hospital, 33 North Street, Spring Hill, 4000, QLD, Australia
  32. 32. Hospital Donostia, Paseo de Begiristain, San-Sebastian, 20014, Spain
  33. 33. University of Florence, Viale Morgagni 85, Florence, 50134, Italy
  34. 34. Westmead Hospital, Hawkesbury Rd., Sydney, 2145, Australia
  35. 35. Liverpool Hospital, Elizabeth St., Liverpool, 21, Australia
  36. 36. Hospital Germans Trias i Pujol, Crtra de Canyet s/n, Badalona, 8916, Spain
  37. 37. Assaf Harofeh Medical Center, Zerifin, Beer-Yaakov, 70100, Israel
  38. 38. Hospital Italiano, Guise 1870, Buenos Aires, 1425, Argentina
  39. 39. Jahn Ferenc Teaching Hospital, Koves u. 1., Budapest, 1101, Hungary
  40. 40. Jewish General Hospital, 3755 Cote-Sainte-Catherine, Montreal, J7A 4T8, Canada
  41. 41. Hospital de Galdakao-Usansolo, Barrio Labeaga s.n., Galdakao, 48660, Spain
  42. 42. INEBA - Institute of Neuroscience Buenos Aires, Guardia Vieja 4435, Buenos Aires, C1192AAW, Argentina
  43. 43. Brain and Mind Centre, University of Sydney, 100 Mallett, Camperdown, 2050, Australia
  44. 44. Department of Neurology, Box-Hill Hospital, Monash University, Melbourne, Australia

Source: Brain Published:2017


Abstract

Timely initiation of effective therapy is crucial for preventing disability in multiple sclerosis; however, treatment response varies greatly among patients. Comprehensive predictive models of individual treatment response are lacking. Our aims were: (i) to develop predictive algorithms for individual treatment response using demographic, clinical and paraclinical predictors in patients with multiple sclerosis; and (ii) to evaluate accuracy, and internal and external validity of these algorithms. This study evaluated 27 demographic, clinical and paraclinical predictors of individual response to seven disease-modifying therapies in MSBase, a large global cohort study. Treatment response was analysed separately for disability progression, disability regression, relapse frequency, conversion to secondary progressive disease, change in the cumulative disease burden, and the probability of treatment discontinuation. Multivariable survival and generalized linear models were used, together with the principal component analysis to reduce model dimensionality and prevent overparameterization. Accuracy of the individual prediction was tested and its internal validity was evaluated in a separate, non-overlapping cohort. External validity was evaluated in a geographically distinct cohort, the Swedish Multiple Sclerosis Registry. In the training cohort (n = 8513), the most prominent modifiers of treatment response comprised age, disease duration, disease course, previous relapse activity, disability, predominant relapse phenotype and previous therapy. Importantly, the magnitude and direction of the associations varied among therapies and disease outcomes. Higher probability of disability progression during treatment with injectable therapies was predominantly associated with a greater disability at treatment start and the previous therapy. For fingolimod, natalizumab or mitoxantrone, it was mainly associated with lower pretreatment relapse activity. The probability of disability regression was predominantly associated with pre-baseline disability, therapy and relapse activity. Relapse incidence was associated with pretreatment relapse activity, age and relapsing disease course, with the strength of these associations varying among therapies. Accuracy and internal validity (n = 1196) of the resulting predictive models was high (480%) for relapse incidence during the first year and for disability outcomes, moderate for relapse incidence in Years 2-4 and for the change in the cumulative disease burden, and low for conversion to secondary progressive disease and treatment discontinuation. External validation showed similar results, demonstrating high external validity for disability and relapse outcomes, moderate external validity for cumulative disease burden and low external validity for conversion to secondary progressive disease and treatment discontinuation. We conclude that demographic, clinical and paraclinical information helps predict individual response to disease-modifying therapies at the time of their commencement. © The Author (2017). Published by Oxford University Press on behalf of the Guarantors of Brain. All rights reserved.
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