Top

Published in:

Open Access 01-12-2020 | Astrocytoma | Functional Neuroradiology

Automatic identification of atypical clinical fMRI results

Authors: J. Martijn Jansma, Geert-Jan Rutten, Lenny E. Ramsey, T. J. Snijders, Alberto Bizzi, Katharina Rosengarth, Frank Dodoo-Schittko, Elke Hattingen, Mar Jiménez de la Peña, Gord von Campe, Margit Jehna, Nick F. Ramsey

Published in: Neuroradiology | Issue 12/2020

Abstract

Purpose

Functional MRI is not routinely used for neurosurgical planning despite potential important advantages, due to difficulty of determining quality. We introduce a novel method for objective evaluation of fMRI scan quality, based on activation maps. A template matching analysis (TMA) is presented and tested on data from two clinical fMRI protocols, performed by healthy controls in seven clinical centers. Preliminary clinical utility is tested with data from low-grade glioma patients.

Methods

Data were collected from 42 healthy subjects from seven centers, with standardized finger tapping (FT) and verb generation (VG) tasks. Copies of these “typical” data were deliberately analyzed incorrectly to assess feasibility of identifying them as “atypical.” Analyses of the VG task administered to 32 tumor patients assessed sensitivity of the TMA method to anatomical abnormalities.

Results

TMA identified all atypical activity maps for both tasks, at the cost of incorrectly classifying 3.6 (VG)–6.5% (FT) of typical maps as atypical. For patients, the average TMA was significantly higher than atypical healthy scans, despite localized anatomical abnormalities caused by a tumor.

Conclusion

This study supports feasibility of TMA for objective identification of atypical activation patterns for motor and verb generation fMRI protocols. TMA can facilitate the use and evaluation of clinical fMRI in hospital settings that have limited access to fMRI experts. In a clinical setting, this method could be applied to automatically flag fMRI scans showing atypical activation patterns for further investigation to determine whether atypicality is caused by poor scan data quality or abnormal functional topography.

Castellano A, Cirillo S, Bello L, Riva M, Falini A (2017) Functional MRI for surgery of gliomas. Curr Treat Options Neurol 19:34PubMed

Dimou S, Battisti RA, Hermens DF, Lagopoulos J (2013) A systematic review of functional magnetic resonance imaging and diffusion tensor imaging modalities used in presurgical planning of brain tumour resection. Neurosurg Rev 36:205–214PubMed

Rutten GJ, Ramsey NF (2010) The role of functional magnetic resonance imaging in brain surgery. Neurosurg Focus 28:E4PubMed

Wang L, Chen D, Olson J, Ali S, Fan T, Mao H (2012) Re-examine tumor-induced alterations in hemodynamic responses of BOLD fMRI: implications in presurgical brain mapping. Acta Radiol 53:802–811PubMed

Bick AS, Mayer A, Levin N (2012) From research to clinical practice: implementation of functional magnetic imaging and white matter tractography in the clinical environment. J Neurol Sci 312:158–165PubMed

Rutten G (2002) fMRI-determined language lateralization in patients with unilateral or mixed language dominance according to the Wada test. NeuroImage 17:447–460PubMed

Bauer PR, Reitsma JB, Houweling BM, Ferrier CH, Ramsey NF (2014) Can fMRI safely replace the Wada test for preoperative assessment of language lateralisation? A meta-analysis and systematic review. J Neurol Neurosurg Psychiatry 85:581–588PubMed

Arora J, Pugh K, Westerveld M, Spencer S, Spencer DD, Todd Constable R (2009) Language lateralization in epilepsy patients: fMRI validated with the Wada procedure. Epilepsia 50:2225–2241PubMed

Binder JR (2011) Functional MRI is a valid noninvasive alternative to Wada testing. Epilepsy Behav 20:214–222PubMed

10.

McKinsey RD, Moritz CH, Meyerand ME, Tome WA (2010) Assessment of multiple task activation and reproducibility in patients with benign and low-grade neoplasm. Technol Cancer Res Treat 9:319–326PubMedPubMedCentral

11.

Wengenroth M, Blatow M, Guenther J, Akbar M, Tronnier VM, Stippich C (2011) Diagnostic benefits of presurgical fMRI in patients with brain tumours in the primary sensorimotor cortex. Eur Radiol 21:1517–1525PubMedPubMedCentral

12.

Weng HH, Noll KR, Johnson JM, Prabhu SS, Tsai YH, Chang SW, Huang YC, Lee JD, Yang JT, Yang CT, Tsai YH, Yang CY, Hazle JD, Schomer DF, Liu HL (2018) Accuracy of presurgical functional MR imaging for language mapping of brain tumors: a systematic review and meta-analysis. Radiology 286:512–523PubMed

13.

Tyndall AJ, Reinhardt J, Tronnier V, Mariani L, Stippich C (2017) Presurgical motor, somatosensory and language fMRI: technical feasibility and limitations in 491 patients over 13 years. Eur Radiol 27:267–278PubMed

14.

Sair HI, Yahyavi-Firouz-Abadi N, Calhoun VD, Airan RD, Agarwal S, Intrapiromkul J, Choe AS, Gujar SK, Caffo B, Lindquist MA, Pillai JJ (2016) Presurgical brain mapping of the language network in patients with brain tumors using resting-state fMRI: comparison with task fMRI. Hum Brain Mapp 37:913–923PubMed

15.

Gould L, Mickleborough MJ, Wu A, Tellez J, Ekstrand C, Lorentz E, Ellchuk T, Babyn P, Borowsky R (2016) Presurgical language mapping in epilepsy: using fMRI of reading to identify functional reorganization in a patient with long-standing temporal lobe epilepsy. Epilepsy Behav Case Rep 5:6–10PubMed

16.

Kuchcinski G, Mellerio C, Pallud J, Dezamis E, Turc G, Rigaux-Viode O, Malherbe C, Roca P, Leclerc X, Varlet P, Chretien F, Devaux B, Meder JF, Oppenheim C (2015) Three-tesla functional MR language mapping: comparison with direct cortical stimulation in gliomas. Neurology 84:560–568PubMed

17.

Austermuehle A, Cocjin J, Reynolds R, Agrawal S, Sepeta L, Gaillard WD, Zaghloul KA, Inati S, Theodore WH (2017) Language functional MRI and direct cortical stimulation in epilepsy preoperative planning. Ann Neurol 81:526–537PubMedPubMedCentral

18.

Giussani C, Roux FE, Ojemann J, Sganzerla EP, Pirillo D, Papagno C (2010) Is preoperative functional magnetic resonance imaging reliable for language areas mapping in brain tumor surgery? Review of language functional magnetic resonance imaging and direct cortical stimulation correlation studies. Neurosurgery 66:113–120PubMed

19.

Petrella JR, Shah LM, Harris KM, Friedman AH, George TM, Sampson JH, Pekala JS, Voyvodic JT (2006) Preoperative functional MR imaging localization of language and motor areas: effect on therapeutic decision making in patients with potentially resectable brain tumors. Radiology 240:793–802PubMed

20.

Beisteiner R, Robinson S, Wurnig M, Hilbert M, Merksa K, Rath J, Hollinger I, Klinger N, Marosi C, Trattnig S, Geissler A (2011) Clinical fMRI: evidence for a 7T benefit over 3T. Neuroimage 57:1015–1021PubMedPubMedCentral

21.

Khorrami MS, Faro SH, Seshadri A, Moonat S, Lidicker J, Hershey BL, Mohamed FB (2011) Functional MRI of sensory motor cortex: comparison between finger-to-thumb and hand squeeze tasks. J Neuroimaging 21:236–240PubMed

22.

Rutten GJ, van Rijen PC, van Veelen CW, Ramsey NF (1999) Language area localization with three-dimensional functional magnetic resonance imaging matches intrasulcal electrostimulation in Broca’s area. Ann Neurol 46:405–408PubMed

23.

Kunii N, Kamada K, Ota T, Kawai K, Saito N (2011) A detailed analysis of functional magnetic resonance imaging in the frontal language area: a comparative study with extraoperative electrocortical stimulation. Neurosurgery 69:590–596PubMed

24.

Neggers SF, Hermans EJ, Ramsey NF (2008) Enhanced sensitivity with fast three-dimensional blood-oxygen-level-dependent functional MRI: comparison of SENSE-PRESTO and 2D-EPI at 3 T. NMR Biomed 21:663–676PubMed

25.

Thevenaz P, Ruttimann UE, Unser M (1998) A pyramid approach to subpixel registration based on intensity. IEEE Trans Med Imaging 7:27–41

26.

Jenkinson M, Bannister P, Brady M, Smith S (2002) Improved optimization for the robust and accurate linear registration and motion correction of brain images. Neuroimage 17:825–841PubMed

27.

Tanabe J, Miller D, Tregellas J, Freedman R, Meyer FG (2002) Comparison of detrending methods for optimal fMRI preprocessing. Neuroimage 15:902–907PubMed

28.

Jansma JM, Ramsey N, Rutten GJ (2015) A comparison of brain activity associated with language production in brain tumor patients with left and right sided language laterality. J Neurosurg Sci 59:327–335PubMed

29.

Batouli SA, Hasani N, Gheisari S, Behzad E, Oghabian MA (2016) Evaluation of the factors influencing brain language laterality in presurgical planning. Phys Med 32:1201–1209PubMed

30.

Hou BL, Holodny AI, Cooperman N, Gutin PH (2006) Reorganization of the cortical control of movement due to radiation necrosis. Case report. J Neurosurg 104:147–149PubMed

31.

Tailby C, Abbott DF, Jackson GD (2017) The diminishing dominance of the dominant hemisphere: language fMRI in focal epilepsy. Neuroimage Clin 14:141–150PubMedPubMedCentral

32.

Hou BL, Bradbury M, Peck KK, Petrovich NM, Gutin PH, Holodny AI (2006) Effect of brain tumor neovasculature defined by rCBV on BOLD fMRI activation volume in the primary motor cortex. Neuroimage 32:489–497PubMed

33.

Rath J, Wurnig M, Fischmeister F, Klinger N, Hollinger I, Geissler A, Aichhorn M, Foki T, Kronbichler M, Nickel J, Siedentopf C, Staffen W, Verius M, Golaszewski S, Koppelstaetter F, Auff E, Felber S, Seitz RJ, Beisteiner R (2016) Between- and within-site variability of fMRI localizations. Hum Brain Mapp 37:2151–2160PubMedPubMedCentral

34.

Friedman L, Stern H, Brown GG, Mathalon DH, Turner J, Glover GH, Gollub RL, Lauriello J, Lim KO, Cannon T, Greve DN, Bockholt HJ, Belger A, Mueller B, Doty MJ, He J, Wells W, Smyth P, Pieper S, Kim S, Kubicki M, Vangel M, Potkin SG (2008) Test-retest and between-site reliability in a multicenter fMRI study. Hum Brain Mapp 29:958–972PubMed

35.

Costafreda SG, Brammer MJ, Vencio RZ, Mourao ML, Portela LA, de Castro CC, Giampietro VP, Amaro E Jr (2007) Multisite fMRI reproducibility of a motor task using identical MR systems. J Magn Reson Imaging 26:1122–1126PubMed

36.

Maitra R, Roys SR, Gullapalli RP (2002) Test-retest reliability estimation of functional MRI data. Magn Reson Med 48:62–70PubMed

37.

Gountouna VE, Job DE, McIntosh AM, Moorhead TW, Lymer GK, Whalley HC, Hall J, Waiter GD, Brennan D, McGonigle DJ, Ahearn TS, Cavanagh J, Condon B, Hadley DM, Marshall I, Murray AD, Steele JD, Wardlaw JM, Lawrie SM (2010) Functional magnetic resonance imaging (fMRI) reproducibility and variance components across visits and scanning sites with a finger tapping task. Neuroimage 49:552–560PubMed

38.

Voyvodic JT (2006) Activation mapping as a percentage of local excitation: fMRI stability within scans, between scans and across field strengths. Magn Reson Imaging 24:1249–1261PubMed

39.

Vlieger EJ, Lavini C, Majoie CB, den Heeten GJ (2003) Reproducibility of functional MR imaging results using two different MR systems. AJNR Am J Neuroradiol 24:652–657PubMed

40.

Zou KH, Greve DN, Wang M, Pieper SD, Warfield SK, White NS, Manandhar S, Brown GG, Vangel MG, Kikinis R, Wells WM 3rd (2005) Reproducibility of functional MR imaging: preliminary results of prospective multi-institutional study performed by Biomedical Informatics Research Network. Radiology 237:781–789PubMedPubMedCentral

41.

Brown GG, Mathalon DH, Stern H, Ford J, Mueller B, Greve DN, McCarthy G, Voyvodic J, Glover G, Diaz M, Yetter E, Ozyurt IB, Jorgensen KW, Wible CG, Turner JA, Thompson WK, Potkin SG (2011) Multisite reliability of cognitive BOLD data. Neuroimage 54:2163–2175PubMed

42.

Casey BJ, Cohen JD, O’Craven K, Davidson RJ, Irwin W, Nelson CA, Noll DC, Hu X, Lowe MJ, Rosen BR, Truwitt CL, Turski PA (1998) Reproducibility of fMRI results across four institutions using a spatial working memory task. NeuroImage 8:249–261PubMed

43.

Gee DG, McEwen SC, Forsyth JK, Haut KM, Bearden CE, Addington J, Goodyear B, Cadenhead KS, Mirzakhanian H, Cornblatt BA, Olvet D, Mathalon DH, McGlashan TH, Perkins DO, Belger A, Seidman LJ, Thermenos H, Tsuang MT, van Erp TG, Walker EF, Hamann S, Woods SW, Constable T, Cannon TD (2015) Reliability of an fMRI paradigm for emotional processing in a multisite longitudinal study. Hum Brain Mapp 36:2558–2579PubMedPubMedCentral

44.

Costafreda S (2009) Pooling fMRI data: meta-analysis, mega-analysis and multi-center studies. Front Neuroinformatics 3:33PubMedCentral

45.

Rutten GJ, Ramsey NF, van Rijen PC, Noordmans HJ, van Veelen CW (2002) Development of a functional magnetic resonance imaging protocol for intraoperative localization of critical temporoparietal language areas. Ann Neurol 51:350–360PubMed

46.

Roessler K, Donat M, Lanzenberger R, Novak K, Geissler A, Gartus A, Tahamtan AR, Milakara D, Czech T, Barth M, Knosp E, Beisteiner R (2005) Evaluation of preoperative high magnetic field motor functional MRI (3 Tesla) in glioma patients by navigated electrocortical stimulation and postoperative outcome. J Neurol Neurosurg Psychiatry 76:1152–1157PubMedPubMedCentral

47.

Hermes D, Miller KJ, Vansteensel MJ, Aarnoutse EJ, Leijten FS, Ramsey NF (2012) Neurophysiologic correlates of fMRI in human motor cortex. Hum Brain Mapp 33:1689–1699PubMed

48.

Brunner P, Ritaccio AL, Lynch TM, Emrich JF, Wilson JA, Williams JC, Aarnoutse EJ, Ramsey NF, Leuthardt EC, Bischof H, Schalk G (2009) A practical procedure for real-time functional mapping of eloquent cortex using electrocorticographic signals in humans. Epilepsy Behav 15:278–286PubMedPubMedCentral

49.

Liu TT, Frank LR, Wong EC, Buxton RB (2001) Detection power, estimation efficiency, and predictability in event-related fMRI. Neuroimage 13:759–773PubMed

50.

Thirion B, Pinel P, Meriaux S, Roche A, Dehaene S, Poline JB (2007) Analysis of a large fMRI cohort: statistical and methodological issues for group analyses. Neuroimage 35:105–120PubMed

51.

Crinion J, Ashburner J, Leff A, Brett M, Price C, Friston K (2007) Spatial normalization of lesioned brains: performance evaluation and impact on fMRI analyses. Neuroimage 37:866–875PubMedPubMedCentral

Title: Automatic identification of atypical clinical fMRI results
Authors: J. Martijn Jansma
Geert-Jan Rutten
Lenny E. Ramsey
T. J. Snijders
Alberto Bizzi
Katharina Rosengarth
Frank Dodoo-Schittko
Elke Hattingen
Mar Jiménez de la Peña
Gord von Campe
Margit Jehna
Nick F. Ramsey
Publication date: 01-12-2020
Publisher: Springer Berlin Heidelberg
Keywords: Astrocytoma
Astrocytoma
Astrocytoma
Published in: Neuroradiology / Issue 12/2020
Print ISSN: 0028-3940
Electronic ISSN: 1432-1920
DOI: https://doi.org/10.1007/s00234-020-02510-z

At a glance: The STEP trials

Springer Medicine

Automatic identification of atypical clinical fMRI results

Abstract

Purpose

Methods

Results

Conclusion

At a glance: The STEP trials

Springer Medicine

Abstract

Purpose

Methods

Results

Conclusion

Please log in to get access to this content

Other articles of this Issue 12/2020

Accuracy and practical aspects of semi- and fully automatic segmentation methods for resected brain areas

Radiation exposure in endovascular stroke treatment of acute basilar artery occlusions—a matched-pair analysis

Intravoxel incoherent motion diffusion-weighted imaging for discrimination of benign and malignant retropharyngeal nodes

Dual-energy CT for differentiating acute intracranial hemorrhage from contrast staining or calcification: a meta-analysis

Complex vascular anatomy is a predictor of silent cerebral ischemia after carotid artery stenting

Vertebral augmentation with spinal implants: third-generation vertebroplasty