In this methodological study, a procedure for measuring regional CBF (rCBF) with positron emission tomography and 15O-labelled tracers is optimized. Four healthy volunteers were subjected to eight studies with use of [15O]butanol as a tracer: four times while reading aloud and four times while reading silently from a phonologically balanced list of single words. The gain from these repeated intra-individual studies of the same activation state (fractionation) was demonstrated in terms of noise-equivalent counts in a phantom study. A computerized brain atlas was used to reformat the images to a common anatomical representation, thereby minimizing the effects of inter- and intra-individual anatomical and positional variations. This allowed the formation of inter- and intra-individual average subtraction images with error estimates. Differences between the two activation states were detected with use of an exploratory significance map based on a paired Student's t test. The results compared well with Friston's method of determining levels of statistical significance. No difference was obtained when comparing results from rCBF images and images generated from measurement of uptake of the tracer. The paradigm chosen for activation was shown to yield a constant activation level during the repeated measurements (i.e., no habituation).
BergströmMBoethiusJErikssonLGreitzTRibbeTWidénL, (1981) Head fixation device for reproducible position alignment in transmission CT and positron emission tomography. J Comput Assist Tomogr5:136–141
2.
BerridgeMCassidyMMiraldyF, (1990) A routine synthesis of 15O-labelled butanol for positron tomography. J Nucl Med31:1727–1731
3.
BohmCGreitzTBlomqvistGFardeLForsgrenPOKingsleyDSjögrenIWieselF-AWikG, (1986) Applications of a computerized adjustable brain atlas in positron emission tomography. Acta Radiol Suppl (Stockh)369:449–452
BohmCGreitzTKingsleyDBerggrenBMOlssonL, (1983) Adjustable computerized stereotaxic brain atlas for transmission and emission tomography. Am J Neuroradiol4:731–733
6.
CherrySRDahlbomMHoffmanEJ, (1991) Three dimensional positron emission tomography using a conventional multislice tomograph without septa. J Comput Assist Tomogr15:655–668
7.
CherrySRDahlbomMHoffmanEJ, (1992) Evaluation of a 3D reconstruction algorithm for multi-slice PET scanners. Phys Med Biol37:779–790
8.
CherrySWoodsRPHoffmanEJMazziottaJC, (1993a) Improved detection of focal cerebral blood flow changes using three-dimensional positron emission tomography. J Cereb Blood Flow Metab13:630–638
9.
CherrySWoodsRPHoffmanEJMazziottaJC, (1992) Improved methodology for cerebral activation studies in a single subject using 15O-water and PET. IEEE Trans Nucl Sci2:960–962
10.
DamasioARDamasioH, (1992) Brain and language. Sci Am267:63–72
11.
ErikssonLHolteSBohmCKesselbergMHovanderB, (1988) Automated blood sampling systems for positron emission tomography. IEEE Trans Nucl SciNS-35:703–707
12.
FoxPT, (1991) Physiological ROI definition by image subtraction. J Cereb Blood Flow Metab11:A79–A82
13.
FoxPTMintunMA, (1989) Noninvasive functional brain mapping by change-distribution analysis of averaged PET images of H215O tissue activity. J Nucl Med30:141–149
14.
FoxPTPerlmutterJSRaichleME, (1985) A stereotactic method of anatomic localization for positron emission tomography. J Comput Assist Tomogr9:141–153
15.
FristonKJFrithCDLiddlePFFrackowiakRS, (1991a) Comparing functional (PET) images: The assessment of significant change. J Cereb Blood Flow Metab11:690–699
16.
FristonKJFrithCDLiddlePFFrackowiakRS, (1991b) Plastic transformation of PET images. J Comput Assist Tomogr15:634–639
17.
FristonKJPassinghamRENuttJGHeatherJDSawleGVFrackowiakRS, (1989) Localisation in PET images: Direct fitting of the intercommissural (AC-PC) line. J Cereb Blood Flow Metab9:690–695
18.
GraftonSMazziottaJPrestySFristonKFrackowiakRPhelpsM, (1992) Functional anatomy of human procedural learning determined with regional cerebral blood flow and PET. J Neurosci12:2542–2548
19.
GreitzTBergströmMBoëthiusJKingsleyDRibbeT, (1980) Head fixation system for integration of radiodiagnostic and therapeutic procedures. Neuroradiology19:1–11
20.
GreitzTBohmCHolteSErikssonL, (1991) A computerized brain atlas: Construction, anatomical content, and some applications. J Comput Assist Tomogr15:26–38
21.
HolteSErikssonLDahlbomM, (1989) A preliminary evaluation of the Scanditronix PC-2048-15B brain scanner. Eur J Nucl Med15:719–721
22.
IngvarDH, (1985) Serial aspects of language and speech related to prefrontal cortical activity. A selective review. J Human Neurobiol2:177–189
23.
IngvarDLassenN, (1963) Regional blood flow of the cortex determined by 85Krypton. Acta Physiol Scand54:328–338
24.
KabalkaGLambrechtRSajjadMFowlerJKundaSMcCollumGMacGregorR, (1985) Synthesis of 15O-labeled butanol via organoborane chemistry. Int J Appl Radiat Isot36:853–855
25.
KannoI, (1991) Discussion in Brain Work and Mental Activity (LassenNIngvarDRaichleMFribergL, eds), Copenhagen, Munksgaard, p 433–435
26.
KoeppeRHoldenJIpW, (1985) Performance of parameter estimation techniques for the quantitation of local cerebral blood flow by dynamic positron computed tomography. J Cereb Blood Flow Metab5:224–234
LarsenBSkinhøjELassenNA, (1978) Variations in regional cortical blood flow in the right and left hemispheres during speech. Brain101:193–209
29.
LassenNIngvarD, (1961) The blood flow of the cerebral cortex determined by radioactive 85Krypton. Experentia (Basel)17:42
30.
LassenNIngvarDRaichleMFribergL, (1991) Brain work and mental activity, Copenhagen, Munksgaard, pp 1–446
31.
MazziottaJHuangS-CPhelpsMECarsonREMacDonaldNSMahoneyK, (1985) A non-invasive positron computed tomography technique using oxygen-15 labelled water for the evaluation of neurobehavioural task batteries. J Cereb Blood Flow Metab5:70–78
32.
MintunMAFoxPTRaichleME, (1989) A highly accurate method of localizing regions of neuronal activation in the human brain with positron emission tomography. J Cereb Blood Flow Metab9:96–103
33.
PardoJVFoxPTRaichleME, (1991) Localization of a human system for sustained attention by positron emission tomography. Nature349:61–63
34.
PenfieldWJasperH, (1954) Epilepsy and the functional anatomy of the human brain, London: J. A. Churchill
35.
PetersenSEFoxPTPosnerMIMintunMRaichleME, (1988) Positron emission tomographic studies of the cortical anatomy of single word processing. Nature331:585–589
36.
PosnerMIPetersenSEFoxPTRaichleME, (1988) Localization of cognitive operations in the human brain. Science240:1627–1631
37.
RaichleMEFiezJAVideenTOMacleodAM KPardoJVFoxPTPetersenSE, (1994) Practice related changes in human brain functional anatomy during non-motor learning. Cerebral Cortex4:8–26
38.
RoyCSherringtonC, (1896) On the regulation of the blood supply to the brain. J Physiol (Lond)2:323–359
39.
RydingEBrådvikBIngvarDH, (1993a) Silent speech activates prefrontal cortical regions asymmetrically, as well as speech related areas in the dominant hemisphere. Cogn Brain Res (in press)
40.
RydingEDecetyJSjöholmHStenbergGIngvarDH, (1993b) Motor imagery activates the cerebellum regionally. A SPECT study. Cogn Brain Res2:94–99
41.
SeitzRJBohmCGreitzTRolandPEErikssonLBlomqvistGRosenqvistGNordellB, (1990a) Accuracy and precision of the computerized brain atlas programme for localization and quantification in positron emission tomography. J Cereb Blood Flow Metab10:443–457
42.
SeitzRJRolandEBohmCGreitzTStone-ElanderS, (1990b) Motor learning in man: A positron emission tomographic study. Neuroreport1:57–60
43.
StrotherSCLiowJSMoellerJRSidtisJJDhawanVJRottenbergDA, (1991) Absolute quantitation in neurological PET: Do we need it?J Cereb Blood Flow Metab11:163–173
44.
TownsendDWSpinksTJonesTGeissbühlerADefriseMGilardiMCHeatherJ, (1989) Three dimensional reconstruction of PET data from a multi-ring camera. IEEE Trans Nucl SciNS-36:1056–1065
