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Abstract

The face inversion effect refers to a decrement in performance when we try to recognise familiar faces turned upside down (inverted), compared with familiar faces presented in their usual (upright) orientation. Recently, we have demonstrated that the inversion effect can also be found with checkerboards drawn from prototype-defined categories when the participants have been trained with these categories, suggesting that factors such as expertise and the relationships between stimulus features may be important determinants of this effect. We also demonstrated that the typical inversion effect on the N170 seen with faces is found with checkerboards, suggesting that modulation of the N170 is a marker for disruption in the use of configural information. In the present experiment, we first demonstrate that our scrambling technique greatly reduces the inversion effect in faces. Following this, we used Event-Related Potentials (ERPs) recorded while participants performed an Old/New recognition study on normal and scrambled faces presented in both upright and inverted orientations to investigate the impact of scrambling on the N170. We obtained the standard robust inversion effect for normal faces: The N170 was both larger and delayed for normal inverted faces as compared with normal upright faces, whereas a significantly reduced inversion effect was recorded for scrambled faces. These results show that the inversion effect on the N170 is greater for normal compared with scrambled faces, and we interpret the smaller effect for scrambled faces as being due to the reduction in expertise for those faces consequent on scrambling.

Keywords

Face inversion effect N170 peak scrambled faces configural processing

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References

Bentin

Allison

Puce

Perez

McCarthy

(1996). Electrophysiological studies of face perception in humans. Journal of Cognitive Neuroscience, 8, 551–565.

Burton

A. M.

Schweinberger

S. R.

Jenkins

Kaufmann

J. M.

(2015). Arguments against a configural processing account of familiar face recognition. Perspectives on Psychological Science, 10, 482–496.

Busey

Vanderkolk

(2005). Behavioural and electrophysiological evidence for configural processing in fingerprint experts. Vision Research, 45, 431–448.

Carmel

Bentin

(2002). Domain specificity versus expertise: Factors influencing distinct processing of faces. Cognition, 83, 1–29.

Civile

McLaren

I. P. L.

(2014). The face inversion effect: Parts and wholes. The Quarterly Journal of Experimental Psychology, 67, 728–746.

Civile

McLaren

I. P. L.

(2016). The face inversion effect: Roles of first and second-order relational information. The American Journal of Psychology, 129, 23–35.

Civile

Zhao

Elchlepp

Lavric

McLaren

I. P. L.

(2014). Perceptual learning and inversion effect: Recognition of prototype-defined familiar checkerboards. Journal of Experimental Psychology: Animal Learning and Cognition, 40, 144–161.

Cohen

(1988). Statistical power analysis for the behavioural sciences (2nd ed.). Hillsdale, NJ: Lawrence Earlbaum.

Collishaw

Hole

(2000). Featural and configurational processes in the recognition of faces of different familiarity. Perception, 29, 893–909.

10.

Dallett

Wilcox

D’Andrea

(1968). Picture memory experiments. Journal of Experimental Psychology, 76, 312–320.

11.

Delorme

Makeig

(2004). EEGLAB: An open source toolbox for analysis of single-trial EEG dynamics including independent component analysis. Journal of Neuroscience Methods, 134, 9–21.

12.

Diamond

Carey

(1986). Why faces are and are not special: An effect of expertise. Journal of Experimental Psychology: General, 115, 107–117.

13.

Dienes

(2011). Bayesian versus orthodox statistics: Which side are you on? Perspectives on Psychological Science, 6, 274–290.

14.

Eimer

(2000). The face-specific N170 component reflects late stages in the structural encoding of faces. Neuroreport, 11, 2319–2324.

15.

Faul

Erdfelder

Lang

Buchner

(2007). G*Power3: A flexible statistical power analysis program for the social, behavioural, and biomedical sciences. Behaviour Research Methods, 39, 175–191.

16.

Gauthier

Skudlarski

Gore

J. C.

Anderson

(2000). Expertise for cars and birds recruits brain areas involved in face recognition. Nature Neuroscience, 3, 191–197.

17.

Gauthier

Tarr

(1997). Becoming a “greeble” expert: Exploring mechanisms for face recognition. Vision Research, 37, 1673–1682.

18.

George

Evans

Fiori

Davidoff

Renault

(1996). Brain events related to normal and moderately scrambled faces. Cognitive Brain Research, 4, 65–76.

19.

Goffaux

Gauthier

Rossion

(2003). Spatial scale contribution to early visual differences between face and object processing. Cognition Brain Research, 16, 416–424.

20.

Halit

de Haan

Johnson

M. H.

(2000). Modulation of event-related potentials by prototypical and atypical faces. Neuroreport, 11, 1871–1875.

21.

Haxby

Hoffman

Gobbini

(2000). The distributed human neural system for face perception. Trends in Cognitive Science, 4, 223–233.

22.

Jacques

Rossion

(2004). Concurrent processing reveals competition between visual representations of faces. Neuroreport, 15, 2417–2421.

23.

Jung

Makeig

Westerfield

Townsend

Courchesne

Sejnowski

(2001). Analysis and visualization of single-trial event-related potential. Human Brain Mapping, 14, 166–185.

24.

Latinus

Taylor

(2006). Face processing stages: Impact of difficulty and the separation of effects. Brain Research, 1123, 179–187.

25.

Lecarme

Delvare

(2013). The book of GIMP: The complete guide to nearly everything. San Francisco, CA: No Starch Press.

26.

Leder

Bruce

(1998). Local and relational aspects of face distinctiveness. The Quarterly Journal of Experimental Psychology, 51, 449–473.

27.

Leder

Huber

Bruce

(2001). Configural features in the context of upright and inverted faces. Perception, 30, 73–83.

28.

Lopez-Calderon

Luck

S. J.

(2014). ERPLAB: An open-source toolbox for the analysis of event-related potentials. Frontiers in Human Neuroscience, 8, 1–14.

29.

Luck

S. J.

(2005). An introduction to the event-related potential technique (2nd ed.). Cambridge, MA: The MIT Press.

30.

Maurer

Le Grand

Mondloch

(2002). The many faces of configural processing. Trends in Cognitive Science, 6, 255–260.

31.

McLaren

I. P. L.

(1997). Categorisation and perceptual learning: An analogue of the face inversion effect. The Quarterly Journal of Experimental Psychology, 50, 257–273.

32.

McLaren

I.P.L.

Kaye

Mackintosh

N.J.

(1989). An associative theory of the representation of stimuli: Applications to perceptual learning and latent inhibition. In Morris

R.G.M.

(Ed.) Parallel Distributed Processing - Implications for Psychology and Neurobiology. Oxford, Oxford University Press.

33.

Robbins

McKone

(2007). No face-like processing for objects-of-expertise in three behavioural tasks. Cognition, 103, 34–79.

34.

Rossion

Delvenne

Debatisse

Goffaux

Bruyer

Crommelinck

. . . Guerit

(1999). Spatio-temporal localization of the face inversion effect: An event-related potentials study. Biological Psychology, 50, 173–189.

35.

Rossion

Gauthier

(2002). How does the brain process upright and inverted faces? Behavioural and Cognitive Neuroscience Reviews, 1, 62–74.

36.

Rossion

Gauthier

Goffaux

Tarr

Crommelinck

(2002). Expertise training with novel objects leads to face-like electrophysiological responses. Psychological Science, 13, 250–257.

37.

Rossion

Jacques

(2008). Does physical interstimulus variance account for early electrophysiological face sensitive responses in the human brain: Ten lessons on the N170. Neuroimage, 39, 1959–1979.

38.

Sagiv

Bentin

(2001). Structural encoding of human and schematic faces: Holistic and part-based processes. Journal of Cognitive Neuroscience, 13, 937–951.

39.

Searcy

Bartlett

(1996). Inversion and processing of component and spatial-relational information in faces. Journal of Experimental Psychology: Human Perception and Performance, 22, 904–915.

40.

Stanislaw

Todorov

(1999). Calculation of signal detection theory measures. Behaviour Research Methods, Instruments, and Computers, 31, 137–149.

41.

Tanaka

Farah

(1993). Parts and wholes in face recognition. The Quarterly Journal of Experimental Psychology, 46, 225–245.

42.

Towler

Parketny

Eimer

(2016). Perceptual face processing in developmental prosopagnosia is not sensitive to the canonical location of face parts. Cortex, 74, 53–66.

43.

Valentine

Bruce

(1988). Mental rotation of faces. Memory & Cognition, 16, 556–566.

44.

Yin

(1969). Looking at upside-down faces. Journal of Experimental Psychology, 81, 141–145.

45.

Zion-Golumbic

Bentin

(2007). Dissociated neural mechanisms for face detection and configural encoding: Evidence from N170 and Gamma-band oscillation effects. Cerebral Cortex, 17, 1741–1749.

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The effect of scrambling upright and inverted faces on the N170

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