Chemosensory Perception

, Volume 5, Issue 3–4, pp 300–307 | Cite as

Olfactory Abilities and Psychopathy: Higher Psychopathy Scores Are Associated with Poorer Odor Discrimination and Identification

Article

Abstract

Olfactory processing is known to involve the orbitofrontal cortex (OFC). The OFC is also believed to function less effectively in individuals scoring higher in psychopathic personality traits. In this study, we examined whether poorer olfactory discrimination and identification—taken as an indicator of OFC integrity—was associated with the degree of presence of psychopathic traits in a community sample. Seventy-nine non-criminal participants completed the Self-Report Psychopathy scale and a standardized measure of olfactory ability, the Sniffin’ Sticks, measuring odor threshold, identification, and discrimination. Consistent with predictions, we found a relationship between psychopathy and olfactory discrimination and identification but not odor threshold, even after controlling for gender, age, empathy, smoking status, and craniofacial surgery/injury. These findings suggest that brain areas subserving higher olfactory processes—identification and discrimination—are somehow less efficient in individuals who score higher on psychopathic traits. In particular, we suggest that this relates to processing within the orbitofrontal cortex.

Keywords

Psychopathy Orbitofrontal cortex Olfaction Non-criminal Sniffin’ Sticks 

References

  1. Bechara A, Damasio AR, Damasio H, Anderson SW (1994) Insensitivity to future consequences following damage to human prefrontal cortex. Cognition 50:7–15CrossRefGoogle Scholar
  2. Bechara A, Damasio H, Damasio AR, Lee GP (1999) Different contributions of the human amygdala and ventromedial prefrontal cortex to decision-making. J Neurosci 19(13):5473–5481Google Scholar
  3. Belmore MF, Quinsey VL (1994) Correlates of psychopathy in a noninstitutional sample. J Interpers Violence 9(3):339–349CrossRefGoogle Scholar
  4. Berlin HA, Rolls ET, Kischka U (2004) Impulsivity, time perception, emotion and reinforcement sensitivity in patients with orbitofrontal cortex lesions. Brain 127:1108–1126CrossRefGoogle Scholar
  5. Birbaumer N, Veit R, Lotze M, Erb M, Hermann C, Grodd W, Flor H (2005) Deficient fear conditioning in psychopathy: a functional magnetic resonance imaging study. Arch Gen Psychiat 62(7):799–805CrossRefGoogle Scholar
  6. Blair RJR (2004) The roles of orbital frontal cortex in the modulation of antisocial behaviour. Brain Cognition 55:198–208CrossRefGoogle Scholar
  7. Blair RJR (2006) Subcortical brain systems in psychopathy: the amygdala and associated structures. In: Patrick CJ (ed) Handbook of psychopathy. Guilford, New York, pp 459–478Google Scholar
  8. Blair RJR, Mitchell DGV, Richell RA, Kelly S, Leonard A, Newman C, Scott SK (2002) Turning a deaf ear to fear: impaired recognition of vocal affect in psychopathic individuals. J Abnorm Psychol 111(4):682–686CrossRefGoogle Scholar
  9. Blair KS, Newman C, Mitchell DGV, Richell RA, Leonard A, Morton J, Blair RJR (2006) Differentiating among prefrontal substrates in psychopathy: neuropsychological test findings. Neuropsychology 20(2):153–165CrossRefGoogle Scholar
  10. Danthiir V, Roberts RD, Pallier G, Stankov L (2001) What the nose knows: olfaction and cognitive abilities. Intelligence 29(4):337–361CrossRefGoogle Scholar
  11. Devonshire PA, Howard RC, Sellars C (1988) Frontal lobe functions and personality in mentally abnormal offenders. Pers Indiv Differ 9(2):339–344CrossRefGoogle Scholar
  12. Dias R, Robbins TW, Roberts AC (1996) Dissociation in prefrontal cortex of affective and attentional shifts. Nature 380:69–72CrossRefGoogle Scholar
  13. Dinn WM, Harris CL (2000) Neurocognitive function in antisocial personality disorder. Psychiat Res 97:173–190CrossRefGoogle Scholar
  14. Doty RL, Shaman P, Dann M (1984) Development of the university of Pennsylvania smell identification test: a standardized microencapsulated test of olfactory function. Physiol Behav 32(3):489–502CrossRefGoogle Scholar
  15. Gorenstein EE (1982) Frontal lobe functions in psychopaths. J of Abnorm Psychol 95:368–379Google Scholar
  16. Gottfried JA (2007) What can an orbitofrontal cortex-endowed animal do with smells? Ann NY Acad Sci 1121:102–120CrossRefGoogle Scholar
  17. Gottfried JA, O’Doherty J, Dolan RJ (2002) Appetitive and aversive olfactory learning in humans studied using event-related functional magnetic resonance imaging. J Neurosci 22(24):10829–10837Google Scholar
  18. Hare RD (1984) Performance of psychopaths on cognitive task related to frontal lobe function. J Abnorm Psychol 93(2):133–140CrossRefGoogle Scholar
  19. Hare RD (1991) The Hare psychopathy checklist–revised. Multi-Health Systems, TorontoGoogle Scholar
  20. Hare RD (2003) The Hare psychopathy checklist–revised, 2nd edn. Multi-Health Systems, TorontoGoogle Scholar
  21. Harris GT, Rice ME, Cormier CA (1991) Psychopathy and violent recidivism. Law Human Behav 15(6):625–637CrossRefGoogle Scholar
  22. Hart SD, Forth AE, Hare RD (1990) Performance of criminal psychopaths on selected neuropsychological tests. J Abnorm Psychol 99(4):374–379CrossRefGoogle Scholar
  23. Hawkes CH, Doty RL (2009) The neurology of olfaction. Cambridge University Press, CambridgeGoogle Scholar
  24. Hoffman JJ, Hall RW, Bartsch TW (1987) On the relative importance of “psychopathic” personality and alcoholism on neuropsychological measures of frontal lobe dysfunction. J Abnorm Psychol 96:158–160CrossRefGoogle Scholar
  25. Hulshoff Pol HE, Hijman R, Tulleken CA, Heeren TJ, Schneider N, van Ree JM (2002) Odor discrimination in patients with frontal lobe damage and Korsakoff’s syndrome. Neuropsychologia 40:888–891CrossRefGoogle Scholar
  26. Hummel T, Sekinger B, Wolf SR, Pauli E, Kobal G (1997) ‘Sniffin’ Sticks’: olfactory performance assessed by the combined testing of odor identification, odor discrimination and olfactory threshold. Chem Senses 22:39–52CrossRefGoogle Scholar
  27. Hummel T, Kobal G, Gudziol H, Mackay-Sim A (2007) Normative data for the Sniffin’ Sticks including test of odor identification, odor discrimination, and olfactory thresholds: an upgrade based on a group of more than 3,000 subjects. Eur Arch Otorhinolaryngol 264:237–243CrossRefGoogle Scholar
  28. Jimenez DF, Sundrani S, Barone CM (1997) Posttraumatic anosmia in craniofacial trauma. J Craniomaxillofac Trauma 3(1):8–15Google Scholar
  29. LaPierre D, Braun CMJ, Hodgins S (1995) Ventral frontal deficits in psychopathy: neuropsychological test findings. Neuropsychologia 33(2):139–151CrossRefGoogle Scholar
  30. Lezak MD (1995) Neuropsychological assessment, 3rd edn. Oxford University Press, New York, pp 650–685Google Scholar
  31. Lorber MF (2004) Psychophysiology of aggression, psychopathy and conduct problems: a meta-analysis. Psychol Bull 130(4):531–552CrossRefGoogle Scholar
  32. Lykken DT (1957) A study of anxiety in the sociopathic personality. J Abnorm Soc Psych 55:6–10CrossRefGoogle Scholar
  33. Mahmut MK, Homewood J, Stevenson RJ (2008) The characteristics of non-criminals with high psychopathy traits: are they similar to criminal psychopaths? J Res Pers 42:679–692CrossRefGoogle Scholar
  34. Mahmut MK, Menictas C, Stevenson RJ, Homewood J (2011) Validating the factor structure of the self-report psychopathy scale in a community sample. Psychol Assessment 23(3):670–678CrossRefGoogle Scholar
  35. Mehrabian A, Epstein N (1972) A measure of emotional empathy. J Pers 40:525–543CrossRefGoogle Scholar
  36. Mitchell DGV, Colledge E, Leonard A, Blair RJR (2002) Risky decisions and response reversal: is there evidence of orbitofrontal cortex dysfunction in psychopathic individuals? Neuropsychologia 40(12):2013–2022CrossRefGoogle Scholar
  37. Mitchell DGV, Fine C, Richell RA, Newman C, Lumsden J, Blair KS, Blair RJR (2006) Instrumental learning and relearning in individuals with psychopathy and in patients with lesions involving the amygdala or orbitofrontal cortex. Neuropsychology 20(3):280–289CrossRefGoogle Scholar
  38. Motzkin JC, Newman JP, Kiehl KA, Koenigs M (2011) Reduced prefrontal connectivity in psychopathy. J Neurosci 31(48):17348–17357CrossRefGoogle Scholar
  39. Neal TMS, Sellbom M (2012) Examining the factor structure of the Hare self-report psychopathy scale. J Pers Assess 94(3):244–253. doi:10.1080/00223891.2011.648294 CrossRefGoogle Scholar
  40. Öngür D, Price JL (2000) The organization of networks within the orbital and medial prefrontal cortex of rats, monkeys and humans. Cereb Cortex 10:206–219Google Scholar
  41. Paulhus DL, Neumann CS, Hare RD (2012) Manual for the self-report psychopathy scale. Multi-health systems, TorontoGoogle Scholar
  42. Raine A (2008) From genes to brain to antisocial behaviour. Curr Dir Psychol Sci 17(5):323–328CrossRefGoogle Scholar
  43. Raine A, Lencz T, Bihrle S, LaCasse L, Colletti P (2000) Reduced prefrontal gray matter volume and reduced autonomic activity in antisocial personality disorder. Arch Gen Psychiat 57(2):119–127CrossRefGoogle Scholar
  44. Raine A, Ishikawa SS, Arce E, Lencz T, Knuth KH, Bihrle S, LaCasse L, Colletti P (2004) Hippocampal structural asymmetry in unsuccessful psychopaths. Biol Psychiat 55(2):185–191CrossRefGoogle Scholar
  45. Rolls ET (2000) The orbitofrontal cortex and reward. Cereb Cortex 10:284–294CrossRefGoogle Scholar
  46. Rolls ET (2004) The functions of the orbitofrontal cortex. Brain Cognition 55(1):11–29CrossRefGoogle Scholar
  47. Rolls ET, Critchley HD, Mason R, Wakeman EA (1996) Orbitofrontal cortex neurons: role in olfactory and visual association learning. J Neurophysiol 75:970–1981Google Scholar
  48. Roussy S, Toupin J (2000) Behavioral inhibition deficits in juvenile psychopaths. Aggressive Behav 26:413–424CrossRefGoogle Scholar
  49. Royet JP, Hudry J, Zald DH, Godinot D, Gregoire MC, Lavenne F, Costes N, Holley A (2001) Functional neuroanatomy of different olfactory judgments. NeuroImage 13:506–519Google Scholar
  50. Schalling D, Rosen AS (1968) Porteus Maze differences between psychopathic and non-psychopathic criminals. Brit J Soc Clin Psyc 7(3):224–228CrossRefGoogle Scholar
  51. Smith SS, Arnett PA, Newman JP (1992) Neuropsychological differentiation of psychopathic and nonpsychopathic criminal offenders. Pers Indiv Differ 13(11):1233–1243CrossRefGoogle Scholar
  52. Spinella M (2002) A relationship between smell identification and empathy. Int J Neurosci 112:605–612CrossRefGoogle Scholar
  53. Stevenson RJ, Mahmut MK (2011) Olfactory test performance and its relationship with the perceived location of odors. Atten Percept Psycho 73:1966–1976CrossRefGoogle Scholar
  54. Sugiyama K, Hasegawa Y, Sugiyama N, Suzuki M, Watanabe N, Murakami S (2006) Smoking-induced olfactory dysfunction in chronic sinusitis and assessment of brief University of Pennsylvania Smell Identification Test and T & T methods. Am J Rhinol 20:439–444CrossRefGoogle Scholar
  55. Sutker PB, Allain AN (1987) Cognitive abstraction, shifting, and control: clinical sample comparisons of psychopaths and non-psychopaths. J Abnorm Psychol 96(1):73–75CrossRefGoogle Scholar
  56. Taylor J, Lang AR (2006) Psychopathy and substance use disorders. In: Patrick CJ (ed) Handbook of psychopathy. Guilford, New York, pp 495–511Google Scholar
  57. van Honk J, Hermans EJ, Putman P, Montagne B, Schutter DJLG (2002) Defective somatic markers in sub-clinical psychopathy. NeuroReport 13(8):1025–1027CrossRefGoogle Scholar
  58. Williams KM, Paulhus DL, Hare RD (2007) Capturing the four-factor structure of psychopathy in college students via self-report. J Pers Assess 88(2):205–219CrossRefGoogle Scholar
  59. Yang Y, Raine A, Lencz T, Bihrle S, LaCasse L, Colletti P (2005) Volume reduction in prefrontal gray matter in unsuccessful criminal psychopaths. Biol Psychiat 57(10):1103–1108CrossRefGoogle Scholar
  60. Zald DH, Pardo JV (2000) Functional neuroimaging of the olfactory system in humans. Int J Psychophysiol 36:165–181Google Scholar

Copyright information

© Springer Science + Business Media, LLC 2012

Authors and Affiliations

  1. 1.Department of PsychologyMacquarie UniversitySydneyAustralia

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