Book contents
- Frontmatter
- Contents
- Contributors
- Preface
- Acknowledgments
- A Tribute to Edmond Roudnitska
- OLFACTION, TASTE, AND COGNITION
- Section 1 A Specific Type of Cognition
- Section 2 Knowledge and Languages
- Section 3 Emotion
- Section 4 Memory
- Section 5 Neural Bases
- Section 6 Individual Variations
- 24 New Psychophysical Insights in Evaluating Genetic Variation in Taste
- 25 The Individuality of Odor Perception
- 26 Olfactory Cognition at the Start of Life: The Perinatal Shaping of Selective Odor Responsiveness
- 27 Age-related Changes in Chemosensory Functions
- Index
- References
26 - Olfactory Cognition at the Start of Life: The Perinatal Shaping of Selective Odor Responsiveness
Published online by Cambridge University Press: 21 September 2009
Book contents
- Frontmatter
- Contents
- Contributors
- Preface
- Acknowledgments
- A Tribute to Edmond Roudnitska
- OLFACTION, TASTE, AND COGNITION
- Section 1 A Specific Type of Cognition
- Section 2 Knowledge and Languages
- Section 3 Emotion
- Section 4 Memory
- Section 5 Neural Bases
- Section 6 Individual Variations
- 24 New Psychophysical Insights in Evaluating Genetic Variation in Taste
- 25 The Individuality of Odor Perception
- 26 Olfactory Cognition at the Start of Life: The Perinatal Shaping of Selective Odor Responsiveness
- 27 Age-related Changes in Chemosensory Functions
- Index
- References
Summary
In the days following birth, human newborns are swept into a whirlwind of stimuli that are both complex and unpredictable in terms of space, time, and multimodal contingencies. In their very first excursion into the postnatal world, newborns can respond to only a limited array of those stimuli, but their brains possess effective perceptive and integrative capacities that soon will allow them to organize differential perceptions and directional actions in what might otherwise be a “blooming, buzzing confusion.” Our current knowledge of the initial states of perceptual and cognitive functions and their development has been derived almost exclusively from studies of unimodal and cross-modal visual and auditory perceptions (e.g., Gottlieb and Krasnegor, 1985; Lewkowicz and Lickliter, 1994; Kellman and Arterberry, 1998; Slater, 1998; Rochat, 1999). However, evidence that nonvisual, nonaural cues are involved in the partitioning of the neonatal Umwelt has begun to accumulate, both for animals and for humans. Studies have demonstrated, for example, that some newborn animals rely so profoundly and pervasively on olfactory cues that “we cannot appreciate their behavior without understanding the roles of olfaction” (Alberts, 1981, p. 352). Compared with the findings in animal studies, the evidence for olfactory modulation of behavior in our own species remains narrow and shallow, although the body of data is steadily growing. Accordingly, our current knowledge of human cognitive development does not encompass the psychological facets of the chemical senses, a situation that may distort our understanding of the world and mind of the infant (Turkewitz, 1979).
- Type
- Chapter
- Information
- Olfaction, Taste, and Cognition , pp. 421 - 440Publisher: Cambridge University PressPrint publication year: 2002
References
Alberts J R (1981). Ontogeny of Olfaction: Reciprocal Roles of Sensation and Behavior in the Development of Perception. In: Development of Perception: Psychobiological Perspectives, vol. 1, ed. R N Aslin, J R Alberts, & M R Petersen, pp. 322–52. New York: Academic PressCrossRef
Alberts J R (1987). Early Learning and Ontogenetic Adaptation. In: Perinatal Development. A Psychobiological Perspective, ed. N E Krasnegor, E M Blass, M A Hofer, & W P Smotherman, pp. 11–37. Orlando: Academic Press
, , & (1985). Perception of Relational Invariants by Newborns. Developmental Psychology 21:942–8CrossRefGoogle Scholar
& (1986). Olfactory Preferences Resulting from Mere Exposure in Human Neonates. Infant Behavior and Development 9:395–401CrossRefGoogle Scholar
Bornstein M H (1984). A Descriptive Taxonomy of Psychological Categories Used by Infants. In: Origins of Cognitive Skills, ed. C Sophian, pp. 313–38. Hillsdale, NJ: Lawrence Erlbaum
& (1973). Alliesthésie olfactive et prise alimentaire chez l'homme. Journal de Physiologie 66:113–35Google Scholar
& (1975). Acceptance of Novel Flavours Is Increased after Early Exposure of Diverse Taste. Nature 254:689–91CrossRefGoogle Scholar
& (1985). Recognition of Maternal Axillary Odors by Infants. Child Development 56:1593–8CrossRefGoogle Scholar
Coureaud G, Schaal B, Langlois D, & Perrier G (1999). The Mammary Pheromone of the Rabbit: A Milk Odor Fraction That Equals Odor Cues from Lactating Females' Abdomen and from Milk. Presented at the sixteenth annual meeting of the International Society for Chemical Ecology, Marseille, France
, , , & Perrier G (2001). Orientation of Newborn Rabbits to Odours Emitted by Lactating Females: Relative Effectiveness of Surface and Milk Cues. Animal Behavior 61:153–62CrossRefGoogle Scholar
& (1991). Persistent Effects of Early Odor Exposure on Human Neonates. Chemical Senses 16:169–74CrossRefGoogle Scholar
& (1965). Decrement and Recovery of Responses to Olfactory Stimuli in the Human Neonate. Journal of Comparative and Physiological Psychology 59:312–16CrossRefGoogle Scholar
, , & (1963). Olfactory Response and Adaptation in the Human Neonate. Journal of Comparative and Physiological Psychology 56:73–7CrossRefGoogle Scholar
& (1994). Infants' Sensitivity to Arbitrary Object–Odor Pairings. Infant Behavior and Development 17:471–4CrossRefGoogle Scholar
Gottlieb G G & Krasnegor N A (eds.) (1985). Measurement of Audition and Vision in the First Year of Postnatal Life. Norwood, NJ: Ablex
, , , , & (1999). The Influence of Early Experience with Vanillin on Food Preference Later in Life. Chemical Senses 24:465–7CrossRefGoogle Scholar
(1994). Long Term Retention of Kinship Recognition Established during Infancy in the Domestic Dog. Behavioural Processes 33:3–14CrossRefGoogle Scholar
& (1996). Odor Memory: Review and Analysis. Psychonomic Bulletin Review 3:300–13CrossRefGoogle Scholar
Hudson R & Distel H (1995). On the Nature and Action of the Rabbit Nipple-Search Pheromone: A Review. In: Chemical Signals in Vertebrates VII, ed. R Apfelbach, D Müller-Schwarze, K Reuter, & E Weiler, pp. 223–32. London: Elsevier
Hudson R, Schaal B, & Bilko A (1999). Transmission of Olfactory Information from Mother to Young in the European Rabbit. In: Mammalian Social Learning: Comparative and Ecological Perspectives, ed. H O Box & K R Gibson, pp. 141–57. Cambridge University Press
Izard C E (1977). Human Emotions. New York: Plenum Press
, , , & (1998). The Food-related Odor Environment of French Newborns: Human and Formula Milk Odors Compared by Adult Nose. Chemical Senses 24:80–1Google Scholar
Johanson I B & Terry L M (1986). Learning in Infancy. A Mechanism for Behavioral Change during Development. In: Handbook of Behavioral Neurobiology. Vol. 9. Developmental Psychobiology and Behavioral Ecology, ed. E M Blass, pp. 245–81, New York: Plenum Press
Kellman P J & Arterberry M E (1998). The Cradle of Knowledge. Cambridge, MA: MIT Press
, , & (1994). Learning of Suckling Odors by Newborn Rabbits Declines with Age and Suckling Experience. Developmental Psychobiology 27:111–22CrossRefGoogle Scholar
(1996). Stress, Arousal, and Gene Activation at Birth. News in Physiological Sciences 11:214–8Google Scholar
Leon M, Coopersmith R, Lee S, Sullivan R M, Wilson D A, & Woo C C (1987). Neural and Behavioral Plasticity Induced by Early Olfactory Learning. In: Perinatal Development. A Psychobiological Perspective, ed. N E Krasnegor, E M Blass, M A Hofer, & W P Smotherman, pp. 145–67. Orlando: Academic Press
Lewkowicz D J & Lickliter R (eds.) (1994). The Development of Intersensory Perception: Comparative Perspectives. Hillsdale, NJ: Lawrence Erlbaum
(1975). Olfaction in the Development of Social Preferences in the Human Neonate. Ciba Foundation Symposia 33:103–17Google Scholar
, , & (1981). Infant State and Behavior during the First Postpartum Hour. Psychological Record 31:455–8CrossRefGoogle Scholar
, , & (1965). Causation of Sexual Preferences of House Mouse. The Behaviour of Mice Reared by Parents Whose Odour Was Artificially Altered. Atti della Societa Italiana de Scienze Naturali 104:325–38Google Scholar
& (1989). Attractiveness of Lactating Females' Breast Odors to Neonates. Child Development 60:803–10CrossRefGoogle Scholar
& (1997). Familiarité et discrimination olfactive chez le nouveau-né: influence différentielle du mode d'alimentation?Enfance 1:47–61Google Scholar
Marlier L & Schaal B (1999). Feeding-Experience Dependent and Feeding-Experience Independent Odour Preference Responses in Human Infants: In Search of an Inborn Attractive Factor in Human Milk. Presented at the first European Symposium on Olfaction and Cognition, Lyon, France, June 10–12
, , & (1997). Orientation Responses to Biological Odours in the Human Newborn. Initial Pattern and Postnatal Plasticity. Comptes Rendus de l'Académie des Sciences (Paris) Life Sciences 320:999–1005Google Scholar
, , & (1998a). Neonatal Responsiveness to the Odor of Amniotic and Lacteal Fluids: A Test of Perinatal Chemosensory Continuity. Child Development 69:611–23CrossRefGoogle Scholar
, , & (1998b). Bottle-fed Neonates Prefer an Odor Experienced in Utero to an Odor Experienced Postnatally in the Feeding Context. Developmental Psychobiology 33:133–453.0.CO;2-K>CrossRefGoogle Scholar
& (1996). Developmental Changes in the Acceptance of Protein Hydrolysate Formula. Developmental and Behavioral Pediatrics 17:386–91CrossRefGoogle Scholar
& (1998). Infants' Exploration of Scented Toys: Effects of Prior Experiences. Chemical Senses 23:11–17CrossRefGoogle Scholar
Oster H & Rosenstein D (1993). Baby FACS: Analyzing Facial Movements in Infants. Unpublished manuscript
& (1988). Infants' Sensitivity to Arbitrary Pairings of Color and Taste. Infant Behavior and Development 11:245–50CrossRefGoogle Scholar
Rochat P (ed.) (1999). Early Social Development. Hillsdale, NJ: Lawrence Erlbaum
, , & (1996). Perinatal Stimulation and Adaptation of the Neonate. Acta Paediatrica, Supplement 416:8–15Google Scholar
(1969). Psychophysical Scaling of Olfactory Response to the Aliphatic Alcohols in Human Neonates. Journal of Experimental Child Psychology 7:245–54CrossRefGoogle Scholar
Schaal B (1986). Presumed Olfactory Exchanges between Mother and Neonate in Humans. In: Ethology and Psychology, ed. J Le Camus & J Cosnier, pp. 101–10. Toulouse: Privat-IEC.
, , & (1995a). Responsiveness to the Odour of Amniotic Fluid in the Human Neonate. Biology of the Neonate 67:397–406CrossRefGoogle Scholar
, , & (1998). Olfactory Function in the Human Fetus: Evidence from Selective Neonatal Responsiveness to the Odor of Amniotic Fluid. Behavioral Neuroscience 112:1438–49CrossRefGoogle Scholar
, , & (2000). Human Fetuses Learn Odors from Their Pregnant Mother's Diet. Chemical Senses 25:729–37CrossRefGoogle Scholar
, , , , , & (1980). Les stimulations olfactives dans les relation entre l'enfant et la mère. Reproduction, Nutrition, Dévelopment 20:843–58CrossRefGoogle Scholar
Schaal B, Orgeur P, & Rognon C (1995b). Odor Sensing in the Human Fetus: Anatomical, Functional and Chemo-ecological Bases. In: Prenatal Development. A Psychobiological Perspective, ed. J P Lecanuet, N A Krasnegor, W A Fifer, & W P Smotherman, pp. 205–37. Hillsdale, NJ: Lawrence Erlbaum
& (1990). The Significance of Mother's Perfume for Infants in the First Weeks of Their Life. Ethology and Sociobiology 11:145–54CrossRefGoogle Scholar
Schneirla T C (1965). Aspects of Stimulation and Organization in Approach/Withdrawal Processes underlying Vertebrate Behavioral Development. In: Advances in the Study of Behavior, vol. 1, ed. D S Lehrman, R A Hinde, & E Shaw, pp. 1–74. New York: Academic PressCrossRef
Slater A (ed.) (1998). Perceptual Development. Visual, Auditory and Speech Perception in Infancy. Exeter: Psychology Press
, , & (1999). Olfactory Alliesthesia in Human Neonates: Prandial State and Stimulus Familiarity Modulate Facial and Autonomic Responses to Milk Odors. Developmental Psychobiology 35:3–143.0.CO;2-F>CrossRefGoogle Scholar
, , , & (1997). Facial and Autonomic Responses to Biological and Artificial Olfactory Stimuli in Human Neonates: Re-examining Early Hedonic Discrimination of Odors. Physiology and Behavior 62:745–58CrossRefGoogle Scholar
Steiner J E (1979). Human Facial Expressions in Response to Taste and Smell Stimulations. In: Advances in Child Development, vol. 13, ed. L P Lipsitt & H W Reese, pp. 257–95. New York: Academic PressCrossRef
, , & (1991a). Norepinephrine-induced Plasticity and One-Trial Olfactory Learning in Neonatal Rats. Brain Research, Developmental Brain Research 60:219–28CrossRefGoogle Scholar
, , , , , , , & (1991b). Olfactory Classical Conditioning in Neonates. Pediatrics 87:511–17Google Scholar
& (1995). A Possible Protocognitive Role for Odors in Human Infant Development. Brain and Cognition 29:275–93CrossRefGoogle Scholar
Voznessenskaya V, Feoktistova N, & Wysocki C (1999). Is There a Time during Neonatal Development for Maximal Imprinting of Odor? In: Advances in Chemical Signals in Vertebrates, ed. R E Johnston, D Müller-Schwarze, & P W Sorensen, pp. 617–22. New York: Plenum PressCrossRef
& (1994). Neurobiology of Associative Learning in the Neonate: Early Olfactory Learning. Behavioral and Neural Biology 61:1–18CrossRefGoogle Scholar
, , , & (1994). The Effect of the Odour of Mother's Milk and Orange on the Spectral Power of EEG in Infants. Journal of UOEH 16:71–83CrossRefGoogle Scholar
- 11
- Cited by