体味传递情绪: 情绪体味影响情绪交流的作用机制及其生物学意义

doi:10.3724/SP.J.1042.2026.0299

摘要/Abstract

摘要： 情绪体味(emotional body odors)是由情绪唤起时交感神经系统激活外分泌腺分泌的物质, 经皮肤微生物分解后产生的挥发性化合物。这些化合物以化学信号的形式编码并传递情绪信息。当个体嗅到情绪体味时, 通常可诱发相似的情绪状态, 实现嗅觉情绪交流, 但其作用机制与生物学意义却不清晰。研究发现消极情绪体味改变接收者的生理唤醒、认知偏向和行为反应, 介导不同的防御性功能; 积极情绪体味促进情绪感染和社交联结, 增强生理适应性和认知功能。两者共同构成生物进化中“防御-联结”的双向调控体系, 提高社会生存适应性。为明确情绪体味调控功能在群体进化中的意义, 本文提出“交际化学演化假说”, 通过解构情绪体味从化学线索(代谢副产物化)、化学信号(社会适应工具)到信息素(进化稳定策略)的功能层级跃迁, 为人类情绪体味的生物学意义提供了时间维度与选择机制的解释框架。未来研究可以采用社会交互实验范式、双生子研究和虚拟现实技术, 结合高级化学分析技术进一步揭示情绪体味的社交功能和生物学意义, 为情绪障碍患者的情绪识别和表达缺陷提供嗅觉干预新靶点。

关键词: 情绪体味, 情绪交流, 嗅觉, 信息素, 化学交流

Abstract: This review synthesizes recent empirical findings on emotional body odors (EBOs) and advances a unified evolutionary framework that repositions EBOs as adaptive chemical communicators rather than unanalyzed background cues. Rather than repeat basic definitions, the review focuses on three innovations. First, it integrates multi-level evidence—behavioral, autonomic, electrophysiological, neuroimaging, and molecular—to map the specific response profiles that different EBOs evoke in receivers. Second, it offers a critical molecular and receptor-level appraisal that challenges the default classification of EBOs as pheromones. Third, it proposes the “communicative chemical evolution hypothesis,” a testable model that links learning, selection, and population dynamics to stages in the functional maturation of chemical signals.
Empirical synthesis reveals reproducible, emotion-specific effects. Negative EBOs (fear, anxiety, anger, sadness) trigger rapid threat-oriented cascades. Fear body odor (FBO) reliably increases sympathetic markers, modulates facial motor responses (orbicularis oculi, corrugator supercilii), reduces heart rate variability, and biases perceptual and decision processes toward threat. Electrophysiology shows early sensory amplification (N1/P1) and enhanced face-processing components (N170, P3), while neuroimaging highlights amygdala-fusiform-ventromedial prefrontal circuits that mediate threat detection and attention allocation. Anxiety odors produce similar autonomic shifts, strengthen startle reflexes, and bias risk assessment. Anger odors amplify skin conductance and recruit thalamic-hypothalamic-insula-amygdala-cingulate pathways, particularly in high-trait-anxiety participants. Sadness-related chemosignals (e.g., from tears) decrease testosterone and sexual arousal in males, and dampen hypothalamic and reward-related responses. By contrast, positive EBOs (e.g., happiness odor) increase parasympathetic indices, induce Duchenne smiles, elevate late positive potentials (LPP), and enhance cognitive flexibility and cooperative tendencies. Across studies, the functional dichotomy is robust: negatives favor rapid defense and avoidance; positives promote affiliation and exploration.
Comparative and cross-cultural evidence provides preliminary support for partial universality. Cross-species responses to FBOs (dogs, horses) and consistent effects across East Asian and Western samples suggest conserved processing biases. However, most evidence stems from controlled lab paradigms that use direct nasal delivery of concentrated samples. This raises ecological validity concerns and limits inferences about real-world sender-receiver dynamics.
At the molecular level, the review identifies a central gap: EBOs lack clearly identified, steroidal molecules at biologically plausible concentrations that would parallel classical pheromones (e.g., androstadienone). Receptor evidence is likewise scarce, and human vomeronasal function appears vestigial. These facts argue against uncritical classification of EBOs as pheromones. The review proposes instead that EBOs function primarily via the main olfactory epithelium and associative learning mechanisms, interacting with individual experience to produce stable behavioral regularities.
The communicative chemical evolution hypothesis formalizes this view. It frames EBOs on a continuum from chemical cues (metabolic by-products) to chemical signals (contextually exploited cues) and, under stringent conditions of genetic fixation and sender-receiver reciprocity, to releaser pheromones. The model emphasizes three drivers of functional transition: (1) unique chemical features that allow consistent discrimination; (2) repeated cue-response pairings that generate learned associations and canalize responses; and (3) population-level selection that stabilizes sender and receiver strategies (a Baldwin-effect mechanism). By integrating learning and selection, the model explains cross-cultural consistency without presuming purely innate coding.
The review also evaluates empirical limitations and methodological fixes. Current work over-relies on single-receiver paradigms, neglects sender benefits, and ignores chronic exposure consequences. To move the field forward, the review recommends: multi-agent interaction experiments to capture bidirectional dynamics; twin and family designs to partition genetic and experiential variance; longitudinal intergenerational sampling to detect fixation; virtual reality coupled with high-resolution olfactometers for ecological control; and metabolomic fingerprinting to discover candidate biomarkers. These approaches will enable direct tests of sender-receiver reciprocity, fitness consequences, and the molecular prerequisites for pheromone status.
Finally, the review sketches translational pathways. If validated, EBO-based interventions could augment exposure therapies, enhance social-skill training, or serve as adjuncts in assistive technologies for autism spectrum disorders. Yet translation requires caution: weak effect sizes, contextual dependence, and ethical issues around manipulation of chemosignals demand rigorous validation.
In sum, this review advances theory and method by (1) distinguishing signal from cue at molecular and behavioral scales, (2) articulating a testable evolutionary pathway for EBOs, and (3) specifying concrete empirical programs to evaluate whether, when, and how human emotional chemosignals become evolutionarily stabilized communicative tools.

Key words: emotional body odor, emotional communication, olfaction, pheromones, chemical communication

中图分类号:

B842
B845

周兴攀, 刘沛菡, 吴奇, 雷怡. (2026). 体味传递情绪: 情绪体味影响情绪交流的作用机制及其生物学意义. 心理科学进展 , 34(2), 299-312.

ZHOU Xingpan, LIU Peihan, WU Qi, LEI Yi. (2026). Emotional body odor: Mechanisms in emotional communication and biological significance. Advances in Psychological Science, 34(2), 299-312.

参考文献

[1] Adolph D., Meister L., & Pause B. M. (2013). Context counts! Social anxiety modulates the processing of fearful faces in the context of chemosensory anxiety signals.Frontiers in Human Neuroscience, 7, 283.
[2] Adolph D., Schlösser S., Hawighorst M., & Pause B. M. (2010). Chemosensory signals of competition increase the skin conductance response in humans.Physiology & Behavior, 101(5), 666-671.
[3] Agron S., de March C. A., Weissgross R., Mishor E., Gorodisky L., Weiss T., .. Sobel N. (2023). A chemical signal in human female tears lowers aggression in males.PLoS Biology, 21(12), e3002442.
[4] Albrecht J., Demmel M., Schöpf V., Kleemann A. M., Kopietz R., May J., .. Wiesmann M. (2011). Smelling chemosensory signals of males in anxious versus nonanxious condition increases state anxiety of female subjects.Chemical Senses, 36(1), 19-27.
[5] Alcañiz M., Giglioli I. A. C., Carrasco-ribelles L. A., Minissi M. E., López C. G., & Semin G. R. (2023). How priming with body odors affects decision speeds in consumer behavior.Scientific Reports, 13(1), 609.
[6] Alexandra Kredlow M., Fenster R. J., Laurent E. S., Ressler K. J., & Phelps E. A. (2022). Prefrontal cortex, amygdala, and threat processing: Implications for PTSD.Neuropsychopharmacology, 47(1), 247-259.
[7] Barson J. R., Mack N. R., & Gao W. J. (2020). The paraventricular nucleus of the thalamus is an important node in the emotional processing network.Frontiers in Behavioral Neuroscience, 14, 598469.
[8] Behnke M., Kreibig S. D., Kaczmarek L. D., Assink M., & Gross J. J. (2022). Autonomic nervous system activity during positive emotions: A meta-analytic review.Emotion Review, 14(2), 132-160.
[9] Bensafi M., Tsutsui T., Khan R., Levenson R. W., & Sobel N. (2004). Sniffing a human sex-steroid derived compound affects mood and autonomic arousal in a dose-dependent manner.Psychoneuroendocrinology, 29(10), 1290-1299.
[10] Bylsma L. M., Gračanin A., & Vingerhoets A. J. (2019). The neurobiology of human crying.Clinical Autonomic Research, 29, 63-73.
[11] Callara A. L., Cecchetto C., Dal Bò E., Citi L., Gentili C., Vanello N., .. Greco A. (2022, July). Human body odors of happiness and fear modulate the late positive potential component during neutral face processing: A preliminary ERP study on healthy subjects. In2022 44th Annual International Conference of the IEEE Engineering in Medicine & Biology Society (EMBC)(pp. 4093-4096).
[12] Calvi E., Quassolo U., Massaia M., Scandurra A., D'Aniello B., & D'Amelio P. (2020). The scent of emotions: A systematic review of human intra‐and interspecific chemical communication of emotions.Brain and Behavior, 10(5), e01585.
[13] Cecchetto C., Dal Bò E., Eliasson E. T., Vigna E., Natali L., Scilingo E. P., .. Gentili C. (2025). Sniffing out a solution: How emotional body odors can improve mindfulness therapy for social anxiety.Journal of Affective Disorders, 369, 1082-1089.
[14] Chen, D., & Haviland-Jones, J. (2000). Human olfactory communication of emotion.Perceptual and Motor Skills, 91(3), 771-781.
[15] Chen R., Zhu Z., Ji S., Geng Z., Hou Q., Sun X., & Fu X. (2020). Sweat gland regeneration: Current strategies and future opportunities.Biomaterials, 255, 120201.
[16] D’Aniello B., Pinelli C., Scandurra A., Di Lucrezia A., Aria M., & Semin G. R. (2023). When are puppies receptive to emotion-induced human chemosignals? The cases of fear and happiness.Animal Cognition, 26(4), 1241-1250.
[17] D’Aniello B., Semin G. R., Alterisio A., Aria M., & Scandurra A. (2018). Interspecies transmission of emotional information via chemosignals: From humans to dogs (Canis lupus familiaris).Animal Cognition, 21, 67-78.
[18] d’Ingeo S., Siniscalchi M., Straziota V., Ventriglia G., Sasso R., & Quaranta A. (2023). Relationship between asymmetric nostril use and human emotional odours in cats.Scientific Reports, 13(1), 10982.
[19] Dal Bò E., Cecchetto C., Callara A. L., Greco A., Mura F., Vanello N., .. Gentili C. (2024). Emotion perception through the nose: How olfactory emotional cues modulate the perception of neutral facial expressions in affective disorders.Translational Psychiatry, 14(1), 342.
[20] de Groot J. H., Haertl T., Loos H. M., Bachmann C., Kontouli A., & Smeets M. A. (2023). Unraveling the universality of chemical fear communication: Evidence from behavioral, genetic, and chemical analyses. Chemical Senses, 48, bjad046.
[21] de Groot J. H., Kirk P. A., & Gottfried J. A. (2020). Encoding fear intensity in human sweat.Philosophical Transactions of the Royal Society B, 375(1800), 20190271.
[22] de Groot J. H., Kirk P. A., & Gottfried J. A. (2021). Titrating the smell of fear: Initial evidence for dose-invariant behavioral, physiological, and neural responses.Psychological Science, 32(4), 558-572.
[23] de Groot J. H., Semin G. R., & Smeets M. A. (2014). Chemical communication of fear: A case of male-female asymmetry.Journal of Experimental Psychology: General, 143(4), 1515-1525.
[24] de Groot J. H., Semin G. R., & Smeets M. A. (2017). On the communicative function of body odors: A theoretical integration and review.Perspectives on Psychological Science, 12(2), 306-324.
[25] de Groot J. H., Smeets M. A., & Semin G. R. (2015). Rapid stress system drives chemical transfer of fear from sender to receiver.PLoS One, 10(2), e0118211.
[26] de Groot J. H., Smeets M. A., Kaldewaij A., Duijndam M. J., & Semin G. R. (2012). Chemosignals communicate human emotions.Psychological Science, 23(11), 1417-1424.
[27] de Groot J. H., Smeets M. A., Rowson M. J., Bulsing P. J., Blonk C. G., Wilkinson J. E., & Semin G. R. (2015). A sniff of happiness.Psychological Science, 26(6), 684-700.
[28] de Groot J. H., van Houtum L. A., Gortemaker I., Ye Y., Chen W., Zhou W., & Smeets M. A. (2018). Beyond the west: Chemosignaling of emotions transcends ethno-cultural boundaries.Psychoneuroendocrinology, 98, 177-185.
[29] Destrez A., Costes-Thiré M., Viart A. S., Prost F., Patris B., & Schaal B. (2021). Male mice and cows perceive human emotional chemosignals: A preliminary study.Animal Cognition, 24(6), 1205-1214.
[30] Di Cicco F., Evans R. L., James A. G., Weddell I., Chopra A., & Smeets M. A. (2023). Intrinsic and extrinsic factors affecting axillary odor variation. A comprehensive review.Physiology & Behavior, 270, 114307.
[31] Dimitroff S. J., Kardan O., Necka E. A., Decety J., Berman M. G., & Norman G. J. (2017). Physiological dynamics of stress contagion.Scientific Reports, 7, 6168.
[32] Ekman, P., & Friesen, W. V. (2003). Unmasking the face: A guide to recognizing emotions from facial clues (Vol. 10). Ishk.
[33] Endevelt-Shapira Y., Perl O., Ravia A., Amir D., Eisen A., Bezalel V., .. Sobel N. (2018). Altered responses to social chemosignals in autism spectrum disorder.Nature Neuroscience, 21(1), 111-119.
[34] Feldt-Rasmussen U., Effraimidis G., & Klose M. (2021). The hypothalamus-pituitary-thyroid (HPT)-axis and its role in physiology and pathophysiology of other hypothalamus- pituitary functions.Molecular and Cellular Endocrinology, 525, 111173.
[35] Ferdowsi S., Ognibene D., Foulsham T., Abolghasemi V., Li W., & Citi L. (2020, October). Human chemosignals modulate interactions between social and emotional brain areas. In2020 IEEE 20th International Conference on Bioinformatics and Bioengineering (BIBE)(pp. 513-518).
[36] Ferreira J., Parma V., Alho L., Silva C. F., & Soares S. C. (2018). Emotional body odors as context: Effects on cardiac and subjective responses.Chemical Senses, 43(5), 347-355.
[37] Ferrero D. M., Moeller L. M., Osakada T., Horio N., Li Q., Roy D. S., .. Liberles S. D. (2013). A juvenile mouse pheromone inhibits sexual behaviour through the vomeronasal system.Nature, 502(7471), 368-371.
[38] Fox A. S., Oler J. A., Tromp D. P., Fudge J. L., & Kalin N. H. (2015). Extending the amygdala in theories of threat processing.Trends in Neurosciences, 38(5), 319-329.
[39] Futuyma D. J., & Kirkpatrick, M. (2023). Evolution (5th ed.). Oxford University Press..
[40] Gelstein S., Yeshurun Y., Rozenkrantz L., Shushan S., Frumin I., Roth Y., & Sobel N. (2011). Human tears contain a chemosignal.Science, 331(6014), 226-230.
[41] Gioia F., Callara A. L., Bruderer T., Ripszam M., Di Francesco F., Scilingo E. P., & Greco A. (2022, June). Potential physiological stress biomarkers in human sweat. In2022 IEEE International Symposium on Medical Measurements and Applications (MeMeA)(pp. 01-06).
[42] Gomes, N., & Semin, G. R. (2021). The function of fear chemosignals: Preparing for danger. Chemical Senses, 46, bjab005.
[43] Gomes N., Pause B. M., Smeets M. A., & Semin G. R. (2023). Comparing fear and anxiety chemosignals: Do they modulate facial muscle activity and facilitate identifying facial expressions? Chemical Senses, 48, bjad016.
[44] Gomes N., Silva F., & Semin G. R. (2020). The lasting smell of emotions: The effects of reutilizing fear sweat samples.Behavior Research Methods, 52(6), 2438-2451.
[45] Gračanin A., Bylsma L. M., & Vingerhoets A. J. (2018). Why only humans shed emotional tears: Evolutionary and cultural perspectives.Human Nature, 29(2), 104-133.
[46] Gračanin A., Van Assen M. A., Omrčen V., Koraj I., & Vingerhoets A. J. (2017). Chemosignalling effects of human tears revisited: Does exposure to female tears decrease males’ perception of female sexual attractiveness?Cognition and Emotion, 31(1), 139-150.
[47] Guo X., He H., Sun J., & Kang L. (2023). Plasticity of aggregation pheromones in insects.Current Opinion in Insect Science, 59, 101098.
[48] Hadjikhani, N., & de Gelder, B. (2003). Seeing fearful body expressions activates the fusiform cortex and amygdala.Current Biology, 13(24), 2201-2205.
[49] Haegler K., Zernecke R., Kleemann A. M., Albrecht J., Pollatos O., Brückmann H., & Wiesmann M. (2010). No fear no risk! Human risk behavior is affected by chemosensory anxiety signals.Neuropsychologia, 48(13), 3901-3908.
[50] Hare R. M., Schlatter S., Rhodes G., & Simmons L. W. (2017). Putative sex-specific human pheromones do not affect gender perception, attractiveness ratings or unfaithfulness judgements of opposite sex faces.Royal Society Open Science, 4(3), 160831.
[51] Heiss S., Vaschillo B., Vaschillo E. G., Timko C. A., & Hormes J. M. (2021). Heart rate variability as a biobehavioral marker of diverse psychopathologies: A review and argument for an “ideal range”. Neuroscience & Biobehavioral Reviews, 121, 144-155.
[52] Holton E., Grohn J., Ward H., Manohar S. G., O’reilly J. X., & Kolling N. (2024). Goal commitment is supported by vmPFC through selective attention.Nature Human Behaviour, 8(7), 1351-1365.
[53] Howard, J. D., & Gottfried, J. A. (2014). Configural and elemental coding of natural odor mixture components in the human brain.Neuron, 84(4), 857-869.
[54] Jabbi M., Swart M., & Keysers C. (2007). Empathy for positive and negative emotions in the gustatory cortex.Neuroimage, 34(4), 1744-1753.
[55] Kamiloğlu R. G., Smeets M. A., de Groot J. H., & Semin G. R. (2018). Fear odor facilitates the detection of fear expressions over other negative expressions.Chemical Senses, 43(6), 419-426.
[56] Karlson, P., & Lüscher, M. (1959). ‘Pheromones’: A new term for a class of biologically active substances.Nature, 183(4653), 55-56.
[57] Lanata A., Nardelli M., Valenza G., Baragli P., D’Aniello B., Alterisio A., .. Scilingo E. P. (2018, July). A case for the interspecies transfer of emotions: A preliminary investigation on how humans odors modify reactions of the autonomic nervous system in horses. In2018 40th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)(pp. 522-525).
[58] Larrigaldie I., Damon F., Mousqué S., Patris B., Lansade L., Schaal B., & Destrez A. (2024). Do sheep (Ovis aries) discriminate human emotional odors?Animal Cognition, 27(1), 51.
[59] LeDoux, J. E., & Pine, D. S. (2016). Using neuroscience to help understand fear and anxiety: A two-system framework.American Journal of Psychiatry, 173(11), 1083-1093.
[60] Leung F. Y. N., Sin J., Dawson C., Ong J. H., Zhao C., Veić A., & Liu F. (2022). Emotion recognition across visual and auditory modalities in autism spectrum disorder: A systematic review and meta-analysis.Developmental Review, 63, 101000.
[61] Liberles, S. D. (2014). Mammalian pheromones.Annual Review of Physiology, 76, 151-175.
[62] Lu J., Ye Y., & Wu Y. (2024). Little evidence that androstadienone affects social distance-dependent prosocial behaviour: A pre-registered study.Royal Society Open Science, 11(5), 240004.
[63] Lübke K. T., Storch D., & Pause B. M. (2024). Sexual orientation affects neural responses to subtle social aggression signals.Archives of Sexual Behavior, 53(1), 153-175.
[64] Maier A., Scheele D., Spengler F. B., Menba T., Mohr F., Güntürkün O., .. Hurlemann R. (2019). Oxytocin reduces a chemosensory-induced stress bias in social perception.Neuropsychopharmacology, 44(2), 281-288.
[65] Mazzola V., Arciero G., Fazio L., Lanciano T., Gelao B., Bertolino A., & Bondolfi G. (2020). Emotion-body connection dispositions modify the insulae-midcingulate effective connectivity during anger processing.PloS One, 15(2), e0228404.
[66] Meister, L., & Pause, B. M. (2021). It’s trust or risk? Chemosensory anxiety signals affect bargaining in women.Biological Psychology, 162, 108114.
[67] Miranda J. A., Canabal M. F., Gutiérrez-Martín L., Lanza- Gutierrez J. M., Portela-García M., & López-Ongil C. (2021). Fear recognition for women using a reduced set of physiological signals.Sensors, 21(5), 1587.
[68] Moore, B. C. (2012). An introduction to the psychology of hearing (Chapter 2, pp.57-64). Brill.
[69] Motzkin J. C., Philippi C. L., Wolf R. C., Baskaya M. K., & Koenigs M. (2015). Ventromedial prefrontal cortex is critical for the regulation of amygdala activity in humans.Biological Psychiatry, 77(3), 276-284.
[70] Mujica-Parodi L. R., Strey H. H., Frederick B., Savoy R., Cox D., Botanov Y., .. Weber J. (2009). Chemosensory cues to conspecific emotional stress activate AMYgdala in humans.PloS One, 4(7), e6415.
[71] Mutic S., Brünner Y. F., Rodriguez-Raecke R., Wiesmann M., & Freiherr J. (2017). Chemosensory danger detection in the human brain: Body odor communicating aggression modulates limbic system activation.Neuropsychologia, 99, 187-198.
[72] Mutic S., Parma V., Brünner Y. F., & Freiherr J. (2016). You smell dangerous: Communicating fight responses through human chemosignals of aggression.Chemical Senses, 41(1), 35-43.
[73] Ortegón S. R., Carlos O., Robert-Hazotte A., Lelgouarch A., Desoche C., Duncan K. K., .. Ferdenzi C. (2023). Investigating the human chemical communication of positive emotions using a virtual reality-based mood induction.Physiology & Behavior, 264, 114147.
[74] Pause B. M., Adolph D., Prehn-Kristensen A., & Ferstl R. (2009). Startle response potentiation to chemosensory anxiety signals in socially anxious individuals.International Journal of Psychophysiology, 74(2), 88-92.
[75] Pause B. M., Lübke K., Laudien J. H., & Ferstl R. (2010). Intensified neuronal investment in the processing of chemosensory anxiety signals in non-socially anxious and socially anxious individuals.PloS One, 5(4), e10342.
[76] Pause B. M., Storch D., & Lübke K. T. (2020). Chemosensory communication of aggression: Women's fine-tuned neural processing of male aggression signals.Philosophical Transactions of the Royal Society B, 375(1800), 20190270.
[77] Prehn A., Ohrt A., Sojka B., Ferstl R., & Pause B. M. (2006). Chemosensory anxiety signals augment the startle reflex in humans.Neuroscience Letters, 394(2), 127-130.
[78] Prehn-Kristensen A., Wiesner C., Bergmann T. O., Wolff S., Jansen O., Mehdorn H. M., .. Pause B. M. (2009). Induction of empathy by the smell of anxiety.PloS One, 4(6), e5987.
[79] Quintana P., Nolet K., Baus O., & Bouchard S. (2019). The effect of exposure to fear-related body odorants on anxiety and interpersonal trust toward a virtual character.Chemical Senses, 44(9), 683-692.
[80] Regnier, F. E., & Law, J. H. (1968). Insect pheromones.Journal of Lipid Research, 9(5), 541-551.
[81] Ressler K. J., Berretta S., Bolshakov V. Y., Rosso I. M., Meloni E. G., Rauch S. L., & Carlezon Jr, W. A. (2022). Post-traumatic stress disorder: Clinical and translational neuroscience from cells to circuits.Nature Reviews Neurology, 18(5), 273-288.
[82] Richard Ortegón S., Fournel A., Carlos O., Kawabata Duncan K., Hirabayashi K., Tagai K., .. Ferdenzi C. (2022). And I’m feeling good: Effect of emotional sweat and perfume on others’ physiology, verbal responses, and creativity. Chemical Senses, 47, bjac012.
[83] Riddell P., Paris M. C., Joonè C. J., Pageat P., & Paris D. B. (2021). Appeasing pheromones for the management of stress and aggression during conservation of wild canids: Could the solution be right under our nose?Animals, 11(6), 1574.
[84] Rocha M., Parma V., Lundström J. N., & Soares S. C. (2018). Anxiety body odors as context for dynamic faces: Categorization and psychophysiological biases.Perception, 47(10-11), 1054-1069.
[85] Rodriguez I., Greer C. A., Mok M. Y., & Mombaerts P. (2000). A putative pheromone receptor gene expressed in human olfactory mucosa.Nature Genetics, 26(1), 18-19.
[86] Roseman, I. J. (2018). Functions of anger in the emotion system.The Function of Emotions: When and Why Emotions Help Us, 141-173.
[87] Rubin D., Botanov Y., Hajcak G., & Mujica-Parodi L. R. (2012). Second-hand stress: Inhalation of stress sweat enhances neural response to neutral faces.Social Cognitive and Affective Neuroscience, 7(2), 208-212.
[88] Sabiniewicz A., Tarnowska K., Świątek R., Sorokowski P., & Laska M. (2020). Olfactory-based interspecific recognition of human emotions: Horses (Equus ferus caballus) can recognize fear and happiness body odour from humans (Homo sapiens).Applied Animal Behaviour Science, 230, 105072.
[89] Sakamoto K., Butera M. A., Zhou C., Maurizi G., Chen B., Ling L., .. Buettner C. (2025). Overnutrition causes insulin resistance and metabolic disorder through increased sympathetic nervous system activity.Cell Metabolism, 37(1), 121-137.
[90] Semin G. R., DePhillips M., & Gomes N. (2024). Investigating inattentional blindness through the lens of fear chemosignals.Psychological Science, 35(1), 72-81.
[91] Silva F., Gomes N., Korb S., & Semin G. R. (2020). Not all emotions are equal: Fear chemosignals lower awareness thresholds only for fearful faces.Chemical Senses, 45(7), 601-608.
[92] Simpson, G. G. (1953). The Baldwin effect.Evolution, 7(2), 110-117.
[93] Singh P. B., Young A., Lind S., Leegaard M. C., Capuozzo A., & Parma V. (2018). Smelling anxiety chemosignals impairs clinical performance of dental students.Chemical Senses, 43(6), 411-417.
[94] Smeets M. A., Rosing E. A., Jacobs D. M., van Velzen E., Koek J. H., Blonk C., .. Semin G. R. (2020). Chemical fingerprints of emotional body odor. Metabolites, 10(3), 84.
[95] Smith, E. R., & Semin, G. R. (2007). Situated social cognition.Current Directions in Psychological Science, 16(3), 132-135.
[96] Sorokowski P., Karwowski M., Misiak M., Marczak M. K., Dziekan M., Hummel T., & Sorokowska A. (2019). Sex differences in human olfaction: A meta-analysis.Frontiers in Psychology, 10, 242.
[97] Steiger S., Schmitt T., & Schaefer H. M. (2011). The origin and dynamic evolution of chemical information transfer.Proceedings of the Royal Society B: Biological Sciences, 278(1708), 970-979.
[98] Stökl, J., & Steiger, S. (2017). Evolutionary origin of insect pheromones.Current Opinion in Insect Science, 24, 36-42
[99] Susskind J. M., Lee D. H., Cusi A., Feiman R., Grabski W., & Anderson A. K. (2008). Expressing fear enhances sensory acquisition.Nature Neuroscience, 11(7), 843-850.
[100] Van Kleef, G. A., & Côté, S. (2022). The social effects of emotions.Annual Review of Psychology, 73(1), 629-658.
[101] Verheggen F. J., Haubruge E., & Mescher M. C. (2010). Alarm pheromones-chemical signaling in response to danger.Vitamins & Hormones, 83, 215-239.
[102] Voznessenskaya V. V., Klyuchnikova M. A., & Laktionova T. K. (2022). Evolution of pheromones in mammals.Biology Bulletin Reviews, 12(1), 49-64.
[103] Williams, R. (2017). Anger as a basic emotion and its role in personality building and pathological growth: The neuroscientific, developmental and clinical perspectives.Frontiers in Psychology, 8, 1950.
[104] Wilson C., Campbell K., Petzel Z., & Reeve C. (2022). Dogs can discriminate between human baseline and psychological stress condition odours.PLoS One, 17(9), e0274143.
[105] Wu Y., Chen K., Xing C., Huang M., Zhao K., & Zhou W. (2024). Human olfactory perception embeds fine temporal resolution within a single sniff.Nature Human Behaviour, 1-11.
[106] Wudarczyk O. A., Kohn N., Bergs R., Goerlich K. S., Gur R. E., Turetsky B., .. Habel U. (2016). Chemosensory anxiety cues enhance the perception of fearful faces-An fMRI study.Neuroimage, 143, 214-222.
[107] Wudarczyk O. A., Kohn N., Bergs R., Gur R. E., Turetsky B., Schneider F., & Habel U. (2015). Chemosensory anxiety cues moderate the experience of social exclusion- an fMRI investigation with Cyberball.Frontiers in Psychology, 6, 1475.
[108] Wunder A., Ludwig J., Haertl T., Arnhardt S., Schwinn L., Chellapandian D. C., .. Freiherr J. (2023). Can you smell my stress? Influence of stress chemosignals on empathy and emotion recognition in depressed individuals and healthy controls.Physiology & Behavior, 270, 114309.
[109] Wyatt, T. D. (2020). Reproducible research into human chemical communication by cues and pheromones: Learning from psychology's renaissance.Philosophical Transactions of the Royal Society B, 375(1800), 20190262.
[110] Zhou, W., & Chen, D. (2009). Fear-related chemosignals modulate recognition of fear in ambiguous facial expressions.Psychological Science, 20(2), 177-183.