The effects of different sensory functions on depression and its neuromechanism

doi:10.3724/SP.J.1042.2023.00641

Abstract

Abstract:

The ancient term "sense" is one of the most important topics in psychology. The brain receives information from the outside world through the visual, auditory, olfactory, taste, and tactile sensory channels. Different senses form human cognition and experience by converting information from the real world into electrical signals that the brain can process. Sensory deprivation occurs when the amount of sensory stimuli that a person receives decreases or falls below a normal threshold, and this change becomes a risk factor for neuropsychiatric disorders such as depression. Therefore, different sensory impairments are involved in the central mechanism of depression, and appropriate stimulation based on different sensory channels and multi-sensory combined interventions may also play a significant role in its treatment. Among the effects of different sensory functions on mental health, depression has a greater proportion; however, the patient's disease type, age stage, gender difference (especially during pregnancy and postpartum period), and other factors can affect the susceptibility to depression. Yet, the sensory stimulation that the body receives is not “more is better”; excessive sensory stimulation will also lead to the imbalance of the body's sensory and emotional function, as blue light and noise over stimulation will induce depression. The appropriate sensory stimulation can be used as a "compensatory input" to effectively improve the symptoms and severity of depression.
Taking "symptoms-brain region-mechanism-treatment" as the logical thread, the author systematically reviewed the clinical symptoms of depression, the neural mechanisms of depression, and the antidepressant treatments based on sensory stimulation for the first time in persons with five major sensory disorders. The results show that different sensory dysfunctions in the neural mechanisms related to depression may represent the different pathologies of depression, involving neuronal electrical activity (firing of certain neurons and activation of neural circuits, etc.) and neural biochemical changes (neuroplasticity and neurogenesis, inflammatory immunity and HPA axis, neurohormones and neurotransmitters, etc.); these mainly occur in the limbic system (amygdala, hippocampus, hypothalamus, nucleus accumbens, cingulate gyrus, and olfactory bulb) and its adjacent brain regions (lateral habenula nucleus, nucleus of solitary tract, superior colliculus), which involve the insular lobe, temporal lobe, frontal lobe, etc. The review found that individualized visual cortex transcranial magnetic stimulation, visual art therapy, transcutaneous auricular vagus nerve stimulation, frequency conversion music therapy, olfactory-based deep brain stimulation, intranasal administration, psychological behavioral therapy based on sugar intake, massage therapy with music and fragrance, and reiki therapy had good curative effects and few side effects for the improvement of depression symptoms, and were appropriate for clinical application.
At present, the research on the relationship between sensory disorders as well as their treatment and neuropsychiatric diseases is still very immature, the research on the underlying mechanisms is still in the initial stage, and the development of relevant treatment methods is just beginning. There are still many problems that need to be clarified and solved. Future research should focus on the extraction of different sensory information, which will provide a new research perspective for the etiology and treatment of human depression. In the interdisciplinary context of physics, chemistry, psychology, biology and computer science, researchers should develop how to make reasonable assessments based on certain sensory parameters to assist the medical treatment of depression. For example, with the help of artificial intelligence technology, audio-visual sensory information will be digitized, more practical wearable devices will be invented, and virtual reality and augmented-reality technology will be accelerated to contribute to depression inquiry. In a word, the extraction of sensory information will help in the intervention and rehabilitation of mental diseases, and enable digital medicine, technological medicine, and precision medicine, to rewrite the model of traditional medical thinking, and promote humans into a new medical era.

Key words: visual, auditory, olfactory, taste, tactile, depression

CLC Number:

B845

LIU Wenbin, QI Zhengtang, LIU Weina. The effects of different sensory functions on depression and its neuromechanism[J]. Advances in Psychological Science, 2023, 31(4): 641-656.

Figures/Tables 1

References 134

[1]	邓小峰. (2018). 电针治疗噪声聋伴发抑郁症状的疗效评价及免疫机制探讨 (博士学位论文). 广州中医药大学.
[2]	郝婷, 李红梅, 张俊, 杨启慧, 杨佳. (2022). 视觉艺术疗法对老年乳腺癌患者认知障碍和负性情绪的影响. 中国护理管理, 22(2), 201-206.
[3]	赫晨, 黄淑丽, 刘景, 宋怡然, 鲁伟, 张知彬. (2021). 视觉和嗅觉密度信号对布氏田鼠社会应激的影响. 兽类学报, 41(4), 416-430. doi: 10.16829/j.slxb.150532
[4]	华庆平, 罗非. (2007). 第二触觉系统:编码触觉情绪成分的C纤维. 生理科学进展, 38(4), 323-326.
[5]	江帆. (2021). 山东省冠县听障老年人抑郁现状调查与基于助听器的干预效果评价研究 (博士学位论文). 山东大学, 济南.
[6]	李琨. (2018). 成年触觉丰富对小鼠焦虑样行为和记忆功能的影响与机制 (硕士学位论文). 浙江大学, 杭州.
[7]	马潇斌. (2020). Soundsory变频音乐疗法对冠心病共病高血压患者认知障碍和焦虑抑郁的干预效果 (硕士学位论文). 华北理工大学, 唐山.
[8]	马志辉. (2021). 多感官刺激对脑卒中后认知功能障碍和焦虑抑郁的干预效果(硕士学位论文). 华北理工大学, 唐山.
[9]	谢青莲, 李喆, 邓伟, 王强, 李名立, 李寅飞,... 郑重. (2016). 双相障碍抑郁发作与单相抑郁症患者听觉事件相关电位P300的对照研究. 临床精神医学杂志, 26(5), 302-305.
[10]	张珍珍, 陈佩佩, 路立红, 徐夫真. (2015). 听障青少年疏离感与抑郁的关系: 自我概念的中介效应. 中国特殊教育, 180(6), 35-38.
[11]	Agren H., Osterberg B., & Franzen O. (1983). Depression and somatosensory evoked potentials: II. Correlations between SEP and depressive phenomenology. Biological Psychiatry, 18(6), 651-659. pmid: 6135458
[12]	Amigó J., Díaz A., Pilar-Cuéllar F., Vidal R., Martín A., Compan V., .... Castro E. (2016). The absence of 5-HT₄ receptors modulates depression-and anxiety-like responses and influences the response of fluoxetine in olfactory bulbectomised mice: Adaptive changes in hippocampal neuroplasticity markers and 5-HT1A autoreceptor. Neuropharmacology, 111(12), 47-58. doi: 10.1016/j.neuropharm.2016.08.037 URL
[13]	An K., Zhao H., Miao Y., Xu Q., Li Y. F., Ma Y. Q., .... Xue T. (2020). A circadian rhythm-gated subcortical pathway for nighttime-light-induced depressive-like behaviors in mice. Nature Neuroscience, 23(7), 869-880. doi: 10.1038/s41593-020-0640-8 pmid: 32483349
[14]	Asal N., Bayar M. N., Inal M., Sahan M. H., Dogan A., & Buturak S. V. (2018). Olfactory bulbus volume and olfactory sulcus depth in psychotic patients and patients with anxiety disorder/depression. European Archives of Oto-Rhino-Laryngology, 275(12), 3017-3024. doi: 10.1007/s00405-018-5187-x
[15]	Athanassi A., Doncel R. D., Bath K. G., & Mandairon N. (2021). Relationship between depression and olfactory sensory function: A review. Chemical Senses, 46(1), 1-12.
[16]	Bianconi S., Poretti M. B., Rodríguez P., Maestri G., Rodríguez P. E., de Barioglio S. R., .... Carlini V. P. (2021). Ghrelin restores memory impairment following olfactory bulbectomy in mice by activating hippocampal NMDA1 and MAPK1 gene expression. Behavioural Brain Research, 410(7), 113341-113351. doi: 10.1016/j.bbr.2021.113341 URL
[17]	Billot M., Daycard M., Wood C., & Tchalla A. (2019). Reiki therapy for pain, anxiety and quality of life. BMJ Supportive and Palliative Care, 9(4), 434-438. doi: 10.1136/bmjspcare-2019-001775 pmid: 30948444
[18]	Birte-Antina W., Ilona C., Antje H., & Thomas H. (2018). Olfactory training with older people. International Journal of Geriatric Psychiatry, 33(1), 212-220. doi: 10.1002/gps.4725 pmid: 28429377
[19]	Bischmann D. A., & Witte K. L. (1996). Food identification, taste complaints, and depression in younger and older adults. Experimental Aging Research, 22(1), 23-32. pmid: 8665985
[20]	Brody B. L., Gamst A. C., Williams R. A., Smith A. R., Lau P. W., Dolnak D., .... Brown S. I. (2001). Depression, visual acuity, comorbidity, and disability associated with age-related macular degeneration. Ophthalmology, 108(10), 1893-1901. doi: 10.1016/s0161-6420(01)00754-0 pmid: 11581068
[21]	Canbeyli R. (2010). Sensorimotor modulation of mood and depression: an integrative review. Behavioural Brain Research, 207(2), 249-264. doi: 10.1016/j.bbr.2009.11.002 pmid: 19913058
[22]	Canbeyli R. (2022). Sensory stimulation via the visual, auditory, olfactory and gustatory systems can modulate mood and depression. The European Journal of Neuroscience, 55(1), 244-263. doi: 10.1111/ejn.v55.1 URL
[23]	Case L. K., Laubacher C. M., Olausson H., Wang B., Spagnolo P. A., & Bushnell M. C. (2016). Encoding of touch intensity but not pleasantness in human primary somatosensory cortex. The Journal of Neuroscience, 36(21), 5850-5860. doi: 10.1523/JNEUROSCI.1130-15.2016 URL
[24]	Cho C., Chan C., & Martin L. J. (2021). Can male mice develop preference towards gentle stroking by an experimenter? Neuroscience, 464(6), 26-32. doi: 10.1016/j.neuroscience.2020.12.017 URL
[25]	Clémence-Fau M., Schwan R., Angioi-Duprez K., Laprévote V., & Schwitzer T. (2021). Retinal structural changes in mood disorders: The optical coherence tomography to better understand physiopathology? Progress in Neuro- Psychopharmacology and Biological Psychiatry, 108(6), 110080.
[26]	Clepce M., Gossler A., Reich K., Kornhuber J., & Thuerauf N. (2010). The relation between depression, anhedonia and olfactory hedonic estimates—A pilot study in major depression. Neuroscience Letters, 471(3), 139-143. doi: 10.1016/j.neulet.2010.01.027 URL
[27]	Cochrane N. (1990). Physical contact experience and depression. Acta psychiatrica Scandinavica. Supplementum, 82(357), 1-91. doi: 10.1111/acp.1990.82.issue-s361 URL
[28]	Demirbağ B., & Erci B. (2012). The effects of sleep and touch therapy on symptoms of fibromyalgia and depression. Iranian Journal of Public Health, 41(11), 44-53. pmid: 23304675
[29]	Dichter G. S., Smoski M. J., Kampov-Polevoy A. B., Gallop R., & Garbutt J. C. (2010). Unipolar depression does not moderate responses to the Sweet Taste Test. Depression and Anxiety, 27(9), 859-863. doi: 10.1002/da.20690 pmid: 20336799
[30]	Dong X., & Ng N. (2021). Contribution of multiple pathways to the relationship between visual impairment and depression: Explaining mental health inequalities among older Chinese adults. Journal of Affective Disorders, 278(1), 350-356. doi: 10.1016/j.jad.2020.09.068 URL
[31]	Dong Y., Zhou Y., Chu X., Chen S., Chen L., Yang B., .... Li W. (2016). Dental noise exposed mice display depressive-like phenotypes. Molecular Brain, 9(1), 50.
[32]	Doty R. L., Popova V., Wylie C., Fedgchin M., Daly E., Janik A., .... Drevets W. C. (2021). Effect of esketamine nasal spray on olfactory function and nasal tolerability in patients with treatment-resistant depression: Results from four multicenter, randomized, double-Blind, placebo-controlled, phase III studies. CNS Drugs, 35(7), 781-794. doi: 10.1007/s40263-021-00826-9 pmid: 34235612
[33]	Dreyzehner J., & Goldberg K. A. (2019). Depression in deaf and hard of hearing youth. Child and Adolescent Psychiatric Clinics of North America, 28(3), 411-419. doi: S1056-4993(19)30032-X pmid: 31076117
[34]	Dudine L., Canaletti C., Giudici F., Lunardelli A., Abram G., Santini I., .... Negro C. (2021). Investigation on the loss of taste and smell and consequent psychological effects: A cross-sectional study on healthcare workers who contracted the COVID-19 infection. Frontiers in Public Health, 9, 666442. doi: 10.3389/fpubh.2021.666442 URL
[35]	Dutta T. M., Josiah A. F., Cronin C. A., Wittenberg G. F., & Cole J. W. (2013). Altered taste and stroke: A case report and literature review. Topics in Stroke Rehabilitation, 20(1), 78-86.
[36]	Dyer N. L., Baldwin A. L., & Rand W. L. (2019). A large- scale effectiveness trial of reiki for physical and psychological health. The Journal of Alternative and Complementary Medicine, 25(12), 1156-1162. doi: 10.1089/acm.2019.0022 URL
[37]	Eliyan Y., Wroblewski K. E., Mcclintock M. K., & Pinto J. M. (2021). Olfactory dysfunction predicts the development of depression in older US adults. Chemical Senses, 46(1), 1-8.
[38]	Esquiva G., & Hannibal J. (2019). Melanopsin-expressing retinal ganglion cells in aging and disease. Histology and Histopathology, 34(12), 1299-1311. doi: 10.14670/HH-18-138 pmid: 31219170
[39]	Field T. (2002). Violence and touch deprivation in adolescents. Adolescence, 37(148), 735-749. pmid: 12564826
[40]	Field T., Diego M., Hernandez-Reif M., Medina L., Delgado J., & Hernandez A. (2012). Yoga and massage therapy reduce prenatal depression and prematurity. Journal of Bodywork and Movement Therapies, 16(2), 204-209. doi: 10.1016/j.jbmt.2011.08.002 pmid: 22464118
[41]	Flores-Gutiérrez E., Cabrera-Muñoz E. A., Vega-Rivera N. M., Ortiz-López L., & Ramírez-Rodríguez G. B. (2018). Exposure to patterned auditory stimuli during acute stress prevents despair-like behavior in adult mice that were previously housed in an enriched environment in combination with auditory stimuli. Journal of Neural Transplantation and Plasticity, 2018, 8205245.
[42]	Giloyan A., Harutyunyan T., & Petrosyan V. (2015). Visual impairment and depression among socially vulnerable older adults in Armenia. Aging and Mental Health, 19(2), 175-181. doi: 10.1080/13607863.2014.920298 pmid: 24898137
[43]	Glezer I., & Malnic B. (2019). Olfactory receptor function. Handbook of Clinical Neurology, 164, 67-78.
[44]	Gomaa M. A., Elmagd M. H., Elbadry M. M., & Kader R. M. (2014). Depression, anxiety and stress scale in patients with tinnitus and hearing loss. European Archives of Oto-Rhino-Laryngology, 271(8), 2177-2184. doi: 10.1007/s00405-013-2715-6 URL
[45]	Grant A., Aubin M. J., Buhrmann R., Kergoat M. J., & Freeman E. E. (2021). Visual Impairment, eye disease, and the 3-year incidence of depressive symptoms: The canadian longitudinal study on aging. Ophthalmic Epidemiology, 28(1), 77-85. doi: 10.1080/09286586.2020.1823425 URL
[46]	Gu M., Li X., Yan L., Zhang Y., Yang L., Li S., & Song C. (2021). Endogenous ω-3 fatty acids in Fat-1 mice attenuated depression-like behaviors, spatial memory impairment and relevant changes induced by olfactory bulbectomy. Prostaglandins, Leukotrienes and Essential Fatty Acids, 171(8), 102313.
[47]	Guo Z. P., Sörös P., Zhang Z. Q., Yang M. H., Liao D., & Liu C. H. (2021). Use of transcutaneous auricular vagus nerve stimulation as an adjuvant therapy for the depressive symptoms of COVID-19: A literature review. Frontiers in Psychiatry, 12, 765106. doi: 10.3389/fpsyt.2021.765106 URL
[48]	Hahad O., Prochaska J. H., Daiber A., & Muenzel T. (2019). Environmental noise-induced effects on stress hormones, oxidative stress, and vascular dysfunction: Key factors in the relationship between cerebrocardiovascular and psychological disorders. Oxidative Medicine and Cellular Longevity, 2019, 4623109.
[49]	Han P., Georgi M., Cuevas M., Haehner A., Gudziol V., & Hummel T. (2018). Decreased electrogustometric taste sensitivity in patients with acquired olfactory dysfunction. Rhinology, 56(2), 158-165. doi: 10.4193/Rhin17.186 pmid: 29306960
[50]	Hansen N. V., Jørgensen T., & Ørtenblad L. (2006). Massage and touch for dementia. Cochrane Database of Systematic Reviews, 4), 1-18.
[51]	Heath T. P., Melichar J. K., Nutt D. J., & Donaldson L. F. (2006). Human taste thresholds are modulated by serotonin and noradrenaline. The Journal of Neuroscience, 26(49), 12664-12671. doi: 10.1523/JNEUROSCI.3459-06.2006 URL
[52]	Hellweg R., Zueger M., Fink K., Hörtnagl H., & Gass P. (2007). Olfactory bulbectomy in mice leads to increased BDNF levels and decreased serotonin turnover in depression-related brain areas. Neurobiology of Disease, 25(1), 1-7. pmid: 16990008
[53]	Holló G., Sándor N. G., Kóthy P., & Géczy A. (2021). Influence of painless one-eye blindness on depression, anxiety and quality of life in glaucoma patients with a normal fellow eye. BMC Ophthalmology, 21(1), 89.
[54]	Huang L., Xi Y., Peng Y., Yang Y., Huang X., Fu Y., .... Ren C. (2019). A visual circuit related to habenula underlies the antidepressive effects of light therapy. Neuron, 102(1), 128-142. doi: S0896-6273(19)30064-9 pmid: 30795900
[55]	Hur K., Choi J. S., Zheng M., Shen J., & Wrobel B. (2018). Association of alterations in smell and taste with depression in older adults. Laryngoscope Investigative Otolaryngology, 3(2), 94-99. doi: 10.1002/lio2.142 pmid: 29721540
[56]	Jafari Z., Kolb B. E., & Mohajerani M. H. (2019). Age-related hearing loss and tinnitus, dementia risk, and auditory amplification outcomes. Ageing Research Reviews, 56, 100963. doi: 10.1016/j.arr.2019.100963 URL
[57]	Jayakody D. M. P., Almeida O. P., Speelman C. P., Bennett R. J., Moyle T. C., Yiannos J. M., & Friedland P. L. (2018). Association between speech and high-frequency hearing loss and depression, anxiety and stress in older adults. Maturitas, 110(4), 86-91. doi: 10.1016/j.maturitas.2018.02.002 URL
[58]	Kalyanasundar B., Blonde G. D., Spector A. C., & Travers S. P. (2020). Electrophysiological responses to sugars and amino acids in the nucleus of the solitary tract of type 1 taste receptor double-knockout mice. Journal of Neurophysiology, 123(2), 843-859. doi: 10.1152/jn.00584.2019 pmid: 31913749
[59]	Kaptan S. K., Dursun B. O., Knowles M., Husain N., & Varese F. (2021). Group eye movement desensitization and reprocessing interventions in adults and children: A systematic review of randomized and nonrandomized trials. Clinical Psychology and Psychotherapy, 28(4), 784-806. doi: 10.1002/cpp.2549 pmid: 33415797
[60]	Kazour F., Richa S., Abi Char C., Surget A., Elhage W., & Atanasova B. (2020). Olfactory markers for depression: Differences between bipolar and unipolar patients. PLoS One, 15(8), e0237565.
[61]	Ketterer M. C., Häussler S. M., Hildenbrand T., Speck I., Peus D., Rosner B., .... Olze H. (2020). Binaural hearing rehabilitation improves speech perception, quality of Life, tinnitus distress, and psychological comorbidities. Otology and Neurotology, 41(5), 563-574. doi: 10.1097/MAO.0000000000002590 pmid: 32068692
[62]	Khalil R. B., Atallah E., Dirani E., Kallab M., Kassab A., Mourad M., & El Khoury R. (2020). Can atypical dysgeusia in depression be related to a deafferentation syndrome? Medical Hypotheses, 144, 110047. doi: 10.1016/j.mehy.2020.110047 URL
[63]	Kohli P., Soler Z. M., Nguyen,. S A., Muus J. S., & Schlosser R. J. (2016). The association between olfaction and depression: A systematic review. Chemical Senses, 41(6), 479-486. doi: 10.1093/chemse/bjw061 pmid: 27170667
[64]	Kopf D. (2021). Massage and touch-based therapy: Clinical evidence, neurobiology and applications in older patients with psychiatric symptoms. Zeitschrift für Gerontologie und Geriatrie, 54(8), 753-758. doi: 10.1007/s00391-021-01995-4
[65]	Kraus K. S., & Canlon B. (2012). Neuronal connectivity and interactions between the auditory and limbic systems. Effects of noise and tinnitus. Hearing Research, 288(1-2), 34-46. doi: 10.1016/j.heares.2012.02.009 pmid: 22440225
[66]	Kullakçi H., & Sonkaya A. R. (2021). The investigation of the effects of repetitive transcranialmagnetic stimulation treatment on taste and smell sensations in depressed patients. Noro-Psikiyatri Arsivi, 58(1), 26-33.
[67]	Lapierre Y. D., & Butter H. J. (1980). Agitated and retarded depression. A clinical psychophysiological evaluation. Neuropsychobiology, 6(4), 217-223. pmid: 7393432
[68]	Li Q., Becker B., Wernicke J., Chen Y., Zhang Y., Li R., .... Kendrick K. M. (2019). Foot massage evokes oxytocin release and activation of orbitofrontal cortex and superior temporal sulcus. Psychoneuroendocrinology, 101(3), 193-203. doi: 10.1016/j.psyneuen.2018.11.016 URL
[69]	Li S., Fong D., Wong J., Mcpherson B., Lau E., Huang L., & Ip M. (2021). Noise sensitivity associated with nonrestorative sleep in Chinese adults: A cross-sectional study. BMC Public Health, 21(1), 643.
[70]	Lindström S. H., Sundberg S. C., Larsson M., Andersson F. K., Broman J., & Granseth B. (2020). VGluT1 deficiency impairs visual attention and reduces the dynamic range of short-term plasticity at corticothalamic synapses. Cerebral Cortex, 30(3), 1813-1829. doi: 10.1093/cercor/bhz204 URL
[71]	Liu B., Qiao L., Liu K., Liu J., Piccinni-Ash T. J., & Chen Z. F. (2022). Molecular and neural basis of pleasant touch sensation. Science, 376(6592), 483-491. doi: 10.1126/science.abn2479 pmid: 35482870
[72]	Liu C. H., Yang M. H., Zhang G. Z., Wang X. X., Li B., Li M., .... Wang L. (2020). Neural networks and the anti-inflammatory effect of transcutaneous auricular vagus nerve stimulation in depression. Journal of Neuroinflammation, 17(1), 54.
[73]	Liu X., Zhou Y., Li S., Yang D., Jiao M., Liu X., & Wang Z. (2020). Type 3 adenylyl cyclase in the main olfactory epithelium participates in depression-like and anxiety-like behaviours. Journal of Affective Disorders, 268(5), 28-38. doi: 10.1016/j.jad.2020.02.041 URL
[74]	Liyue H., Chiang P. P., Sung S. C. & Tong L. (2016). Dry eye-related visual blurring and irritative symptoms and their association with depression and anxiety in eye clinic patients. Current Eye Research, 41(5), 590-599. doi: 10.3109/02713683.2015.1056804 pmid: 26337790
[75]	Lu J., Zhang Z., Yin X., Tang Y., Ji R., Chen H., .... Guo Z. V. (2022). An entorhinal-visual cortical circuit regulates depression-like behaviors. Molecular Psychiatry, Advance online publication. https://doi.org/10.1038/s41380-022-01540-8
[76]	Marinkov E. M. Z., Rancic N. K., Milisavljevic D. R., Stankovic M. D., Milosevic V. D., Malobabic M. M., .... Stojanovic J. D. (2022). Impact of sensorineural hearing loss during the pandemic of COVID-19 on the appearance of depressive symptoms, anxiety and stress. Medicina (Kaunas, Lithuania), 58(2), 233-240.
[77]	Marmamula S., Kumbham T. R., Modepalli S. B., Barrenkala N. R., Yellapragada R., & Shidhaye R. (2021). Depression, combined visual and hearing impairment (dual sensory impairment): a hidden multi-morbidity among the elderly in Residential Care in India. Scientific Reports, 11(1), 16189.
[78]	Mikhail C., Elgaaly K., Abd, E. L. A.E., Shaker O., & Ali S. (2021). Gustatory dysfunction among a sample of depressed egyptian adults under antidepressants therapy: A retrospective cohort study. International Journal of Dentistry, 2021, 5543840.
[79]	Miller S. M., & Naylor G. J. (1989). Unpleasant taste--a neglected symptom in depression. Journal of Affective Disorders, 17(3), 291-293. pmid: 2529299
[80]	Miranda M. I. (2012). Taste and odor recognition memory: The emotional flavor of life. Reviews in the Neurosciences, 23(5-6), 481-499. pmid: 23072843
[81]	Molander P., Hesser H., Weineland S., Bergwall K., Buck S., Hansson-Malmlof J., .... Andersson G. (2015). Internet- based acceptance and commitment therapy for psychological distress experienced by people with hearing problems: Study protocol for a randomized controlled trial. American Journal of Audiology, 24(3), 307-310. pmid: 26649536
[82]	Morales-Medina J. C., Iannitti T., Freeman A., & Caldwell H. K. (2017). The olfactory bulbectomized rat as a model of depression: The hippocampal pathway. Behavioural Brain Research, 317(1), 562-575. doi: 10.1016/j.bbr.2016.09.029 URL
[83]	Moriguchi S., Inagaki R., Shimojo H., Sugimura Y., & Fukunaga K. (2020). Memantine improves depressive-like behaviors via Kir6.1 channel inhibition in olfactory bulbectomized mice. Neuroscience, 442(8), 264-273. doi: 10.1016/j.neuroscience.2020.06.002 URL
[84]	Morrison I., Björnsdotter M., & Olausson H. (2011). Vicarious responses to social touch in posterior insular cortex are tuned to pleasant caressing speeds. The Journal of Neuroscience, 31(26), 9554-9562. doi: 10.1523/JNEUROSCI.0397-11.2011 URL
[85]	Morrison I., Löken L. S., & Olausson H. (2010). The skin as a social organ. Experimental Brain Research, 204(3), 305-314. doi: 10.1007/s00221-009-2007-y pmid: 19771420
[86]	Mosher C. P., Zimmerman P. E., Fuglevand A. J., & Gothard K. M. (2016). Tactile stimulation of the face and the production of facial expressions activate neurons in the primate amygdala. eNeuro, 3(5), 1-9.
[87]	Nagai M., Matsumoto S., Endo J., Sakamoto R., & Wada M. (2015). Sweet taste threshold for sucrose inversely correlates with depression symptoms in female college students in the luteal phase. Physiology & Behavior, 141, 92-96. doi: 10.1016/j.physbeh.2015.01.003 URL
[88]	Nakatake Y., Furuie H., Ukezono M., Yamada M., Yoshizawa K., & Yamada M. (2020). Indirect exposure to socially defeated conspecifics using recorded video activates the HPA axis and reduces reward sensitivity in mice. Scientific Reports, 10(1), 16881-16890. doi: 10.1038/s41598-020-73988-z pmid: 33037312
[89]	Naudin M., El-Hage W., Gomes M., Gaillard P., Belzung C., & Atanasova B. (2012). State and trait olfactory markers of major depression. PLoS One, 7(10), e46938.
[90]	Noel C., & Dando R. (2015). The effect of emotional state on taste perception. Appetite, 95, 89-95. doi: 10.1016/j.appet.2015.06.003 pmid: 26122754
[91]	Noran N. H., Izzuna M. G., Bulgiba A. M., Mimiwati Z., & Ayu S. M. (2009). Severity of visual impairment and depression among elderly Malaysians. Asia-Pacific Journal of Public Health, 21(1), 43-50. doi: 10.1177/1010539508327353 pmid: 19124335
[92]	Okabe S., Yoshida M., Takayanagi Y., & Onaka T. (2015). Activation of hypothalamic oxytocin neurons following tactile stimuli in rats. Neuroscience Letters, 600(7), 22-27. doi: 10.1016/j.neulet.2015.05.055 URL
[93]	Pant U., Frishkopf M., Park T., Norris C. M., & Papathanassoglou E. (2022). A neurobiological framework for the therapeutic potential of music and sound interventions for post-traumatic stress symptoms in critical illness survivors. International Journal of Environmental Research and Public Health, 19(5), 3113-3131. doi: 10.3390/ijerph19053113 URL
[94]	Pawling R., Cannon P. R., Mcglone F. P., & Walker S. C. (2017). C-tactile afferent stimulating touch carries a positive affective value. PLoS One, 12(3), e0173457.
[95]	Paz S. H., Globe D. R., Wu J., Azen S. P., & Varma R. (2003). Relationship between self-reported depression and self-reported visual function in Latinos. Archives of Ophthalmology, 121(7), 1021-1027. doi: 10.1001/archopht.121.7.1021 URL
[96]	Pinto J. O., de Vieira M. B., Dores A. R., Peixoto B., Geraldo A., & Barbosa F. (2021). Narrative review of the multisensory integration tasks used with older adults: inclusion of multisensory integration tasks into neuropsychological assessment. Expert Review of Neurotherapeutics, 21(6), 657-674. doi: 10.1080/14737175.2021.1914592 URL
[97]	Proskurnina E. V., Sokolova S. V., & Portnova G. V. (2021). Touch-induced emotional comfort results in an increase in the salivary antioxidant potential: A correlational study. Psychophysiology, 58(9), e13854.
[98]	Qazi J. J., Wilson J. H., Payne S. C. & Mattos J. L. (2020). Association between smell, taste, and depression in nationally representative sample of older adults in the united states. American Journal of Rhinology & Allergy, 34(3), 369-374.
[99]	Rajkumar R., & Dawe G. S. (2018). OBscure but not OBsolete: Perturbations of the frontal cortex in common between rodent olfactory bulbectomy model and major depression. Journal of Chemical Neuroanatomy, 91(9), 63-100. doi: 10.1016/j.jchemneu.2018.04.001 URL
[100]	Ramachandran V. S., & Brang D. (2008). Tactile-emotion synesthesia. Neurocase, 14(5), 390-399. doi: 10.1080/13554790802363746 pmid: 18821168
[101]	Rantanen M., Hautala J., Loberg O., Nuorva J., Hietanen J. K., Nummenmaa L., & Astikainen P. (2021). Attentional bias towards interpersonal aggression in depression - an eye movement study. Scandinavian Journal of Psychology, 62(5), 639-647. doi: 10.1111/sjop.12735 pmid: 33956357
[102]	Ren G., Xue P., Wu B., Yang F., & Wu X. (2021). Intranasal treatment of lixisenatide attenuated emotional and olfactory symptoms via CREB-mediated adult neurogenesis in mouse depression model. Aging (Albany NY), 13(3), 3898-3908.
[103]	Rideaux R. (2020). Temporal dynamics of GABA and Glx in the visual cortex. eNeuro, 7(4), 1-11.
[104]	Rim T. H., Lee C. S., Lee S. C., Chung B., & Kim S. S. (2015). Influence of visual acuity on suicidal ideation, suicide attempts and depression in South Korea. British Journal of Ophthalmology, 99(8), 1112-1119. doi: 10.1136/bjophthalmol-2014-306518 URL
[105]	Rolls E. T. (2004). The functions of the orbitofrontal cortex. Brain and Cognition, 55(1), 11-29. doi: 10.1016/S0278-2626(03)00277-X pmid: 15134840
[106]	Rolls E. T. (2019). Taste and smell processing in the brain. Handbook of Clinical Neurology, 164, 97-118.
[107]	Rottstädt F., Han P., Weidner K., Schellong J., Wolff-Stephan S., Strauß T., .... Croy I. (2018). Reduced olfactory bulb volume in depression-A structural moderator analysis. Human Brain Mapping, 39(6), 2573-2582. doi: 10.1002/hbm.24024 pmid: 29493048
[108]	Shang C., Liu Z., Chen Z., Shi Y., Wang Q., Liu S., .... Cao P. (2015). A parvalbumin-positive excitatory visual pathway to trigger fear responses in mice. Science, 348(6242), 1472-1477. doi: 10.1126/science.aaa8694 URL
[109]	Shetty S. L. P., & Fogarty S. (2021). Massage during pregnancy and postpartum. Clinical Obstetrics and Gynecology, 64(3), 648-660. doi: 10.1097/GRF.0000000000000638 pmid: 34323238
[110]	Simmons W. K., Burrows K., Avery J. A., Kerr K. L., Bodurka J., Savage C. R. & Drevets W. C. (2016). Depression-related increases and decreases in appetite reveal dissociable patterns of aberrant activity in reward and interoceptive neurocircuitry. The American Journal of Psychiatry, 173(4), 418-428. doi: 10.1176/appi.ajp.2015.15020162 URL
[111]	Siopi E., Denizet M., Gabellec M. M., de Chaumont F., Olivo-Marin J. C., Guilloux J. P., .... Lazarini F. (2016). Anxiety- and depression-like states lead to pronounced olfactory deficits and impaired adult neurogenesis in mice. The Journal of Neuroscience, 36(2), 518-531. doi: 10.1523/JNEUROSCI.2817-15.2016 URL
[112]	Smith C. J., & Bilbo S. D. (2021). Sickness and the social brain: Love in the time of COVID. Frontiers in Psychiatry, 12(2), 633664.
[113]	Smith K. A., & Alt J. A. (2020). The relationship of chronic rhinosinusitis and depression. Current Opinion in Otolaryngology and Head and Neck Surgery, 28(1), 1-5. doi: 10.1097/MOO.0000000000000595 pmid: 31789926
[114]	Smith S. A., Trotter P. D., Mcglone F. P., & Walker S. C. (2021). Effects of acute tryptophan depletion on human taste perception. Chemical Senses, 46, bjaa078.
[115]	Song C., & Leonard B. E. (2005). The olfactory bulbectomised rat as a model of depression. Neuroscience and Biobehavioral Reviews, 29(4-5), 627-647. doi: 10.1016/j.neubiorev.2005.03.010 pmid: 15925697
[116]	Song X. M., Hu X. W., Li Z., Gao Y., Ju X., Liu D. Y., .... Northoff G. (2021). Reduction of higher-order occipital GABA and impaired visual perception in acute major depressive disorder. Molecular Psychiatry, 26(11), 6747-6755. doi: 10.1038/s41380-021-01090-5 pmid: 33863994
[117]	Swiecicki L., Scinska A., Bzinkowska D., Torbinski J., Sienkiewicz-Jarosz H., Samochowiec J., & Bienkowski P. (2015). Intensity and pleasantness of sucrose taste in patients with winter depression. Nutritional Neuroscience, 18(4), 186-191. doi: 10.1179/1476830514Y.0000000115 pmid: 24628084
[118]	Takahashi T., Nishikawa Y., Yücel M., Whittle S., Lorenzetti V., Walterfang M., .... Allen N. B. (2016). Olfactory sulcus morphology in patients with current and past major depression. Psychiatry Research Neuroimaging, 255, 60-65. doi: 10.1016/j.pscychresns.2016.07.008 URL
[119]	Takahata Y., Yoshimoto W., Kuwagaki E., Yamada Y., & Nagasawa K. (2022). Alteration of sweet taste receptor expression in circumvallate papillae of mice with decreased sweet taste preference induced by social defeat stress. The Journal of Nutritional Biochemistry, 107, 109055. doi: 10.1016/j.jnutbio.2022.109055 URL
[120]	Tao S., Liu L., Shi L., Li X., Shen P., Xun Q., .... Wang J. (2015). Spatial learning and memory deficits in young adult mice exposed to a brief intense noise at postnatal age. Journal of Otology, 10(1), 21-28. doi: 10.1016/j.joto.2015.07.001 pmid: 29937778
[121]	Thomas J., Al-Mesaabi W., Bahusain E., & Mutawa M. (2014). The relationship between taste sensitivity to phenylthiocarbamide and anhedonia. Psychiatry Research, 215(2), 444-447. doi: 10.1016/j.psychres.2013.11.026 pmid: 24355685
[122]	Tian Y., Dong J., & Shi D. (2020). Protection of DAergic neurons mediates treadmill running attenuated olfactory deficits and olfactory neurogenesis promotion in depression model. Biochemical and Biophysical Research Communications, 521(3), 725-731. doi: S0006-291X(19)32066-2 pmid: 31706577
[123]	Touj S., Gallino D., Chakravarty M. M., Bronchti G., & Piché M. (2021). Structural brain plasticity induced by early blindness. The European Journal of Neuroscience, 53(3), 778-795. doi: 10.1111/ejn.v53.3 URL
[124]	Veling W., Lestestuiver B., Jongma M., Hoenders H., & van Driel C. (2021). Virtual reality relaxation for patients with a psychiatric disorder: Crossover randomized controlled trial. Journal of Medical Internet Research, 23(1), e17233.
[125]	Vidal K. S., Suemoto C. K., Moreno A. B., Viana M. C., Lotufo P. A., Benseñor I. M., & Brunoni A. R. (2021). Association between posterior segment eye diseases, common mental disorders, and depression: Cross-sectional and longitudinal analyses of brazilian longitudinal study of adult health cohort. Journal of the Academy of Consultation-Liaison Psychiatry, 62(1), 70-78. doi: 10.1016/j.psym.2020.03.001 pmid: 32279886
[126]	Vieira G., Rodrigues B., da Cunha C., de Morais G. B., Ferreira L., & Ribeiro M. (2021). Depression and dry eye: A narrative review. Revista da Associacao Medica Brasileira, 67(3), 462-467. doi: 10.1590/1806-9282.20200888 pmid: 34468615
[127]	Walker S. C., Trotter P. D., Swaney W. T., Marshall A., & Mcglone F. P. (2017). C-tactile afferents: Cutaneous mediators of oxytocin release during affiliative tactile interactions? Neuropeptides, 64(8), 27-38. doi: 10.1016/j.npep.2017.01.001 URL
[128]	Wirz-Justice A., Skene D. J., & Münch M. (2021). The relevance of daylight for humans. Biochemical Pharmacology, 191, 114304-114307. doi: 10.1016/j.bcp.2020.114304 URL
[129]	Yin C. Y., Li L. D., Xu C., Du Z.-W., Wu J. M., Chen X., .... Zhou Q. G. (2021). A novel method for automatic pharmacological evaluation of sucrose preference change in depression mice. Pharmacological Research, 168(6), 105601.
[130]	Yoshida Y., Miyazaki M., Yajima Y., & Toyoda A. (2021). Subchronic and mild social defeat stress downregulates peripheral expression of sweet and umami taste receptors in male mice. Biochemical and Biophysical Research Communications, 579, 116-121. doi: 10.1016/j.bbrc.2021.09.063 pmid: 34597994
[131]	Yu H., Miao W., Ji E., Huang S., Jin S., Zhu X., .... Yu X. (2022). Social touch-like tactile stimulation activates a tachykinin 1-oxytocin pathway to promote social interactions. Neuron, 110(6), 1051-1067. doi: 10.1016/j.neuron.2021.12.022 URL
[132]	Zhang Z., Zhang H., Xie C. M., Zhang M., Shi Y., Song R., .... Northoff G. (2021). Task-related functional magnetic resonance imaging-based neuronavigation for the treatment of depression by individualized repetitive transcranial magnetic stimulation of the visual cortex. Science China Life Sciences, 64(1), 96-106. doi: 10.1007/s11427-020-1730-5
[133]	Zheng Y., Wu X., Lin X., & Lin H. (2017). The prevalence of depression and depressive symptoms among eye disease patients: A systematic review and meta-analysis. Scientific Reports, 7(1), 46453-46461. doi: 10.1038/srep46453 URL
[134]	Zweerings J., Zvyagintsev M., Turetsky B. I., Klasen M., König A. A., Roecher E., .... Mathiak K. (2019). Fronto-parietal and temporal brain dysfunction in depression: A fMRI investigation of auditory mismatch processing. Human Brain Mapping, 40(12), 3657-3668. doi: 10.1002/hbm.24623 pmid: 31081231