空间导航中方向感的多模态信息整合认知神经机制

doi:10.3724/SP.J.1042.2026.1010

摘要/Abstract

摘要： 方向感是人类与动物进行空间导航的核心能力, 以往缺少对其多模态信息整合认知过程及其神经机制的探讨。文献梳理发现, 个体通过对视觉、前庭觉、本体觉等多模态信息的独立编码、最优整合以及与空间记忆的交互建立、维持和更新方向感, 前庭-视觉通路中多类编码空间信息的细胞通过动态协作为此提供神经基础。未来研究应系统考察方向感的多模态信息动态整合机制; 扩大信息整合范畴, 探讨听、嗅、触觉对方向感的贡献, 拓展其多模态信息整合模型; 构建方向感的神经计算模型, 为航空、驾驶等领域的导航和定向技术迭代提供参考; 探讨个体对方向感的空间言语表述机制, 优化人机导航协作的信息传递模式。

关键词: 方向感, 空间导航, 前庭系统, 压后皮质, 视觉皮层

Abstract: Sense of direction refers to an individual’s awareness of their own location and their ability to determine their orientation by relating the self to the surrounding environment (e.g., landmarks and boundaries). It is a fundamental capacity underlying spatial navigation in both humans and animals. Previous research has lacked systematic investigation into the cognitive processes and neural mechanisms involved when individuals establish, maintain, and update their sense of direction during spatial navigation. Building upon previous studies, this review proposes a multimodal information integration cognitive processing model of the sense of direction and provides a detailed examination of its underlying cognitive and neural mechanisms, offering cognitive theoretical support and corresponding neural foundations for sense-of-direction enhancement and spatial perception training in application scenarios that require precise spatial orientation, such as aviation, driving, and virtual reality.
Based on a synthesis of previous research, this review proposes both a multimodal information integration model of the sense of direction and a corresponding multimodal neural network model. Specifically, during spatial navigation, individuals establish, maintain, and update their sense of direction through independent encoding of multimodal information—such as visual cues and self-motion cues (vestibular and proprioceptive signals)—Bayesian optimal integration, and interactions with spatial memory. At the neural level, the vestibular system, a series of brainstem nuclei, a series of thalamic nuclei, the retrosplenial cortex, the postsubiculum, and the primary and higher-order visual cortices are activated during multimodal information integration. These nuclei and brain regions contain multiple types of spatially tuned cells, such as head direction cells, angular head velocity cells, and place cells. Through dynamic cooperation, these cells generate neural signals related to an individual’s directional representation. Specifically, early vestibular pathways generate self-motion signals through the encoding and integration of vestibular and proprioceptive information. At a subsequent stage, head direction cells generate head direction signals within ring attractor networks by integrating self-perceived motion signals with visual signals. These head direction signals are then extensively integrated with visual signals across multiple brain regions during ascending signal transmission along the vestibular-visual pathway, providing the cognitive and neural basis for the establishment, maintenance, and updating of the sense of direction. Overall, the establishment, maintenance, and updating of the sense of direction constitute a dynamic, multistage process of multimodal information integration, with the vestibular-visual pathway serving as its primary cognitive and neural foundation.
Future research should systematically examine the dynamic multimodal integration mechanisms underlying the sense of direction, particularly by investigating integration modes, integration stages, coupling characteristics, and interactions with memory processes. The scope of information integration should be further expanded, especially under visually restricted conditions, to explore the contributions of auditory, olfactory, and tactile information to the sense of direction, and to identify new patterns of brain activation, such as how the superior temporal gyrus, olfactory cortex, and somatosensory cortex are associated with activation within the multimodal information integration neural network for the sense of direction, thereby further refining the multimodal information integration cognitive processing model and its neural mechanisms. Alternatively, neural computational models of the sense of direction may be constructed, using modular modeling strategies to simulate integration mechanisms among different cell populations (e.g., head direction cells and angular head velocity cells) and brain regions, providing underlying algorithmic logic for the iteration of navigation and orientation technologies in aviation, driving, and virtual reality. In addition, future studies may investigate spatial language interaction mechanisms related to the sense of direction, particularly how individuals externalize multimodally integrated mental representations of the sense of direction into spatial language, and analyze their expression and reception processes in cooperative navigation, thereby optimizing spatial information transmission strategies in human-machine interaction and enhancing collaborative efficiency and navigational experience.

Key words: sense of direction, spatial navigation, vestibular system, retrosplenial cortex, visual cortex

张军恒, 黄雷, 李奎良, 王靖, 姬鸣. (2026). 空间导航中方向感的多模态信息整合认知神经机制. 心理科学进展 , 34(6), 1010-1034.

ZHANG Junheng, HUANG Lei, LI Kuiliang, WANG Jing, JI Ming. (2026). Cognitive and neural mechanisms of multimodal information integration underlying the sense of direction in spatial navigation. Advances in Psychological Science, 34(6), 1010-1034.

参考文献

[1] 郝鑫, 袁忠萍, 林淑婷, 沈婷. (2022). 边界促进空间导航的认知神经机制.心理科学进展, 30(7), 1496-1510.
[2] 黄雷, 张军恒, 姬鸣. (2025). 视觉线索受限环境导航中认知地图的动态加工机制.心理科学进展, 33(4), 673-690.
[3] 简尽涵, 张军恒, 晏碧华, 姬鸣. (2025). 空间语言交互在不同视角下的多线索影响机制.心理学报, 57(6), 1013-1040.
[4] 肖承丽, 隋雨檠, 肖苏衡, 周仁来.(2021). 空间交互研究新视角:多重社会因素的影响.心理科学进展, 29(5), 796-805.
[5] 许琴, 罗宇, 刘嘉. (2010). 方向感的加工机制及影响因素.心理科学进展, 18(8), 1208-1221.
[6] 张艳霞, 李晶. (2025). 逐向导航辅助对大尺度环境下空间记忆的影响及改进方法.心理科学进展, 33(1), 77-91.
[7] Ajabi Z., Keinath A. T., Wei X. X., & Brandon M. P. (2023). Population dynamics of head-direction neurons during drift and reorientation.Nature, 615(7954), 892-899.
[8] Alexander E., Cai L. T., Fuchs S., Hladnik T. C., Zhang Y., Subramanian V.,.. Cooper E. A. (2022). Optic flow in the natural habitats of zebrafish supports spatial biases in visual self-motion estimation.Current Biology, 32(23), 5008-5021.
[9] Alexander A. S., Carstensen L. C., Hinman J. R., Raudies F., Chapman G. W., & Hasselmo M. E. (2020). Egocentric boundary vector tuning of the retrosplenial cortex. Science Advances, 6(8), eaaz2322.
[10] Alexander A. S., Place R., Starrett M. J., Chrastil E. R., & Nitz D. A. (2023). Rethinking retrosplenial cortex: Perspectives and predictions.Neuron, 111(2), 150-175.
[11] Alexander A. S., Rangel L. M., Tingley D., & Nitz D. A. (2018). Neurophysiological signatures of temporal coordination between retrosplenial cortex and the hippocampal formation.Behavioral Neuroscience, 132(5), 453-468.
[12] Anastasiou C., Baumann O., & Yamamoto N. (2023). Does path integration contribute to human navigation in large-scale space?.Psychonomic Bulletin & Review, 30(3), 822-842.
[13] Angelaki, D. E., & Cullen, K. E. (2008). Vestibular system: The many facets of a multimodal sense.Annual Review of Neuroscience, 31(1), 125-150.
[14] Auger S. D., Zeidman P., & Maguire E. A. (2017). Efficacy of navigation may be influenced by retrosplenial cortex-mediated learning of landmark stability.Neuropsychologia, 104, 102-112.
[15] Balasubramaniam L., Doostmohammadi A., Saw T. B., Narayana G. H. N. S., Mueller R., Dang T.,.. Ladoux B. (2021). Investigating the nature of active forces in tissues reveals how contractile cells can form extensile monolayers.Nature Materials, 20(8), 1156-1166.
[16] Bassett, J. P., & Taube, J. S. (2001). Neural correlates for angular head velocity in the rat dorsal tegmental nucleus.Journal of Neuroscience, 21(15), 5740-5751.
[17] Bassett J. P., Tullman M. L., & Taube J. S. (2007). Lesions of the tegmentomammillary circuit in the head direction system disrupt the head direction signal in the anterior thalamus.Journal of Neuroscience, 27(28), 7564-7577.
[18] Beuth, F. (2019). Visual attention in primates and for machines: Neuronal mechanisms [Unpublished doctoral dissertation]. Technische Universität Chemnitz.
[19] Bécu M., Sheynikhovich D., Ramanoël S., Tatur G., Ozier-Lafontaine A., Authié C. N.,.. Arleo A. (2023). Landmark-based spatial navigation across the human lifespan.ELife, 12, e81318.
[20] Bergelt, J., & Hamker, F. H. (2019). Spatial updating of attention across eye movements: A neuro-computational approach.Journal of Vision, 19(7), 1-23.
[21] Berthoz A., Israël I., Georges-François P., Grasso R., & Tsuzuku T. (1995). Spatial memory of body linear displacement: What is being stored?. Science, 269(5220), 95-98.
[22] Bicanski, A., & Burgess, N. (2020). Neuronal vector coding in spatial cognition.Nature Reviews Neuroscience, 21(9), 453-470.
[23] Biju K., Wei E. X., Rebello E., Matthews J., He Q., McNamara T. P., & Agrawal Y. (2021). Performance in real world-and virtual reality-based spatial navigation tasks in patients with vestibular dysfunction.Otology & Neurotology, 42(10), e1524-e1531
[24] Bjerknes T. L., Langston R. F., Kruge I. U., Moser E. I., & Moser M. B. (2015). Coherence among head direction cells before eye opening in rat pups.Current Biology, 25(1), 103-108.
[25] Bohne P., Schwarz M. K., Herlitze S., & Mark M. D. (2019). A new projection from the deep cerebellar nuclei to the hippocampus via the ventrolateral and laterodorsal thalamus in mice.Frontiers in Neural Circuits, 13, 51.
[26] Bostelmann M., Ruggeri P., Rita Circelli A., Costanzo F., Menghini D., Vicari S.,.. Banta Lavenex P. (2020). Path integration and cognitive mapping capacities in Down and Williams syndromes.Frontiers in Psychology, 11, 571394.
[27] Bottini, R., & Doeller, C. F. (2020). Knowledge across reference frames: Cognitive maps and image spaces.Trends in Cognitive Sciences, 24(8), 606-619.
[28] Bouvier G., Senzai Y., & Scanziani M. (2020). Head movements control the activity of primary visual cortex in a luminance-dependent manner.Neuron, 108(3), 500-511.
[29] Brandt T., Schautzer F., Hamilton D. A., Brüning R., Markowitsch H. J., Kalla R.,.. Strupp M. (2005). Vestibular loss causes hippocampal atrophy and impaired spatial memory in humans.Brain, 128(11), 2732-2741.
[30] Brooks, J. X., & Cullen, K. E. (2014). Early vestibular processing does not discriminate active from passive self-motion if there is a discrepancy between predicted and actual proprioceptive feedback.Journal of Neurophysiology, 111(12), 2465-2478.
[31] Buckley M. G., Austen J. M., Myles L. A., Smith S., Ihssen N., Lew A. R., & McGregor A. (2021). The effects of spatial stability and cue type on spatial learning: Implications for theories of parallel memory systems.Cognition, 214, 104802.
[32] Burgess, N. (2008a). Spatial cognition and the brain.Annals of the New York Academy of Sciences, 1124(1), 77-97.
[33] Burgess, N. (2008b). Grid cells and theta as oscillatory interference: Theory and predictions.Hippocampus, 18(12), 1157-1174.
[34] Burkhardt M., Bergelt J., Gönner L., Dinkelbach H. Ü., Beuth F., Schwarz A.,.. Hamker F. H. (2023). A large-scale neurocomputational model of spatial cognition integrating memory with vision.Neural Networks, 167, 473-488.
[35] Butler W. N., Smith K. S., van der Meer, M. A., & Taube J. S. (2017). The head-direction signal plays a functional role as a neural compass during navigation.Current Biology, 27(9), 1259-1267.
[36] Calton J. L., Stackman R. W., Goodridge J. P., Archey W. B., Dudchenko P. A., & Taube J. S. (2003). Hippocampal place cell instability after lesions of the head direction cell network.Journal of Neuroscience, 23(30), 9719-9731.
[37] Chen A., DeAngelis G. C., & Angelaki D. E. (2011). Representation of vestibular and visual cues to self-motion in ventral intraparietal cortex.Journal of Neuroscience, 31(33), 12036-12052.
[38] Chen X., McNamara T. P., Kelly J. W., & Wolbers T. (2017). Cue combination in human spatial navigation.Cognitive Psychology, 95, 105-144.
[39] Chen X., Vieweg P., & Wolbers T. (2019). Computing distance information from landmarks and self-motion cues-Differential contributions of anterior-lateral vs. posterior-medial entorhinal cortex in humans.NeuroImage, 202, 116074.
[40] Chen X., Wei Z., & Wolbers T. (2022). Coexistence of Cue-specific and Cue-independent Spatial Representations for Landmarks and Self-motion Cues in Human Retrosplenial Cortex.BioRxiv, 2022-05.
[41] Chen, Y., & Mou, W. (2024). Path integration, rather than being suppressed, is used to update spatial views in familiar environments with constantly available landmarks.Cognition, 242, 105662.
[42] Chen, Y., & Mou, W. (2025). Disrupted orientation after path integration by absence of anticipated prevalent spatial views.Journal of Experimental Psychology: Learning, Memory, and Cognition. 51(9), 1412-1429.
[43] Cheng, K., & Newcombe, N. S. (2005). Is there a geometric module for spatial orientation? Squaring theory and evidence. Psychonomic Bulletin & Review, 12(1), 1-23.
[44] Cheng K., Shettleworth S. J., Huttenlocher J., & Rieser J. J. (2007). Bayesian integration of spatial information.Psychological Bulletin, 133(4), 625-637.
[45] Chiandetti, C., & Vallortigara, G. (2008). Spatial reorientation in large and small enclosures: Comparative and developmental perspectives.Cognitive Processing, 9(4), 229-238.
[46] Clark B. J., LaChance P. A., Winter S. S., Mehlman M. L., Butler W., LaCour A., & Taube J. S. (2024). Comparison of head direction cell firing characteristics across thalamo-parahippocampal circuitry.Hippocampus, 34(4), 168-196.
[47] Clark, B. J., & Taube, J. S. (2012). Vestibular and attractor network basis of the head direction cell signal in subcortical circuits.Frontiers in Neural Circuits, 6, 7.
[48] Crapse, T. B., & Sommer, M. A. (2008). Corollary discharge circuits in the primate brain.Current Opinion in Neurobiology, 18(6), 552-557.
[49] Cullen, K. E. (2011). The neural encoding of self-motion.Current Opinion in Neurobiology, 21(4), 587-595.
[50] Cullen, K. E. (2012). The vestibular system: Multimodal integration and encoding of self-motion for motor control.Trends in Neurosciences, 35(3), 185-196.
[51] Cullen, K. E., & Brooks, J. X. (2015). Neural correlates of sensory prediction errors in monkeys: Evidence for internal models of voluntary self-motion in the cerebellum.The Cerebellum, 14(1), 31-34.
[52] Cullen, K. E., & Taube, J. S. (2017). Our sense of direction: Progress, controversies and challenges.Nature Neuroscience, 20(11), 1465-1473.
[53] Dalton M. A., McCormick C., & Maguire E. A. (2019). Differences in functional connectivity along the anterior-posterior axis of human hippocampal subfields.NeuroImage, 192, 38-51.
[54] Doeller, C. F., & Burgess, N. (2008). Distinct error-correcting and incidental learning of location relative to landmarks and boundaries.Proceedings of the National Academy of Sciences of the United States of America, 105(15), 5909-5914.
[55] Dokka K., DeAngelis G. C., & Angelaki D. E. (2015). Multisensory integration of visual and vestibular signals improves heading discrimination in the presence of a moving object.Journal of Neuroscience, 35(40), 13599-13607.
[56] Dokka K., MacNeilage P. R., DeAngelis G. C., & Angelaki D. E. (2015). Multisensory self-motion compensation during object trajectory judgments.Cerebral Cortex, 25(3), 619-630.
[57] Du Y., Mou W., & Zhang L. (2020). Unidirectional influence of vision on locomotion in multimodal spatial representations acquired from navigation.Psychological Research, 84(5), 1284-1303.
[58] Easton, R. D., & Sholl, M. J. (1995). Object-array structure, frames of reference, and retrieval of spatial knowledge.Journal of Experimental Psychology: Learning, Memory, and Cognition, 21(2), 483-500.
[59] Ekstrom A. D., Kahana M. J., Caplan J. B., Fields T. A., Isham E. A., Newman E. L., & Fried I. (2003). Cellular networks underlying human spatial navigation.Nature, 425(6954), 184-188.
[60] El Mahmoudi N., Laurent C., Péricat D., Watabe I., Lapotre A., Jacob P. Y.,.. Sargolini F. (2023). Long-lasting spatial memory deficits and impaired hippocampal plasticity following unilateral vestibular loss.Progress in Neurobiology, 223, 102403.
[61] Elyoseph Z., Geisinger D., Zaltzman R., Hartman T. G., Gordon C. R., & Mintz M. (2023). The overarching effects of vestibular deficit: Imbalance, anxiety, and spatial disorientation.Journal of the Neurological Sciences, 451, 120723.
[62] Etienne, A. S., & Jeffery, K. J. (2004). Path integration in mammals.Hippocampus, 14(2), 180-192.
[63] Etienne A. S., Maurer R., Boulens V., Levy A., & Rowe T. (2004). Resetting the path integrator: A basic condition for route-based navigation.Journal of Experimental Biology, 207(9), 1491-1508.
[64] Fetsch C. R., Pouget A., DeAngelis G. C., & Angelaki D. E. (2012). Neural correlates of reliability-based cue weighting during multisensory integration.Nature Neuroscience, 15(1), 146-154.
[65] Flossmann, T., & Rochefort, N. L. (2021). Spatial navigation signals in rodent visual cortex.Current Opinion in Neurobiology, 67, 163-173.
[66] Friedman A., Ludvig E. A., Legge E. L. G., & Vuong Q., C. (2013). Bayesian combination of two-dimensional location estimates.Behavior Research, 45(1), 98-107.
[67] Frost B. E., Martin S. K., Cafalchio M., Islam M. N., Aggleton J. P., & O'Mara S. M. (2021). Anterior thalamic inputs are required for subiculum spatial coding, with associated consequences for hippocampal spatial memory.Journal of Neuroscience, 41(30), 6511-6525.
[68] Gallistel C. R.(1990). The organization of learning. The MIT Press..
[69] Gallistel, C. R., & Matzel, L. D. (2013). The neuroscience of learning: Beyond the Hebbian synapse.Annual Review of Psychology, 64(1), 169-200.
[70] Galloni A. R., Ye Z., & Rancz E. (2022). Dendritic domain-specific sampling of long-range axons shapes feedforward and feedback connectivity of L5 neurons.Journal of Neuroscience, 42(16), 3394-3405.
[71] Gammeri R., Léonard J., Toupet M., Hautefort C., Van Nechel C., Besnard S.,.. Lopez C. (2022). Navigation strategies in patients with vestibular loss tested in a virtual reality T-maze.Journal of Neurology, 269(8), 4333-4348.
[72] Gardner R. J., Hermansen E., Pachitariu M., Burak Y., Baas N. A., Dunn B. A.,.. Moser E. I. (2022). Toroidal topology of population activity in grid cells. Nature, 602(7895), 123-128.
[73] Georges-François P., Rolls E. T., & Robertson R. G. (1999). Spatial view cells in the primate hippocampus: Allocentric view not head direction or eye position or place.Cerebral Cortex, 9(3), 197-212.
[74] Gerb J., Brandt T., & Dieterich M. (2022). Different strategies in pointing tasks and their impact on clinical bedside tests of spatial orientation.Journal of Neurology, 269(11), 5738-5745.
[75] Gerb J., Brandt T., & Dieterich M. (2023). Different approaches to test orientation of self in space: Comparison of a 2D pen-and-paper test and a 3D real-world pointing task.Journal of Neurology, 270(2), 642-650.
[76] Gerlei K., Passlack J., Hawes I., Vandrey B., Stevens H., Papastathopoulos I., & Nolan M. F. (2020). Grid cells are modulated by local head direction.Nature Communications, 11(1), 4228.
[77] Giocomo L. M., Stensola T., Bonnevie T., Van Cauter T., Moser M. B., & Moser E. I. (2014). Topography of head direction cells in medial entorhinal cortex.Current Biology, 24(3), 252-262.
[78] Griffiths B. J., Schreiner T., Schaefer J. K., Vollmar C., Kaufmann E., Quach S.,.. Staudigl T. (2024). Electrophysiological signatures of veridical head direction in humans.Nature Human Behaviour, 8(7), 1334-1350.
[79] Gu Y., Angelaki D. E., & DeAngelis G. C. (2008). Neural correlates of multisensory cue integration in macaque MSTd.Nature Neuroscience, 11(10), 1201-1210.
[80] Guitchounts G., Masís J., Wolff S. B., & Cox D. (2020). Encoding of 3D head orienting movements in the primary visual cortex.Neuron, 108(3), 512-525.
[81] Hafting T., Fyhn M., Bonnevie T., Moser M. B., & Moser E. I. (2008). Hippocampus-independent phase precession in entorhinal grid cells.Nature, 453(7199), 1248-1252.
[82] Hafting T., Fyhn M., Molden S., Moser M. B., & Moser E. I. (2005). Microstructure of a spatial map in the entorhinal cortex.Nature, 436(7052), 801-806.
[83] Hamburger, K. (2020). Visual landmarks are exaggerated: A theoretical and empirical view on the meaning of landmarks in human wayfinding.KI-Künstliche Intelligenz, 34(4), 557-562.
[84] Hampton R. R., Hampstead B. M., & Murray E. A. (2004). Selective hippocampal damage in rhesus monkeys impairs spatial memory in an open-field test.Hippocampus, 14(7), 808-818.
[85] Han, X., & Becker, S. (2014). One spatial map or many? Spatial coding of connected environments.Journal of Experimental Psychology: Learning, Memory, and Cognition, 40(2), 511-531.
[86] Hardcastle K., Ganguli S., & Giocomo L. M. (2015). Environmental boundaries as an error correction mechanism for grid cells.Neuron, 86(3), 827-839.
[87] Harland B., Grieves R. M., Bett D., Stentiford R., Wood E. R., & Dudchenko P. A. (2017). Lesions of the head direction cell system increase hippocampal place field repetition.Current Biology, 27(17), 2706-2712.
[88] Harootonian S. K., Ekstrom A. D., & Wilson R. C. (2022). Combination and competition between path integration and landmark navigation in the estimation of heading direction.PLoS Computational Biology, 18(2), e1009222.
[89] Harris L. R., Jenkin M., & Zikovitz D. C. (2000). Visual and non-visual cues in the perception of linear self motion.Experimental Brain Research, 135(1), 12-21.
[90] Hartley, T., & Burgess, N. (2005). Complementary memory systems: Competition, cooperation and compensation.Trends in Neurosciences, 28(4), 169-170.
[91] Hashimoto, R., & Nakano, I. (2014). The card placing test: A new test for evaluating the function of the retrosplenial and posterior cingulate cortices.European Neurology, 72(1-2), 38-44.
[92] He, Q., & McNamara, T. P. (2018). Spatial updating strategy affects the reference frame in path integration.Psychological Bulletin & Review, 25(3), 1073-1079.
[93] Hirono N., Mori E., Ishii K., Ikejiri Y., Imamura T., Shimomura T.,.. Sasaki M. (1998). Hypofunction in the posterior cingulate gyrus correlates with disorientation for time and place in Alzheimer’s disease.Journal of Neurology, Neurosurgery & Psychiatry, 64(4), 552-554.
[94] Hsieh, L. T., & Ranganath, C. (2015). Cortical and subcortical contributions to sequence retrieval: Schematic coding of temporal context in the neocortical recollection network.Neuroimage, 121, 78-90.
[95] Huang Y., Zhang X., Tang J., Xia Y., Yang X., Zhang Y.,.. Liu Y. (2023). Vestibular cognition assessment system: Tablet-based computerized visuospatial abilities test battery.Frontiers in Psychology, 14, 1095777.
[96] Huffman, D. J., & Ekstrom, A. D. (2021). An important step toward understanding the role of body-based cues on human spatial memory for large-scale environments.Journal of Cognitive Neuroscience, 33(2), 167-179.
[97] Iggena D., Jeung S., Maier P. M., Ploner C. J., Gramann K., & Finke C. (2023). Multisensory input modulates memory-guided spatial navigation in humans. Communications Biology, 6(1), 1167.
[98] Jabbari Y., Kenney D. M., von Mohrenschildt M., & Shedden J. M. (2021). Vestibular cues improve landmark-based route navigation: A simulated driving study.Memory & Cognition, 49(8), 1633-1644.
[99] Jacob P. Y., Casali G., Spieser L., Page H., Overington D., & Jeffery K. (2017). An independent, landmark-dominated head-direction signal in dysgranular retrosplenial cortex.Nature Neuroscience, 20(2), 173-175.
[100] Jacobs J., Weidemann C. T., Miller J. F., Solway A., Burke J. F., Wei X. X.,.. Kahana M. J. (2013). Direct recordings of grid-like neuronal activity in human spatial navigation.Nature Neuroscience, 16(9), 1188-1190.
[101] Jacobs, L. F., & Schenk, F. (2003). Unpacking the cognitive map: The parallel map theory of hippocampal function.Psychological Review, 110(2), 285-315.
[102] Jacobs, R. A. (1999). Optimal integration of texture and motion cues to depth.Vision Research, 39(21), 3621-3629.
[103] Janzen, G., & van Turennout, M. (2004). Selective neural representation of objects relevant for navigation.Nature Neuroscience, 7(6), 673-677.
[104] Jeffery, K. J. (2024). The mosaic structure of the mammalian cognitive map.Learning & Behavior, 52(1), 19-34.
[105] Jeffery, K. J., & Burgess, N. (2006). A metric for the cognitive map: Found at last?.Trends in Cognitive Sciences, 10(1), 1-3.
[106] Kaboodvand N., Bäckman L., Nyberg L., & Salami A. (2018). The retrosplenial cortex: A memory gateway between the cortical default mode network and the medial temporal lobe.Human Brain Mapping, 39(5), 2020-2034.
[107] Kalia A. A., Schrater P. R., & Legge G. E. (2013). Combining path integration and remembered landmarks when navigating without vision.PLoS ONE, 8(9), e72170.
[108] Karim A. M., Rumalla K., King L. A., & Hullar T. E. (2018). The effect of spatial auditory landmarks on ambulation.Gait & Posture, 60, 171-174.
[109] Kay K., Chung J. E., Sosa M., Schor J. S., Karlsson M. P., Larkin M. C.,.. Frank L. M. (2020). Constant sub-second cycling between representations of possible futures in the hippocampus.Cell, 180(3), 552-567.
[110] Keller A. M., Taylor H. A., & Brunyé T. T. (2020). Uncertainty promotes information-seeking actions, but what information?.Cognitive Research: Principles and Implications, 5(1), 42.
[111] Keller, G. B., & Mrsic-Flogel, T. D. (2018). Predictive processing: A canonical cortical computation.Neuron, 100(2), 424-435.
[112] Keller G. B., Bonhoeffer T., & Hübener M. (2012). Sensorimotor mismatch signals in primary visual cortex of the behaving mouse.Neuron, 74(5), 809-815.
[113] Kelly J. W., Avraamides M. N., & Loomis J. M. (2007). Sensorimotor alignment effects in the learning environment and in novel environments.Journal of Experimental Psychology: Learning, Memory, and Cognition, 33(6), 1092-1107.
[114] Kelly, J. W., & McNamara, T. P. (2010). Reference frames during the acquisition and development of spatial memories.Cognition, 116(3), 409-420.
[115] Keshavarzi S., Bracey E. F., Faville R. A., Campagner D., Tyson A. L., Lenzi S. C.,.. Margrie T. W. (2021). The retrosplenial cortex combines internal and external cues to encode head velocity during navigation.BioRxiv, 2021-01.
[116] Keshavarzi S., Bracey E. F., Faville R. A., Campagner D., Tyson A. L., Lenzi S. C.,.. Margrie T. W. (2022). Multisensory coding of angular head velocity in the retrosplenial cortex.Neuron, 110(3), 532-543.
[117] Keshavarzi S., Velez-Fort M., & Margrie T. W. (2023). Cortical integration of vestibular and visual cues for navigation, visual processing, and perception.Annual Review of Neuroscience, 46(1), 301-320.
[118] Kessler F., Frankenstein J., & Rothkopf C. A. (2024). Human navigation strategies and their errors result from dynamic interactions of spatial uncertainties.Nature Communications, 15(1), 5677.
[119] Khona, M., & Fiete, I. R. (2022). Attractor and integrator networks in the brain.Nature Reviews Neuroscience, 23(12), 744-766.
[120] Knill, D. C., & Pouget, A. (2004). The Bayesian brain: The role of uncertainty in neural coding and computation.Trends in Neuroscience, 27(12), 712-719.
[121] Kozlowski, L. T., & Bryant, K. J. (1977). Sense of direction, spatial orientation, and cognitive maps.Journal of Experimental Psychology: Human Perception and Performance, 3(4), 590-598.
[122] Lavenex, P. B., & Lavenex, P. (2009). Spatial memory and the monkey hippocampus: Not all space is created equal.Hippocampus, 19(1), 8-19.
[123] Lee, S. A. (2017). The boundary-based view of spatial cognition: A synthesis.Current Opinion in Behavioral Sciences, 16, 58-65.
[124] Lei, X., & Mou, W. (2021). Updating self-location by self-motion and visual cues in familiar multiscale spaces.Journal of Experimental Psychology: Learning, Memory, and Cognition, 47(9), 1439-1452.
[125] Lei X., Mou W., & Zhang L. (2020). Developing global spatial representations through across-boundary navigation. Journal of Experimental Psychology: Learning, Memory, and Cognition, 46(1), 1-23.
[126] Leinweber M., Ward D. R., Sobczak J. M., Attinger A., & Keller G. B. (2017). A sensorimotor circuit in mouse cortex for visual flow predictions.Neuron, 95(6), 1420-1432.
[127] Lever C., Burton S., Jeewajee A., O'Keefe J., & Burgess N. (2009). Boundary vector cells in the subiculum of the hippocampal formation.Journal of Neuroscience, 29(31), 9771-9777.
[128] Lew, A. R. (2011). Looking beyond the boundaries: Time to put landmarks back on the cognitive map?.Psychological Bulletin, 137(3), 484-507.
[129] Lomi E., Mathiasen M. L., Cheng H. Y., Zhang N., Aggleton J. P., Mitchell A. S., & Jeffery K. J. (2021). Evidence for two distinct thalamocortical circuits in retrosplenial cortex.Neurobiology of Learning and Memory, 185, 107525.
[130] Long X., Wang X., Deng B., Shen R., Lv S. Q., & Zhang S. J. (2024). Intrinsic bipolar head-direction cells in the medial entorhinal cortex.Advanced Science, 11(40), 2401216.
[131] Long, X., & Zhang, S. J. (2021). A novel somatosensory spatial navigation system outside the hippocampal formation.Cell Research, 31(6), 649-663.
[132] Loomis J.M., Klatzky R.L., &Giudice N. A. (2013). Representing3-D space in working memory: Spatial images from vision, hearing, touch, and language. In S. Lacey & R. Lawson (Eds.), Multisensory imagery: Theory and applications(pp. 131-155). New York, NY: Springer.
[133] Lu R., Yu C., Li Z., Mou W., & Li Z. (2020). Set size effects in spatial updating are independent of the online/ offline updating strategy.Journal of Experimental Psychology: Human Perception and Performance, 46(9), 901-911.
[134] Ma, W. J. (2019). Bayesian decision models: A primer.Neuron, 104(1), 164-175.
[135] Madl T., Chen K., Montaldi D., & Trappl R. (2015). Computational cognitive models of spatial memory in navigation space: A review.Neural Networks, 65, 18-43.
[136] Marchette S. A., Vass L. K., Ryan J., & Epstein R. A. (2014). Anchoring the neural compass: Coding of local spatial reference frames in human medial parietal lobe.Nature Neuroscience, 17(11), 1598-1606.
[137] Marlinski, V., & McCrea, R. A. (2009). Self-motion signals in vestibular nuclei neurons projecting to the thalamus in the alert squirrel monkey.Journal of Neurophysiology, 101(4), 1730-1741.
[138] Martins D. M., Manda J. M., Goard M. J., & Parker P. R. (2024). Building egocentric models of local space from retinal input.Current Biology, 34(23), R1185-R1202.
[139] McNamara, T. P., & Chen, X. (2022). Bayesian decision theory and navigation.Psychonomic Bulletin & Review, 29(3), 721-752.
[140] Medendorp W. P., Goltz H. C., Vilis T., & Crawford J. D. (2003). Gaze-centered updating of visual space in human parietal cortex.Journal of Neuroscience, 23(15), 6209-6214.
[141] Medrea, I., & Cullen, K. E. (2013). Multisensory integration in early vestibular processing in mice: The encoding of passive vs. active motion.Journal of Neurophysiology, 110(12), 2704-2717.
[142] Mehta M. R., Barnes C. A., & McNaughton B. L. (1997). Experience-dependent, asymmetric expansion of hippocampal place fields.Proceedings of the National Academy of Sciences, 94(16), 8918-8921.
[143] Mesulam M. M., Nobre A. C., Kim Y. H., Parrish T. B., & Gitelman D. R. (2001). Heterogeneity of cingulate contributions to spatial attention.