Neural mechanisms to exploit positional geometry for collision avoidance

Mapping Intimacies ◽

10.1101/2021.12.11.472218 ◽

2021 ◽

Author(s):

Ryosuke Tanaka ◽

Damon A. Clark

Keyword(s):

Collision Avoidance ◽

Visual Motion ◽

Neural Circuit ◽

Spatial Information ◽

Three Dimensional ◽

Spatial Vision ◽

Geometrical Constraints ◽

Three Dimensional Configuration ◽

Motion Detectors ◽

Visual Neuron

Visual motion provides rich geometrical cues about the three-dimensional configuration the world. However, how brains decode the spatial information carried by motion signals remains poorly understood. Here, we study a collision avoidance behavior in Drosophila as a simple model of motion-based spatial vision. With simulations and psychophysics, we demonstrate that walking Drosophila exhibit a pattern of slowing to avoid collisions by exploiting the geometry of positional changes of objects on near-collision courses. This behavior requires the visual neuron LPLC1, whose tuning mirrors the behavior and whose activity drives slowing. LPLC1 pools inputs from object- and motion-detectors, and spatially biased inhibition tunes it to the geometry of collisions. Connectomic analyses identified circuitry downstream of LPLC1 that faithfully inherits its response properties. Overall, our results reveal how a small neural circuit solves a specific spatial vision task by combining distinct visual features to exploit universal geometrical constraints of the visual world.

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A Bio-inspired Collision Avoidance Model Based on Spatial Information Derived from Motion Detectors Leads to Common Routes

PLoS Computational Biology ◽

10.1371/journal.pcbi.1004339 ◽

2015 ◽

Vol 11 (11) ◽

pp. e1004339 ◽

Cited By ~ 20

Author(s):

Olivier J. N. Bertrand ◽

Jens P. Lindemann ◽

Martin Egelhaaf

Keyword(s):

Collision Avoidance ◽

Spatial Information ◽

Model Based ◽

Motion Detectors

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Human brain regions responsive to visual motion stimuli: determination by magnetoencephalography and three dimensional MRI

Neuroscience Research ◽

10.1016/s0168-0102(00)81117-7 ◽

2000 ◽

Vol 38 ◽

pp. S45

Author(s):

M Bundo

Keyword(s):

Human Brain ◽

Visual Motion ◽

Three Dimensional ◽

Brain Regions

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Virtual Archaeology of Death and Burial: A Procedure for Integrating 3D Visualization and Analysis in Archaeothanatology

Open Archaeology ◽

10.1515/opar-2020-0152 ◽

2021 ◽

Vol 7 (1) ◽

pp. 540-555

Author(s):

Hayley L. Mickleburgh ◽

Liv Nilsson Stutz ◽

Harry Fokkens

Keyword(s):

Spatial Information ◽

3D Visualization ◽

Rapid Development ◽

Three Dimensional ◽

3D Models ◽

The Body ◽

Test Case ◽

Archaeology Of Death ◽

Human Burials ◽

3D Information

Abstract The reconstruction of past mortuary rituals and practices increasingly incorporates analysis of the taphonomic history of the grave and buried body, using the framework provided by archaeothanatology. Archaeothanatological analysis relies on interpretation of the three-dimensional (3D) relationship of bones within the grave and traditionally depends on elaborate written descriptions and two-dimensional (2D) images of the remains during excavation to capture this spatial information. With the rapid development of inexpensive 3D tools, digital replicas (3D models) are now commonly available to preserve 3D information on human burials during excavation. A procedure developed using a test case to enhance archaeothanatological analysis and improve post-excavation analysis of human burials is described. Beyond preservation of static spatial information, 3D visualization techniques can be used in archaeothanatology to reconstruct the spatial displacement of bones over time, from deposition of the body to excavation of the skeletonized remains. The purpose of the procedure is to produce 3D simulations to visualize and test archaeothanatological hypotheses, thereby augmenting traditional archaeothanatological analysis. We illustrate our approach with the reconstruction of mortuary practices and burial taphonomy of a Bell Beaker burial from the site of Oostwoud-Tuithoorn, West-Frisia, the Netherlands. This case study was selected as the test case because of its relatively complete context information. The test case shows the potential for application of the procedure to older 2D field documentation, even when the amount and detail of documentation is less than ideal.

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Improvement on Permeability of Cyclic Peptide/Peptidomimetic: Backbone N-Methylation as A Useful Tool

Marine Drugs ◽

10.3390/md19060311 ◽

2021 ◽

Vol 19 (6) ◽

pp. 311

Author(s):

Yang Li ◽

Wang Li ◽

Zhengshuang Xu

Keyword(s):

Cyclic Peptides ◽

Cyclic Peptide ◽

Three Dimensional ◽

Conformational Space ◽

Cell Permeability ◽

Relative Importance ◽

Intrinsic Properties ◽

Surface Areas ◽

Synthetic Methodologies ◽

Three Dimensional Configuration

Peptides have a three-dimensional configuration that can adopt particular conformations for binding to proteins, which are well suited to interact with larger contact surface areas on target proteins. However, low cell permeability is a major challenge in the development of peptide-related drugs. In recent years, backbone N-methylation has been a useful tool for manipulating the permeability of cyclic peptides/peptidomimetics. Backbone N-methylation permits the adjustment of molecule’s conformational space. Several pathways are involved in the drug absorption pathway; the relative importance of each N-methylation to total permeation is likely to differ with intrinsic properties of cyclic peptide/peptidomimetic. Recent studies on the permeability of cyclic peptides/peptidomimetics using the backbone N-methylation strategy and synthetic methodologies will be presented in this review.

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Navigating in a volumetric world: Metric encoding in the vertical axis of space

Behavioral and Brain Sciences ◽

10.1017/s0140525x13000344 ◽

2013 ◽

Vol 36 (5) ◽

pp. 546-547 ◽

Cited By ~ 2

Author(s):

Theresa Burt de Perera ◽

Robert Holbrook ◽

Victoria Davis ◽

Alex Kacelnik ◽

Tim Guilford

Keyword(s):

Spatial Information ◽

Dimensional Space ◽

Three Dimensional ◽

Vertical Component ◽

Vertical Axis ◽

Orthogonal Axis ◽

Experimental Protocols ◽

Three Dimensional Space ◽

The Way

AbstractAnimals navigate through three-dimensional environments, but we argue that the way they encode three-dimensional spatial information is shaped by how they use the vertical component of space. We agree with Jeffery et al. that the representation of three-dimensional space in vertebrates is probably bicoded (with separation of the plane of locomotion and its orthogonal axis), but we believe that their suggestion that the vertical axis is stored “contextually” (that is, not containing distance or direction metrics usable for novel computations) is unlikely, and as yet unsupported. We describe potential experimental protocols that could clarify these differences in opinion empirically.

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