A self-organizing community of over 200 scientists from more than 100 institutions around the world came together online for a week this past April to explore the gap between basic science and the next-generation clinical advances sought for serious mental and neurological illnesses in humans.
Source Here: medicalxpress.com
Feast or Forage? Study Finds Circuit That Helps a Brain Decide
MIT neuroscientists have discovered the elegant architecture of a fundamental decision-making brain circuit that allows a C. elegans worm to either forage for food or stop to feast when it finds a source. Capable of integrating multiple streams of sensory information, the circuit employs just a few key neurons to sustain long-lasting behaviors and yet flexibly switch between them as environmental conditions warrant.
“For a foraging worm, the decision to roam or to dwell is one that will strongly impact its survival.” says study senior author Steven Flavell, the Lister Brothers Career Development Associate Professor in the Picower Institute for Learning and Memory and the Department of Brain and Cognitive Sciences at MIT. “We thought that studying how the brain controls this crucial decision-making process could uncover fundamental circuit elements that may be deployed in many animals’ brains.”
This approach of studying simple invertebrates to gain basic insights into how the brain functions has a long tradition in neuroscience, Flavell says. For example, studies of how a squid nerve propagates electrical impulses led to the key insight explaining how brain cells fire in virtually all animals.
Though the critical component of brain circuitry identified by Flavell and colleagues may seem simple now that it has been revealed, finding it was anything but easy. Lead author Ni Ji, a postdoc in Flavell’s lab, used several advanced technologies, including one of the lab’s own inventions, to figure it out. The results of her and her co-authors’ work appear in the journal eLife.
C. elegans is a popular model in neuroscience because it only has 302 neurons and the “wiring diagram,” or connectome, has been fully mapped. But even so, the very dense and overlapping interconnectedness among those neurons, plus their ability to signal each other via chemicals called neuromodulators, means that one can hardly just look at the connectome and discern how it switches between different states of behavior.
To identify functional circuitry amid this web of connections, Flavell’s lab developed a new microscope capable of tracking the worms as they move around, thereby constantly imaging the activity of neurons across the worm’s brain, as indicated by calcium-triggered flashes of light. Ji used the scope to focus on 10 interconnected neurons involved in foraging, tracking their patterns of neural activity associated with roaming or dwelling behaviors.
Ji and co-authors trained software that learned the patterns so well that just based on neural activity, it could predict the worm’s behavior with 95 percent accuracy. The analysis revealed a quartet of neurons whose activity was specifically associated with roaming. Another key pattern was that the transition from roaming around to stopping to dwell always followed activation of a neuron called NSM. Flavell’s lab previously showed that NSM can sense the presence of newly ingested food and emit a neuromodulator called serotonin to signal other neurons to slow the worm down to dwell in a nutritive area.
Having identified the activity patterns that changed as the worm switched states, Ji began manipulating neurons in the circuit to understand how they interact. To confirm NSM’s role as the trigger of the dwelling state, Ji engineered it to be artificially activated with a flash of light (a technique called optogenetics). When she flashed the light, it caused the worm to dwell by inhibiting the activity of the roaming-associated neurons. Further experiments showed that this inhibitory power depended on the roaming neurons having an inhibitory serotonin receptor, called MOD-1. If Ji genetically knocked out the MOD-1 receptor, NSM couldn’t inhibit the roaming behavior and quickly stopped trying for lack of feedback.
Similarly, Ji showed that when the worm was roaming, it was because the roaming quartet was using the neuromodulator PDF to inhibit the activity of NSM. Optogenetic activation of PDF-expressing neurons tamped down NSM activity, for instance.
In a normal worm, if the roaming quartet was active NSM was not, and vice versa. But when Ji genetically knocked out the circuit elements that underlie this mutual inhibition both the roaming quartet and NSM could be active at the same time, leaving the worm in a weird state of meandering around at about half of roaming speed.
Thus, via an ongoing battle of mutual inhibition, roaming is sustained by the quartet and dwelling is sustained by NSM, but that still begged the question: How does the worm decide to flip the switch? To find out, Ji and colleagues programmed a machine learning algorithm to discern which neurons might work upstream in the broader circuit to influence the serotonin and PDF tug of war. This approach identified a neuron called AIA, which is known for integrating sensory information about food odors. AIA’s activity co-varied with a couple of the roaming neurons during roaming, and with NSM when dwelling began.
In other words, upon becoming activated by the smell of food, AIA could use its input to drive either side of the mutual inhibitory circuit to switch behavior. Remembering that NSM can sense when the worm is actually eating, Ji and Flavell could deduce what AIA and NSM must be doing. If the worm smells food but is not eating, it needs to roam further to that food smell until it is. If the worm smells food and at the same time it begins eating, then it should continue to dwell there.
“To a foraging worm, food odors are an important, but ambiguous, sensory cue. AIA’s ability to detect food odors and to transmit that information to these different downstream circuits, dependent on other incoming cues, allows animals to contextualize the smell and make adaptive foraging decisions,” Flavell said. “If you are looking for circuit elements that could also be operating in bigger brains, this one stands out as a basic motif that might allow for context-dependent behaviors.”
In addition to Ji and Flavell, the paper’s other authors are Gurrein Madan, Guadalupe Fabre, Alyssa Dayan, Casey Baker, Talya Kramer, and Ijeoma Nwabudike.
Funding for the research came from the National Institutes of Health, the National Science Foundation, the JPB Foundation, the Brain and Behavior Research Foundation, NARSAD, the McKnight Foundation, and the Alfred P. Sloan Foundation.
Original Source: news.mit.edu
Generating a Realistic 3D World
While standing in a kitchen, you push some metal bowls across the counter into the sink with a clang, and drape a towel over the back of a chair. In another room, it sounds like some precariously stacked wooden blocks fell over, and there’s an epic toy car crash. These interactions with our environment are just some of what humans experience on a daily basis at home, but while this world may seem real, it isn’t.
A new study from researchers at MIT, the MIT-IBM Watson AI Lab, Harvard University, and Stanford University is enabling a rich virtual world, very much like stepping into “The Matrix.” Their platform, called ThreeDWorld (TDW), simulates high-fidelity audio and visual environments, both indoor and outdoor, and allows users, objects, and mobile agents to interact like they would in real life and according to the laws of physics. Object orientations, physical characteristics, and velocities are calculated and executed for fluids, soft bodies, and rigid objects as interactions occur, producing accurate collisions and impact sounds.
TDW is unique in that it is designed to be flexible and generalizable, generating synthetic photo-realistic scenes and audio rendering in real time, which can be compiled into audio-visual datasets, modified through interactions within the scene, and adapted for human and neural network learning and prediction tests. Different types of robotic agents and avatars can also be spawned within the controlled simulation to perform, say, task planning and execution. And using virtual reality (VR), human attention and play behavior within the space can provide real-world data, for example.
“We are trying to build a general-purpose simulation platform that mimics the interactive richness of the real world for a variety of AI applications,” says study lead author Chuang Gan, MIT-IBM Watson AI Lab research scientist.
Creating realistic virtual worlds with which to investigate human behaviors and train robots has been a dream of AI and cognitive science researchers. “Most of AI right now is based on supervised learning, which relies on huge datasets of human-annotated images or sounds,” says Josh McDermott, associate professor in the Department of Brain and Cognitive Sciences (BCS) and an MIT-IBM Watson AI Lab project lead. These descriptions are expensive to compile, creating a bottleneck for research. And for physical properties of objects, like mass, which isn’t always readily apparent to human observers, labels may not be available at all. A simulator like TDW skirts this problem by generating scenes where all the parameters and annotations are known. Many competing simulations were motivated by this concern but were designed for specific applications; through its flexibility, TDW is intended to enable many applications that are poorly suited to other platforms.
Another advantage of TDW, McDermott notes, is that it provides a controlled setting for understanding the learning process and facilitating the improvement of AI robots. Robotic systems, which rely on trial and error, can be taught in an environment where they cannot cause physical harm. In addition, “many of us are excited about the doors that these sorts of virtual worlds open for doing experiments on humans to understand human perception and cognition. There’s the possibility of creating these very rich sensory scenarios, where you still have total control and complete knowledge of what is happening in the environment.”
McDermott, Gan, and their colleagues are presenting this research at the conference on Neural Information Processing Systems (NeurIPS) in December.
Behind the framework
The work began as a collaboration between a group of MIT professors along with Stanford and IBM researchers, tethered by individual research interests into hearing, vision, cognition, and perceptual intelligence. TDW brought these together in one platform. “We were all interested in the idea of building a virtual world for the purpose of training AI systems that we could actually use as models of the brain,” says McDermott, who studies human and machine hearing. “So, we thought that this sort of environment, where you can have objects that will interact with each other and then render realistic sensory data from them, would be a valuable way to start to study that.”
To achieve this, the researchers built TDW on a video game platform called Unity3D Engine and committed to incorporating both visual and auditory data rendering without any animation. The simulation consists of two components: the build, which renders images, synthesizes audio, and runs physics simulations; and the controller, which is a Python-based interface where the user sends commands to the build. Researchers construct and populate a scene by pulling from an extensive 3D model library of objects, like furniture pieces, animals, and vehicles. These models respond accurately to lighting changes, and their material composition and orientation in the scene dictate their physical behaviors in the space. Dynamic lighting models accurately simulate scene illumination, causing shadows and dimming that correspond to the appropriate time of day and sun angle. The team has also created furnished virtual floor plans that researchers can fill with agents and avatars. To synthesize true-to-life audio, TDW uses generative models of impact sounds that are triggered by collisions or other object interactions within the simulation. TDW also simulates noise attenuation and reverberation in accordance with the geometry of the space and the objects in it.
Two physics engines in TDW power deformations and reactions between interacting objects — one for rigid bodies, and another for soft objects and fluids. TDW performs instantaneous calculations regarding mass, volume, and density, as well as any friction or other forces acting upon the materials. This allows machine learning models to learn about how objects with different physical properties would behave together.
Users, agents, and avatars can bring the scenes to life in several ways. A researcher could directly apply a force to an object through controller commands, which could literally set a virtual ball in motion. Avatars can be empowered to act or behave in a certain way within the space — e.g., with articulated limbs capable of performing task experiments. Lastly, VR head and handsets can allow users to interact with the virtual environment, potentially to generate human behavioral data that machine learning models could learn from.
Richer AI experiences
To trial and demonstrate TDW’s unique features, capabilities, and applications, the team ran a battery of tests comparing datasets generated by TDW and other virtual simulations. The team found that neural networks trained on scene image snapshots with randomly placed camera angles from TDW outperformed other simulations’ snapshots in image classification tests and neared that of systems trained on real-world images. The researchers also generated and trained a material classification model on audio clips of small objects dropping onto surfaces in TDW and asked it to identify the types of materials that were interacting. They found that TDW produced significant gains over its competitor. Additional object-drop testing with neural networks trained on TDW revealed that the combination of audio and vision together is the best way to identify the physical properties of objects, motivating further study of audio-visual integration.
TDW is proving particularly useful for designing and testing systems that understand how the physical events in a scene will evolve over time. This includes facilitating benchmarks of how well a model or algorithm makes physical predictions of, for instance, the stability of stacks of objects, or the motion of objects following a collision — humans learn many of these concepts as children, but many machines need to demonstrate this capacity to be useful in the real world. TDW has also enabled comparisons of human curiosity and prediction against those of machine agents designed to evaluate social interactions within different scenarios.
Gan points out that these applications are only the tip of the iceberg. By expanding the physical simulation capabilities of TDW to depict the real world more accurately, “we are trying to create new benchmarks to advance AI technologies, and to use these benchmarks to open up many new problems that until now have been difficult to study.”
The research team on the paper also includes MIT engineers Jeremy Schwartz and Seth Alter, who are instrumental to the operation of TDW; BCS professors James DiCarlo and Joshua Tenenbaum; graduate students Aidan Curtis and Martin Schrimpf; and former postdocs James Traer (now an assistant professor at the University of Iowa) and Jonas Kubilius PhD ‘08. Their colleagues are IBM director of the MIT-IBM Watson AI Lab David Cox; research software engineer Abhishek Bhandwalder; and research staff member Dan Gutfreund of IBM. Additional researchers co-authoring are Harvard University assistant professor Julian De Freitas; and from Stanford University, assistant professors Daniel L.K. Yamins (a TDW founder) and Nick Haber, postdoc Daniel M. Bear, and graduate students Megumi Sano, Kuno Kim, Elias Wang, Damian Mrowca, Kevin Feigelis, and Michael Lingelbach.
This research was supported by the MIT-IBM Watson AI Lab.
Original Post: news.mit.edu
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