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3. Neural manifolds for odor-driven innate and acquired appetitive preferences.

Author

Chandak, Rishabh and Raman, Baranidharan

Subjects
ODORS, ASSOCIATIVE learning, STIMULUS & response (Psychology), LOCUSTS
Abstract

Sensory stimuli evoke spiking neural responses that innately or after learning drive suitable behavioral outputs. How are these spiking activities intrinsically patterned to encode for innate preferences, and could the neural response organization impose constraints on learning? We examined this issue in the locust olfactory system. Using a diverse odor panel, we found that ensemble activities both during ('ON response') and after stimulus presentations ('OFF response') could be linearly mapped onto overall appetitive preference indices. Although diverse, ON and OFF response patterns generated by innately appetitive odorants (higher palp-opening responses) were still limited to a low-dimensional subspace (a 'neural manifold'). Similarly, innately non-appetitive odorants evoked responses that were separable yet confined to another neural manifold. Notably, only odorants that evoked neural response excursions in the appetitive manifold could be associated with gustatory reward. In sum, these results provide insights into how encoding for innate preferences can also impact associative learning. It remains unclear how odorants with diverse appetitive preferences are encoded by an ensemble of neurons. Here, the authors show that such odorants can be succinctly described using low-dimensional neural representations or 'neural manifolds.' [ABSTRACT FROM AUTHOR]

Published
2023
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4. Crumpled graphene oxide for enhanced room temperature gas sensing: understanding the critical roles of surface morphology and functionalization.

Author

Haddad, Kelsey, Abokifa, Ahmed, An, Siyuan, Lee, Junseok, Raman, Baranidharan, Biswas, Pratim, and Fortner, John D.

Abstract

This work fundamentally explores graphene oxide morphology and functionality with regard to room temperature gas sensing performance. Highly-oxidized, crumpled graphene oxide (HO-CGO) was synthesized using a scalable, aerosol-based process. To minimize sample-to-sample synthesis variability, CGO and flat graphene oxide materials were thermally reduced allowing for a serial library of graphene oxide materials with comparable shape and surface chemistries. Room temperature sensitivity to ethanol was then systematically evaluated as a function of curing temperature, time (i.e., degree of thermal reduction), and morphology. HO-CGO showed the strongest response after one hour of reduction at a relatively mild temperature (220 °C), which removed most of the oxygen functionality. In contrast, flat graphene oxide sheets at the same C/O ratios showed no response. Density functional theory (DFT) and ab initio molecular dynamics (AIMD) simulations of ethanol interactions with these material surfaces were employed to develop a mechanistic understanding of the observed enhanced (CGO) sensing response. Adsorption energy calculations revealed that point defects have the most favorable adsorption energy for ethanol, followed by oxygen functionalities, and pristine graphene, respectively. In addition, AIMD on a simulated crumpled structure of graphene oxide indicate that ethanol molecules prefer to adsorb at/in the geometrical valleys of the CGO structure. Enhanced gas sensing performance of CGO is proposed to be a function of structural valleys, which act as both stable sites for oxygen defects and preferential binding sites for the ethanol molecules, whose adsorption occurs through physisorption, with a substantial contribution (∼50%) derived from dispersive forces. This work directly demonstrates the benefits of the crumpled structure of CGO, with concave morphological regions, compared to other carbon-based materials, and informs its processing and material incorporation into functional room temperature gas sensing devices. [ABSTRACT FROM AUTHOR]

Published
2023
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5. Invariant odor recognition with ON–OFF neural ensembles.

Author

Nizampatnam, Srinath, Lijun Zhang, Chandak, Rishabh, Li, James, and Raman, Baranidharan

Subjects
LOCUSTS, STIMULUS & response (Psychology), COMPUTATIONAL neuroscience
Abstract

Invariant stimulus recognition is a challenging pattern-recognition problem that must be dealt with by all sensory systems. Since neural responses evoked by a stimulus are perturbed in a multitude of ways, how can this computational capability be achieved? We examine this issue in the locust olfactory system. We find that locusts trained in an appetitive-conditioning assay robustly recognize the trained odorant independent of variations in stimulus durations, dynamics, or history, or changes in background and ambient conditions. However, individual- and populationlevel neural responses vary unpredictably with many of these variations. Our results indicate that linear statistical decoding schemes, which assign positive weights to ON neurons and negative weights to OFF neurons, resolve this apparent confound between neural variability and behavioral stability. Furthermore, simplification of the decoder using only ternary weights (f+1, 0, 21g) (i.e., an “ON-minus-OFF” approach) does not compromise performance, thereby striking a fine balance between simplicity and robustness. [ABSTRACT FROM AUTHOR]

Published
2022
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7. Neural Circuit Dynamics for Sensory Detection.

Author

Mallik, Sruti, Nizampatnam, Srinath, Nandi, Anirban, Saha, Debajit, Raman, Baranidharan, and ShiNung Ching

Subjects
NEURAL circuitry, FORECASTING, LOCUSTS, NEURONS
Abstract

We consider the question of how sensory networks enable the detection of sensory stimuli in a combinatorial coding space. We are specifically interested in the olfactory system, wherein recent experimental studies have reported the existence of rich, enigmatic response patterns associated with stimulus onset and offset. This study aims to identify the functional relevance of such response patterns (i.e., what benefits does such neural activity provide in the context of detecting stimuli in a natural environment). We study this problem through the lens of normative, optimization-based modeling. Here, we define the notion of a low-dimensional latent representation of stimulus identity, which is generated through action of the sensory network. The objective of our optimization framework is to ensure high-fidelity tracking of a nominal representation in this latent space in an energy-efficient manner. It turns out that the optimal motifs emerging from this framework possess morphologic similarity with prototypical onset and offset responses observed in vivo in locusts (Schistocerca americana) of either sex. Furthermore, this objective can be exactly achieved by a network with reciprocal excitatory-inhibitory competitive dynamics, similar to interactions between projection neurons and local neurons in the early olfactory system of insects. The derived model also makes several predictions regarding maintenance of robust latent representations in the presence of confounding background information and trade-offs between the energy of sensory activity and resultant behavioral measures such as speed and accuracy of stimulus detection. [ABSTRACT FROM AUTHOR]

Published
2020
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9. Differential effects of adaptation on odor discrimination.

Author

Haney, Seth, Saha, Debajit, Raman, Baranidharan, and Bazhenov, Maxim

Subjects
OLFACTORY receptors, BIOLOGICAL adaptation, LOCUST anatomy, SMELL, TEMPORAL databases, PHYSIOLOGY
Abstract

Adaptation of neural responses is ubiquitous in sensory systems and can potentially facilitate many important computational functions. Here we examined this issue with a well-constrained computational model of the early olfactory circuits. In the insect olfactory system, the responses of olfactory receptor neurons (ORNs) on the antennae adapt over time. We found that strong adaptation of sensory input is important for rapidly detecting a fresher stimulus encountered in the presence of other background cues and for faithfully representing its identity. However, when the overlapping odorants were chemically similar, we found that adaptation could alter the representation of these odorants to emphasize only distinguishing features. This work demonstrates novel roles for peripheral neurons during olfactory processing in complex environments. [ABSTRACT FROM AUTHOR]

Published
2018
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13. Odor Recognition vs. Classification in Artificial Olfaction.

Author

Raman, Baranidharan, Hertz, Joshua, Benkstein, Kurt, and Semancik, Steve

Subjects
ODORS, SMELL, PREDICTION models, CHEMICAL engineering, MOLECULAR dynamics, INFORMATION processing, CHEMICAL detectors
Abstract

Most studies in chemical sensing have focused on the problem of precise identification of chemical species that were exposed during the training phase (the recognition problem). However, generalization of training to predict the chemical composition of untrained gases based on their similarity with analytes in the training set (the classification problem) has received very limited attention. These two analytical tasks pose conflicting constraints on the system. While correct recognition requires detection of molecular features that are unique to an analyte, generalization to untrained chemicals requires detection of features that are common across a desired class of analytes. A simple solution that addresses both issues simultaneously can be obtained from biological olfaction, where the odor class and identity information are decoupled and extracted individually over time. Mimicking this approach, we proposed a hierarchical scheme that allowed initial discrimination between broad chemical classes (e.g. contains oxygen) followed by finer refinements using additional data into sub-classes (e.g. ketones vs. alcohols) and, eventually, specific compositions (e.g. ethanol vs. methanol) [1]. We validated this approach using an array of temperature-controlled chemiresistors. We demonstrated that a small set of training analytes is sufficient to allow generalization to novel chemicals and that the scheme provides robust categorization despite aging. Here, we provide further characterization of this approach. [ABSTRACT FROM AUTHOR]

Published
2011
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14. Relating Sensor Responses of Odorants to Their Organoleptic Properties by Means of a Biologically-Inspired Model of Receptor Neuron Convergence onto Olfactory Bulb.

Author

Raman, Baranidharan and Gutierrez-Osuna, Ricardo

Abstract

We present a neuromorphic approach to study the relationship between the response of a sensor/instrument to odorant molecules and the perceptual characteristics of the odors. Clearly, such correlations are only possible if the sensing instrument captures information about molecular properties (e.g., functional group, carbon chain-length) to which biological receptors have affinity. Given that information about some of these molecular features can be extracted from their infrared absorption spectra, an attractive candidate for this study is infrared (IR) spectroscopy. In our proposed model, high-dimensional IR absorption spectra of analytes are converted into compact, spatial odor maps using a feature clustering scheme that mimics the chemotopic convergence of receptor neurons onto the olfactory bulb. Cluster analysis of the generated IR odor maps reveals chemical groups with members that have similar perceptual characteristics e.g. fruits, nuts, etc. Further, the generated clusters match those obtained from a similar analysis of olfactory bulb odor maps obtained in rats for the same set of chemicals. Our results suggest that convergence mapping combined with IR absorption spectra may be an appropriate method to capture perceptual characteristics of certain classes of odorants. [ABSTRACT FROM AUTHOR]

Published
2009
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15. Multiscale photoacoustic tomography of neural activities with GCaMP calcium indicators.

Author

Zhang, Ruiying, Li, Lei S., Rao, Bin, Rong, Haoyang, Sun, Min-Yu, Yao, Junjie, Chen, Ruimin, Zhou, Qifa, Mennerick, Steven, Raman, Baranidharan, and Wang, Lihong V.

Subjects
PHOTOACOUSTIC effect, TOMOGRAPHY, OPTICAL limiting, CALCIUM, COMPUTED tomography, TRANSGENIC mice
Abstract

Significance: Optical imaging of responses in fluorescently labeled neurons has progressed significantly in recent years. However, there is still a need to monitor neural activities at divergent spatial scales and at depths beyond the optical diffusion limit. Aim: To meet these needs, we aim to develop multiscale photoacoustic tomography (PAT) to image neural activities across spatial scales with a genetically encoded calcium indicator GCaMP. Approach: First, using photoacoustic microscopy, we show that depth-resolved GCaMP signals can be monitored in vivo from a fly brain in response to odor stimulation without depth scanning and even with the cuticle intact. In vivo monitoring of GCaMP signals was also demonstrated in mouse brains. Next, using photoacoustic computed tomography, we imaged neural responses of a mouse brain slice at depths beyond the optical diffusion limit. Results: We provide the first unambiguous demonstration that multiscale PAT can be used to record neural activities in transgenic flies and mice with select neurons expressing GCaMP. Conclusions: Our results indicate that the combination of multiscale PAT and fluorescent neural activity indicators provides a methodology for imaging targeted neurons at various scales. [ABSTRACT FROM AUTHOR]

Published
2022
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16. Bioinspired Polarization Imaging Sensors: From Circuits and Optics to Signal Processing Algorithms and Biomedical Applications.

Author

York, Timothy, Powell, Samuel B., Gao, Shengkui, Kahan, Lindsey, Charanya, Tauseef, Saha, Debajit, Roberts, Nicholas W., Cronin, Thomas W., Marshall, Justin, Achilefu, Samuel, Lake, Spencer P., Raman, Baranidharan, and Gruev, Viktor

Subjects
CMOS image sensors, MEDICAL imaging systems, OPTICAL sensors, OPTICAL polarization, IMAGE sensors, IMAGING of cancer, BIOMIMICRY
Abstract

In this paper, we present recent work on bioinspired polarization imaging sensors and their applications in biomedicine. In particular, we focus on three different aspects of these sensors. First, we describe the electro–optical challenges in realizing a bioinspired polarization imager, and in particular, we provide a detailed description of a recent low-power complementary metal–oxide–semiconductor (CMOS) polarization imager. Second, we focus on signal processing algorithms tailored for this new class of bioinspired polarization imaging sensors, such as calibration and interpolation. Third, the emergence of these sensors has enabled rapid progress in characterizing polarization signals and environmental parameters in nature, as well as several biomedical areas, such as label-free optical neural recording, dynamic tissue strength analysis, and early diagnosis of flat cancerous lesions in a murine colorectal tumor model. We highlight results obtained from these three areas and discuss future applications for these sensors. [ABSTRACT FROM PUBLISHER]

Published
2014
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17. A spatiotemporal coding mechanism for background-invariant odor recognition.

Author

Saha, Debajit, Leong, Kevin, Li, Chao, Peterson, Steven, Siegel, Gregory, and Raman, Baranidharan

Subjects
SENSORY stimulation, SCHISTOCERCA americana, OLFACTORY receptors, LOCUSTS, NEURAL circuitry
Abstract

Sensory stimuli evoke neural activity that evolves over time. What features of these spatiotemporal responses allow the robust encoding of stimulus identity in a multistimulus environment? Here we examined this issue in the locust (Schistocerca americana) olfactory system. We found that sensory responses evoked by an odorant (foreground) varied when presented atop or after an ongoing stimulus (background). These inconsistent sensory inputs triggered dynamic reorganization of ensemble activity in the downstream antennal lobe. As a result, partial pattern matches between neural representations encoding the same foreground stimulus across conditions were achieved. The degree and segments of response overlaps varied; however, any overlap observed was sufficient to drive background-independent responses in the downstream neural population. Notably, recognition performance of locusts in behavioral assays correlated well with our physiological findings. Hence, our results reveal how background-independent recognition of odors can be achieved using spatiotemporal patterns of neural activity. [ABSTRACT FROM AUTHOR]

Published
2013
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18. Detecting and recognizing chemical targets in untrained backgrounds with temperature programmed sensors.

Author

Raman, Baranidharan, Shenoy, Rupa, Meier, Douglas C., Benkstein, Kurt D., Mungle, Casey, and Semancik, Steve

Abstract

Applications for artificial olfaction typically require analytical performance in the context of diverse backgrounds. Therefore, to deal with practical challenges posed by chemical species recognition in the presence of pre-trained and untrained backgrounds, a desirable feature is the ability to rapidly detect fresh analyte introductions (foreground odor) and segment their contributions from the foreground-background response cocktail. Here, we present a simple approach for this purpose based on the moving-window pair-wise correlation between sensor responses measured at multiple temperatures. We show that pairwise-correlation across isotherm segments can be used as a robust measure to rapidly detect chemical events (onset and offset), as well as to track and compensate for sensor baseline changes due to background variations. We demonstrate this approach for the problem of identifying three toxic industrial chemicals—ammonia, hydrogen cyanide, and chlorine—in several untrained backgrounds. Additionally, we show that the proposed scheme could be used to reduce baseline differences in response signatures between sensors of equivalent manufacture and thereby allow training and testing using different but comparable sensors. [ABSTRACT FROM PUBLISHER]

Published
2012
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19. Temporally Diverse Firing Patterns in Olfactory Receptor Neurons Underlie Spatiotemporal Neural Codes for Odors.

Author

Raman, Baranidharan, Joseph, Joby, Tang, Jeff, and Stopfer, Mark

Subjects
OLFACTORY receptors, NEURONS, MATHEMATICAL models, ELECTROPHYSIOLOGY, ODORS, RESEARCH methodology
Abstract

Odorants are represented as spatiotemporal patterns of spikes in neurons of the antennal lobe (AL; insects) and olfactory bulb (OB; vertebrates). These response patterns have been thought to arise primarily from interactions within the AL/OB, an idea supported, in part, by the assumption that olfactory receptor neurons (ORNs) respond to odorants with simple firing patterns. However, activating the AL directly with simple pulses of current evoked responses in AL neurons that were much less diverse, complex, and enduring than responses elicited by odorants. Similarly, models of the AL driven by simplistic inputs generated relatively simple output. How then are dynamic neural codes for odors generated? Consistent with recent results from several other species, our recordings from locust ORNs showed a great diversity of temporal structure. Furthermore,wefound that, viewed as a population,manyresponse features ofORNswere remarkably similar to those observed within the AL. Using a set of computational models constrained by our electrophysiological recordings, we found that the temporal heterogeneity of responses of ORNs critically underlies the generation of spatiotemporal odor codes in the AL. A test then performed in vivo confirmed that, given temporally homogeneous input, the AL cannot create diverse spatiotemporal patterns on its own; however, given temporally heterogeneous input, the AL generated realistic firing patterns. Finally, given the temporally structured input provided by ORNs, we clarified several separate, additional contributions of the AL to olfactory information processing. Thus, our results demonstrate the origin and subsequent reformatting of spatiotemporal neural codes for odors. [ABSTRACT FROM AUTHOR]

Published
2010
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22. Sparse odor representation and olfactory learning.

Author

Ito, Iori, Ong, Rose Chik-ying, Raman, Baranidharan, and Stopfer, Mark

Subjects
NEUROSCIENCES, OLFACTORY nerve, NEURAL circuitry, NEURONS, BRAIN, CEREBELLUM
Abstract

Sensory systems create neural representations of environmental stimuli and these representations can be associated with other stimuli through learning. Are spike patterns the neural representations that get directly associated with reinforcement during conditioning? In the moth Manduca sexta, we found that odor presentations that support associative conditioning elicited only one or two spikes on the odor's onset (and sometimes offset) in each of a small fraction of Kenyon cells. Using associative conditioning procedures that effectively induced learning and varying the timing of reinforcement relative to spiking in Kenyon cells, we found that odor-elicited spiking in these cells ended well before the reinforcement was delivered. Furthermore, increasing the temporal overlap between spiking in Kenyon cells and reinforcement presentation actually reduced the efficacy of learning. Thus, spikes in Kenyon cells do not constitute the odor representation that coincides with reinforcement, and Hebbian spike timing–dependent plasticity in Kenyon cells alone cannot underlie this learning. [ABSTRACT FROM AUTHOR]

Published
2008
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23. Processing of Chemical Sensor Arrays With a Biologically Inspired Model of Olfactory Coding.

Author

Raman, Baranidharan, Sun, Ping A., Gutierrez-Galvez, Agustin, and Gutierrez-Osuna, Ricardo

Subjects
MACHINERY, SMELL, CHEMICAL senses, SENSES, NEURAL receptors
Abstract

This paper presents a computational model for chemical sensor arrays inspired by the first two stages in the olfactory pathway: distributed coding with olfactory receptor neurons and chemotopic convergence onto glomerular units. We propose a monotonic concentration-response model that maps conventional sensor-array inputs into a distributed activation pattern across a large population of neuroreceptors. Projection onto glomerular units in the olfactory bulb is then simulated with a self-organizing model of chemotopic convergence. The pattern recognition performance of the model is characterized using a database of odor patterns from an array of temperature modulated chemical sensors. The chemotopic code achieved by the proposed model is shown to improve the signal-to-noise ratio available at the sensor inputs while being consistent with results from neurobiology. [ABSTRACT FROM AUTHOR]

Published
2006
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24. Dynamic contrast enhancement and flexible odor codes.

Author

Nizampatnam, Srinath, Saha, Debajit, Chandak, Rishabh, and Raman, Baranidharan

Abstract

Sensory stimuli evoke spiking activities patterned across neurons and time that are hypothesized to encode information about their identity. Since the same stimulus can be encountered in a multitude of ways, how stable or flexible are these stimulus-evoked responses? Here we examine this issue in the locust olfactory system. In the antennal lobe, we find that both spatial and temporal features of odor-evoked responses vary in a stimulus-history dependent manner. The response variations are not random, but allow the antennal lobe circuit to enhance the uniqueness of the current stimulus. Nevertheless, information about the odorant identity is confounded due to this contrast enhancement computation. Notably, predictions from a linear logical classifier (OR-of-ANDs) that can decode information distributed in flexible subsets of neurons match results from behavioral experiments. In sum, our results suggest that a trade-off between stability and flexibility in sensory coding can be achieved using a simple computational logic. Sensory stimuli are encountered in multiple ways necessitating a flexible and adaptive neural population code for identification. Here, the authors show that the dynamics of odor coding in the locust antennal lobe varies with stimulus context so as to enhance the target stimulus representation. [ABSTRACT FROM AUTHOR]

Published
2018
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25. Engaging and disengaging recurrent inhibition coincides with sensing and unsensing of a sensory stimulus.

Author

Saha, Debajit, Sun, Wensheng, Li, Chao, Nizampatnam, Srinath, Padovano, William, Chen, Zhengdao, Chen, Alex, Altan, Ege, Lo, Ray, Barbour, Dennis L., and Raman, Baranidharan

Abstract

Even simple sensory stimuli evoke neural responses that are dynamic and complex. Are the temporally patterned neural activities important for controlling the behavioral output? Here, we investigated this issue. Our results reveal that in the insect antennal lobe, due to circuit interactions, distinct neural ensembles are activated during and immediately following the termination of every odorant. Such non-overlapping response patterns are not observed even when the stimulus intensity or identities were changed. In addition, we find that ON and OFF ensemble neural activities differ in their ability to recruit recurrent inhibition, entrain field-potential oscillations and more importantly in their relevance to behaviour (initiate versus reset conditioned responses). Notably, we find that a strikingly similar strategy is also used for encoding sound onsets and offsets in the marmoset auditory cortex. In sum, our results suggest a general approach where recurrent inhibition is associated with stimulus 'recognition' and 'derecognition'. [ABSTRACT FROM AUTHOR]

Published
2017
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26. Non-invasive aerosol delivery and transport of gold nanoparticles to the brain.

Author

Raliya, Ramesh, Saha, Debajit, Chadha, Tandeep S., Raman, Baranidharan, and Biswas, Pratim

Abstract

Targeted delivery of nanoscale carriers containing packaged payloads to the central nervous system has potential use in many diagnostic and therapeutic applications. Moreover, understanding of the bio-interactions of the engineered nanoparticles used for tissue-specific delivery by non-invasive delivery approaches are also of paramount interest. Here, we have examined this issue systematically in a relatively simple invertebrate model using insects. We synthesized 5 nm, positively charged gold nanoparticles (AuNPs) and targeted their delivery using the electrospray aerosol generator. Our results revealed that after the exposure of synthesized aerosol to the insect antenna, AuNPs reached the brain within an hour. Nanoparticle accumulation in the brain increased linearly with the exposure time. Notably, electrophysiological recordings from neurons in the insect brain several hours after exposure did not show any significant alterations in their spontaneous and odor-evoked spiking properties. Taken together, our findings reveal that aerosolized delivery of nanoparticles can be an effective non-invasive approach for delivering nanoparticles to the brain, and also presents an approach to monitor the short-term nano-biointeractions. [ABSTRACT FROM AUTHOR]

Published
2017
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