Your search keyword '"Picower Institute for Learning and Memory"' showing total 2,017 results

1. Gamma entrainment using audiovisual stimuli alleviates chemobrain pathology and cognitive impairment induced by chemotherapy in mice

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Broad Institute of MIT and Harvard, Kim, TaeHyun, James, Benjamin T., Kahn, Martin C., Blanco-Duque, Cristina, Abdurrob, Fatema, Islam, Md Rezaul, Lavoie, Nicolas S., Kellis, Manolis, Tsai, Li-Huei, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Broad Institute of MIT and Harvard, Kim, TaeHyun, James, Benjamin T., Kahn, Martin C., Blanco-Duque, Cristina, Abdurrob, Fatema, Islam, Md Rezaul, Lavoie, Nicolas S., Kellis, Manolis, and Tsai, Li-Huei

Abstract

Patients with cancer undergoing chemotherapy frequently experience a neurological condition known as chemotherapy-related cognitive impairment, or “chemobrain,” which can persist for the remainder of their lives. Despite the growing prevalence of chemobrain, both its underlying mechanisms and treatment strategies remain poorly understood. Recent findings suggest that chemobrain shares several characteristics with neurodegenerative diseases, including chronic neuroinflammation, DNA damage, and synaptic loss. We investigated whether a noninvasive sensory stimulation treatment we term gamma entrainment using sensory stimuli (GENUS), which has been shown to alleviate aberrant immune and synaptic pathologies in mouse models of neurodegeneration, could also mitigate chemobrain phenotypes in mice administered a chemotherapeutic drug. When administered concurrently with the chemotherapeutic agent cisplatin, GENUS alleviated cisplatin-induced brain pathology, promoted oligodendrocyte survival, and improved cognitive function in a mouse model of chemobrain. These effects persisted for up to 105 days after GENUS treatment, suggesting the potential for long-lasting benefits. However, when administered to mice 90 days after chemotherapy, GENUS treatment only provided limited benefits, indicating that it was most effective when used to prevent the progression of chemobrain pathology. Furthermore, we demonstrated that the effects of GENUS in mice were not limited to cisplatin-induced chemobrain but also extended to methotrexate-induced chemobrain. Collectively, these findings suggest that GENUS may represent a versatile approach for treating chemobrain induced by different chemotherapy agents.

Published

2024

2. Tribute to Professor Takashi Yura

Author

Massachusetts Institute of Technology. Department of Biology, Picower Institute for Learning and Memory, Tonegawa, Susumu, Massachusetts Institute of Technology. Department of Biology, Picower Institute for Learning and Memory, and Tonegawa, Susumu

Published

2023

3. Harnessing cerebral organoids for Alzheimer's disease research

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Bubnys, Adele, Tsai, Li-Huei, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Bubnys, Adele, and Tsai, Li-Huei

Published

2023

4. Detection of neuronal OFF periods as low amplitude neural activity segments

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Harding, Christian D., Guillaumin, Mathilde C. C., Krone, Lukas B., Kahn, Martin C., Blanco-Duque, Cristina, Mikutta, Christian, Vyazovskiy, Vladyslav V., Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Harding, Christian D., Guillaumin, Mathilde C. C., Krone, Lukas B., Kahn, Martin C., Blanco-Duque, Cristina, Mikutta, Christian, and Vyazovskiy, Vladyslav V.

Abstract

Background During non-rapid eye movement sleep (NREM), alternating periods of synchronised high (ON period) and low (OFF period) neuronal activity are associated with high amplitude delta band (0.5–4 Hz) oscillations in neocortical electrophysiological signals termed slow waves. As this oscillation is dependent crucially on hyperpolarisation of cortical cells, there is an interest in understanding how neuronal silencing during OFF periods leads to the generation of slow waves and whether this relationship changes between cortical layers. A formal, widely adopted definition of OFF periods is absent, complicating their detection. Here, we grouped segments of high frequency neural activity containing spikes, recorded as multiunit activity from the neocortex of freely behaving mice, on the basis of amplitude and asked whether the population of low amplitude (LA) segments displayed the expected characteristics of OFF periods. Results Average LA segment length was comparable to previous reports for OFF periods but varied considerably, from as short as 8 ms to > 1 s. LA segments were longer and occurred more frequently in NREM but shorter LA segments also occurred in half of rapid eye movement sleep (REM) epochs and occasionally during wakefulness. LA segments in all states were associated with a local field potential (LFP) slow wave that increased in amplitude with LA segment duration. We found that LA segments > 50 ms displayed a homeostatic rebound in incidence following sleep deprivation whereas short LA segments (< 50 ms) did not. The temporal organisation of LA segments was more coherent between channels located at a similar cortical depth. Conclusion We corroborate previous studies showing neural activity signals contain uniquely identifiable periods of low amplitude with distinct characteristics from the surrounding signal known as OFF periods and attribute the new characteristics of vigilance-state-dependent duration and duration-dependent homeostatic res

Published

2023

5. Motility of Different Gastric Helicobacter spp.

Author

Massachusetts Institute of Technology. Department of Biological Engineering, Picower Institute for Learning and Memory, Bansil, Rama, Constantino, Maira A., Su-Arcaro, Clover, Liao, Wentian, Shen, Zeli, Fox, James G., Massachusetts Institute of Technology. Department of Biological Engineering, Picower Institute for Learning and Memory, Bansil, Rama, Constantino, Maira A., Su-Arcaro, Clover, Liao, Wentian, Shen, Zeli, and Fox, James G.

Abstract

Helicobacter spp., including the well-known human gastric pathogen H. pylori, can cause gastric diseases in humans and other mammals. They are Gram-negative bacteria that colonize the gastric epithelium and use their multiple flagella to move across the protective gastric mucus layer. The flagella of different Helicobacter spp. vary in their location and number. This review focuses on the swimming characteristics of different species with different flagellar architectures and cell shapes. All Helicobacter spp. use a run-reverse-reorient mechanism to swim in aqueous solutions, as well as in gastric mucin. Comparisons of different strains and mutants of H. pylori varying in cell shape and the number of flagella show that their swimming speed increases with an increasing number of flagella and is somewhat enhanced with a helical cell body shape. The swimming mechanism of H. suis, which has bipolar flagella, is more complex than that of unipolar H. pylori. H. suis exhibits multiple modes of flagellar orientation while swimming. The pH-dependent viscosity and gelation of gastric mucin significantly impact the motility of Helicobacter spp. In the absence of urea, these bacteria do not swim in mucin gel at pH < 4, even though their flagellar bundle rotates.

Published

2023

6. Efficient multi-scale representation of visual objects using a biologically plausible spike-latency code and winner-take-all inhibition

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Sanchez-Garcia, Melani, Chauhan, Tushar, Cottereau, Benoit R., Beyeler, Michael, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Sanchez-Garcia, Melani, Chauhan, Tushar, Cottereau, Benoit R., and Beyeler, Michael

Abstract

Deep neural networks have surpassed human performance in key visual challenges such as object recognition, but require a large amount of energy, computation, and memory. In contrast, spiking neural networks (SNNs) have the potential to improve both the efficiency and biological plausibility of object recognition systems. Here we present a SNN model that uses spike-latency coding and winner-take-all inhibition (WTA-I) to efficiently represent visual stimuli using multi-scale parallel processing. Mimicking neuronal response properties in early visual cortex, images were preprocessed with three different spatial frequency (SF) channels, before they were fed to a layer of spiking neurons whose synaptic weights were updated using spike-timing-dependent-plasticity. We investigate how the quality of the represented objects changes under different SF bands and WTA-I schemes. We demonstrate that a network of 200 spiking neurons tuned to three SFs can efficiently represent objects with as little as 15 spikes per neuron. Studying how core object recognition may be implemented using biologically plausible learning rules in SNNs may not only further our understanding of the brain, but also lead to novel and efficient artificial vision systems.

Published

2023

7. Revealing nanostructures in brain tissue via protein decrowding by iterative expansion microscopy

Author

Massachusetts Institute of Technology. Media Laboratory, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Koch Institute for Integrative Cancer Research at MIT, Howard Hughes Medical Institute, Program in Media Arts and Sciences (Massachusetts Institute of Technology), Sarkar, Deblina, Kang, Jinyoung, Wassie, Asmamaw T, Schroeder, Margaret E, Peng, Zhuyu, Tarr, Tyler B, Tang, Ai-Hui, Niederst, Emily D, Young, Jennie Z, Su, Hanquan, Park, Demian, Yin, Peng, Tsai, Li-Huei, Blanpied, Thomas A, Boyden, Edward S, Massachusetts Institute of Technology. Media Laboratory, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Koch Institute for Integrative Cancer Research at MIT, Howard Hughes Medical Institute, Program in Media Arts and Sciences (Massachusetts Institute of Technology), Sarkar, Deblina, Kang, Jinyoung, Wassie, Asmamaw T, Schroeder, Margaret E, Peng, Zhuyu, Tarr, Tyler B, Tang, Ai-Hui, Niederst, Emily D, Young, Jennie Z, Su, Hanquan, Park, Demian, Yin, Peng, Tsai, Li-Huei, Blanpied, Thomas A, and Boyden, Edward S

Abstract

Many crowded biomolecular structures in cells and tissues are inaccessible to labelling antibodies. To understand how proteins within these structures are arranged with nanoscale precision therefore requires that these structures be decrowded before labelling. Here we show that an iterative variant of expansion microscopy (the permeation of cells and tissues by a swellable hydrogel followed by isotropic hydrogel expansion, to allow for enhanced imaging resolution with ordinary microscopes) enables the imaging of nanostructures in expanded yet otherwise intact tissues at a resolution of about 20 nm. The method, which we named 'expansion revealing' and validated with DNA-probe-based super-resolution microscopy, involves gel-anchoring reagents and the embedding, expansion and re-embedding of the sample in homogeneous swellable hydrogels. Expansion revealing enabled us to use confocal microscopy to image the alignment of pre-synaptic calcium channels with post-synaptic scaffolding proteins in intact brain circuits, and to uncover periodic amyloid nanoclusters containing ion-channel proteins in brain tissue from a mouse model of Alzheimer's disease. Expansion revealing will enable the further discovery of previously unseen nanostructures within cells and tissues.

Published

2023

8. Unraveling the Intertwined Effect of pH on Helicobacter pylori Motility and the Microrheology of the Mucin-Based Medium It Swims in

Author

Massachusetts Institute of Technology. Department of Biological Engineering, Picower Institute for Learning and Memory, Su-Arcaro, Clover, Liao, Wentian, Bieniek, Katarzyna, Constantino, Maira A., Decker, Savannah M., Turner, Bradley S., Bansil, Rama, Massachusetts Institute of Technology. Department of Biological Engineering, Picower Institute for Learning and Memory, Su-Arcaro, Clover, Liao, Wentian, Bieniek, Katarzyna, Constantino, Maira A., Decker, Savannah M., Turner, Bradley S., and Bansil, Rama

Abstract

The gastric pathogen, Helicobacter pylori bacteria have to swim across a pH gradient from 2 to 7 in the mucus layer to colonize the gastric epithelium. Previous studies from our group have shown that porcine gastric mucin (PGM) gels at an acidic pH < 4, and H. pylori bacteria are unable to swim in the gel, although their flagella rotate. Changing pH impacts both the rheological properties of gastric mucin and also influences the proton (H+)-pumped flagellar motors of H. pylori as well as their anti-pH sensing receptors. To unravel these intertwined effects of acidic pH on both the viscoelastic properties of the mucin-based mucus as well as the flagellar motors and chemo-receptors of the bacterium, we compared the motility of H. pylori in PGM with that in Brucella broth (BB10) at different pH values using phase contrast microscopy to track the motion of the bacteria. The results show that the distribution of swimming speeds and other characteristics of the bacteria trajectories exhibit pH-dependent differences in both media. The swimming speed exhibits a peak at pH 4 in BB10, and a less pronounced peak at a higher pH of 5 in PGM. At all pH values, the bacteria swam faster and had a longer net displacement in BB10 compared to PGM. While the bacteria were stuck in PGM gels at pH < 4, they swam at these acidic pH values in BB10, although with reduced speed. Decreasing pH leads to a decreased fraction of motile bacteria, with a decreased contribution of the faster swimmers to the distributions of speeds and net displacement of trajectories. The body rotation rate is weakly dependent on pH in BB10, whereas in PGM bacteria that are immobilized in the low pH gel are capable of mechano-sensing and rotate faster. Bacteria can be stuck in the gel in various ways, including the flagella getting entangled in the fibers of the gel or the cell body being stuck to the gel. Our results show that in BB10, swimming is optimized at pH4, reflecting the

Published

2023

9. Thalamus sends information about arousal but not valence to the amygdala

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Leppla, Chris A., Keyes, Laurel R., Glober, Gordon, Matthews, Gillian A., Batra, Kanha, Jay, Maya, Feng, Yu, Chen, Hannah S., Mills, Fergil, Delahanty, Jeremy, Olson, Jacob M., Nieh, Edward H., Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Leppla, Chris A., Keyes, Laurel R., Glober, Gordon, Matthews, Gillian A., Batra, Kanha, Jay, Maya, Feng, Yu, Chen, Hannah S., Mills, Fergil, Delahanty, Jeremy, Olson, Jacob M., and Nieh, Edward H.

Abstract

Rationale The basolateral amygdala (BLA) and medial geniculate nucleus of the thalamus (MGN) have both been shown to be necessary for the formation of associative learning. While the role that the BLA plays in this process has long been emphasized, the MGN has been less well-studied and surrounded by debate regarding whether the relay of sensory information is active or passive. Objectives We seek to understand the role the MGN has within the thalamoamgydala circuit in the formation of associative learning. Methods Here, we use optogenetics and in vivo electrophysiological recordings to dissect the MGN-BLA circuit and explore the specific subpopulations for evidence of learning and synthesis of information that could impact downstream BLA encoding. We employ various machine learning techniques to investigate function within neural subpopulations. We introduce a novel method to investigate tonic changes across trial-by-trial structure, which offers an alternative approach to traditional trial-averaging techniques. Results We find that the MGN appears to encode arousal but not valence, unlike the BLA which encodes for both. We find that the MGN and the BLA appear to react differently to expected and unexpected outcomes; the BLA biased responses toward reward prediction error and the MGN focused on anticipated punishment. We uncover evidence of tonic changes by visualizing changes across trials during inter-trial intervals (baseline epochs) for a subset of cells. Conclusion We conclude that the MGN-BLA projector population acts as both filter and transferer of information by relaying information about the salience of cues to the amygdala, but these signals are not valence-specified.

Published

2022

10. Gamma frequency sensory stimulation in mild probable Alzheimer’s dementia patients: Results of feasibility and pilot studies

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, McGovern Institute for Brain Research at MIT, Harvard University--MIT Division of Health Sciences and Technology, Chan, Diane, Suk, Ho-Jun, Jackson, Brennan L, Milman, Noah P, Stark, Danielle, Klerman, Elizabeth B, Kitchener, Erin, Fernandez Avalos, Vanesa S, de Weck, Gabrielle, Banerjee, Arit, Beach, Sara D, Blanchard, Joel, Stearns, Colton, Boes, Aaron D, Uitermarkt, Brandt, Gander, Phillip, Howard, Matthew, Sternberg, Eliezer J, Nieto-Castanon, Alfonso, Anteraper, Sheeba, Whitfield-Gabrieli, Susan, Brown, Emery N, Boyden, Edward S, Dickerson, Bradford C, Tsai, Li-Huei, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, McGovern Institute for Brain Research at MIT, Harvard University--MIT Division of Health Sciences and Technology, Chan, Diane, Suk, Ho-Jun, Jackson, Brennan L, Milman, Noah P, Stark, Danielle, Klerman, Elizabeth B, Kitchener, Erin, Fernandez Avalos, Vanesa S, de Weck, Gabrielle, Banerjee, Arit, Beach, Sara D, Blanchard, Joel, Stearns, Colton, Boes, Aaron D, Uitermarkt, Brandt, Gander, Phillip, Howard, Matthew, Sternberg, Eliezer J, Nieto-Castanon, Alfonso, Anteraper, Sheeba, Whitfield-Gabrieli, Susan, Brown, Emery N, Boyden, Edward S, Dickerson, Bradford C, and Tsai, Li-Huei

Abstract

Non-invasive Gamma ENtrainment Using Sensory stimulation (GENUS) at 40Hz reduces Alzheimer’s disease (AD) pathology such as amyloid and tau levels, prevents cerebral atrophy, and improves behavioral testing performance in mouse models of AD. Here, we report data from (1) a Phase 1 feasibility study (NCT04042922, ClinicalTrials.gov) in cognitively normal volunteers (n = 25), patients with mild AD dementia (n = 16), and patients with epilepsy who underwent intracranial electrode monitoring (n = 2) to assess safety and feasibility of a single brief GENUS session to induce entrainment and (2) a single-blinded, randomized, placebo-controlled Phase 2A pilot study (NCT04055376) in patients with mild probable AD dementia (n = 15) to assess safety, compliance, entrainment, and exploratory clinical outcomes after chronic daily 40Hz sensory stimulation for 3 months. Our Phase 1 study showed that 40Hz GENUS was safe and effectively induced entrainment in both cortical regions and other cortical and subcortical structures such as the hippocampus, amygdala, insula, and gyrus rectus. Our Phase 2A study demonstrated that chronic daily 40Hz light and sound GENUS was well-tolerated and that compliance was equally high in both the control and active groups, with participants equally inaccurate in guessing their group assignments prior to unblinding. Electroencephalography recordings show that our 40Hz GENUS device safely and effectively induced 40Hz entrainment in participants with mild AD dementia. After 3 months of daily stimulation, the group receiving 40Hz stimulation showed (i) lesser ventricular dilation and hippocampal atrophy, (ii) increased functional connectivity in the default mode network as well as with the medial visual network, (iii) better performance on the face-name association delayed recall test, and (iv) improved measures of d

Published

2022

11. Three-dimensional chromatin organization in brain function and dysfunction

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Dileep, Vishnu, Tsai, Li-Huei, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Dileep, Vishnu, and Tsai, Li-Huei

Abstract

The three-dimensional (3D) organization of chromatin within the nucleus is now recognized as a bona fide epigenetic property influencing genome function, replication, and maintenance. In the recent years, several studies have revealed how 3D chromatin organization is associated with brain function and its emerging role in disorders of the brain. 3D chromatin organization plays a crucial role in the development of different cell types of the nervous system and some neuronal cell types have adapted unique modifications to this organization that deviates from all other cell types. In post-mitotic neurons, dynamic changes in chromatin interactions in response to neuronal activity underlie learning and memory formation. Finally, new evidence directly links 3D chromatin organization to several disorders of the brain. These recent findings position 3D chromatin organization as a fundamental regulatory mechanism poised to reveal the etiology of brain function and dysfunctions., National Institute of Health (Grant 1-R01-NS102730-01)

Published

2022

12. Layer and rhythm specificity for predictive routing

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Bastos, Andre M, Lundqvist, Lars Mikael, Waite, Ayan S, Kopell, Nancy, Miller, Earl K, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Bastos, Andre M, Lundqvist, Lars Mikael, Waite, Ayan S, Kopell, Nancy, and Miller, Earl K

Abstract

© 2020 National Academy of Sciences. All rights reserved. In predictive coding, experience generates predictions that attenuate the feeding forward of predicted stimuli while passing forward unpredicted "errors." Different models have suggested distinct cortical layers, and rhythms implement predictive coding. We recorded spikes and local field potentials from laminar electrodes in five cortical areas (visual area 4 [V4], lateral intraparietal [LIP], posterior parietal area 7A, frontal eye field [FEF], and prefrontal cortex [PFC]) while monkeys performed a task that modulated visual stimulus predictability. During predictable blocks, there was enhanced alpha (8 to 14 Hz) or beta (15 to 30 Hz) power in all areas during stimulus processing and prestimulus beta (15 to 30 Hz) functional connectivity in deep layers of PFC to the other areas. Unpredictable stimuli were associated with increases in spiking and in gamma-band (40 to 90 Hz) power/connectivity that fed forward up the cortical hierarchy via superficial-layer cortex. Power and spiking modulation by predictability was stimulus specific. Alpha/beta power in LIP, FEF, and PFC inhibited spiking in deep layers of V4. Area 7A uniquely showed increases in high-beta (∼22 to 28 Hz) power/connectivity to unpredictable stimuli. These results motivate a conceptual model, predictive routing. It suggests that predictive coding may be implemented via lower-frequency alpha/ beta rhythms that "prepare" pathways processing-predicted inputs by inhibiting feedforward gamma rhythms and associated spiking.

Published

2022

13. Design-development of an at-home modular brain–computer interface (BCI) platform in a case study of cervical spinal cord injury

Author

Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Davis, Kevin C., Meschede-Krasa, Benyamin, Cajigas, Iahn, Prins, Noeline W., Alver, Charles, Gallo, Sebastian, Bhatia, Shovan, Abel, John H., Naeem, Jasim A., Fisher, Letitia, Raza, Fouzia, Rifai, Wesley R., Morrison, Matthew, Ivan, Michael E., Brown, Emery N., Jagid, Jonathan R., Prasad, Abhishek, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Davis, Kevin C., Meschede-Krasa, Benyamin, Cajigas, Iahn, Prins, Noeline W., Alver, Charles, Gallo, Sebastian, Bhatia, Shovan, Abel, John H., Naeem, Jasim A., Fisher, Letitia, Raza, Fouzia, Rifai, Wesley R., Morrison, Matthew, Ivan, Michael E., Brown, Emery N., Jagid, Jonathan R., and Prasad, Abhishek

Abstract

Objective The objective of this study was to develop a portable and modular brain–computer interface (BCI) software platform independent of input and output devices. We implemented this platform in a case study of a subject with cervical spinal cord injury (C5 ASIA A). Background BCIs can restore independence for individuals with paralysis by using brain signals to control prosthetics or trigger functional electrical stimulation. Though several studies have successfully implemented this technology in the laboratory and the home, portability, device configuration, and caregiver setup remain challenges that limit deployment to the home environment. Portability is essential for transitioning BCI from the laboratory to the home. Methods The BCI platform implementation consisted of an Activa PC + S generator with two subdural four-contact electrodes implanted over the dominant left hand-arm region of the sensorimotor cortex, a minicomputer fixed to the back of the subject’s wheelchair, a custom mobile phone application, and a mechanical glove as the end effector. To quantify the performance for this at-home implementation of the BCI, we quantified system setup time at home, chronic (14-month) decoding accuracy, hardware and software profiling, and Bluetooth communication latency between the App and the minicomputer. We created a dataset of motor-imagery labeled signals to train a binary motor imagery classifier on a remote computer for online, at-home use. Results Average bluetooth data transmission delay between the minicomputer and mobile App was 23 ± 0.014 ms. The average setup time for the subject’s caregiver was 5.6 ± 0.83 min. The average times to acquire and decode neural signals and to send those decoded signals to the end-effector were respectively 404.1 ms and 1.02 ms. The 14-month median accuracy of the trained motor imagery classifier was 87.5 ± 4.71% without retraining. Conclusions The study presents the feasibility of an at-home BCI system that sub

Published

2022

14. The Immediate Early Gene Arc Is Not Required for Hippocampal Long-Term Potentiation

Author

Picower Institute for Learning and Memory, Kyrke-Smith, Madeleine, Volk, Lenora J., Cooke, Samuel F., Bear, Mark F., Huganir, Richard L., Shepherd, Jason D., Picower Institute for Learning and Memory, Kyrke-Smith, Madeleine, Volk, Lenora J., Cooke, Samuel F., Bear, Mark F., Huganir, Richard L., and Shepherd, Jason D.

Abstract

Memory consolidation is thought to occur through protein synthesis-dependent synaptic plasticity mechanisms such as long-term potentiation (LTP). Dynamic changes in gene expression and epigenetic modifications underlie the maintenance of LTP. Similar mechanisms may mediate the storage of memory. Key plasticity genes, such as the immediate early gene Arc, are induced by learning and by LTP induction. Mice that lack Arc have severe deficits in memory consolidation, and Arc has been implicated in numerous other forms of synaptic plasticity, including long-term depression and cell-to-cell signaling. Here, we take a comprehensive approach to determine if Arc is necessary for hippocampal LTP in male and female mice. Using a variety of Arc knock-out (KO) lines, we found that germline Arc KO mice show no deficits in CA1 LTP induced by high-frequency stimulation and enhanced LTP induced by theta-burst stimulation. Temporally restricting the removal of Arc to adult animals and spatially restricting it to the CA1 using Arc conditional KO mice did not have an effect on any form of LTP. Similarly, acute application of Arc antisense oligodeoxynucleotides had no effect on hippocampal CA1 LTP. Finally, the maintenance of in vivo LTP in the dentate gyrus of Arc KO mice was normal. We conclude that Arc is not necessary for hippocampal LTP and may mediate memory consolidation through alternative mechanisms.SIGNIFICANCE STATEMENT The immediate early gene Arc is critical for maintenance of long-term memory. How Arc mediates this process remains unclear, but it has been proposed to sustain Hebbian synaptic potentiation, which is a key component of memory encoding. This form of plasticity is modeled experimentally by induction of LTP, which increases Arc mRNA and protein expression. However, mechanistic data implicates Arc in the endocytosis of AMPA-type glutamate receptors and the weakening of synapses. Here, we took a comprehensive approach to determine if Arc is necessary for hippocamp

Published

2022

15. Eszopiclone and Zolpidem Produce Opposite Effects on Hippocampal Ripple Density

Author

Picower Institute for Learning and Memory, Center for Brains, Minds, and Machines, Becker, Logan A., Penagos, Hector L., Flores Plaza, Francisco Javier, Manoach, Dara S., Wilson, Matthew A., Varela, Carmen, Picower Institute for Learning and Memory, Center for Brains, Minds, and Machines, Becker, Logan A., Penagos, Hector L., Flores Plaza, Francisco Javier, Manoach, Dara S., Wilson, Matthew A., and Varela, Carmen

Abstract

Clinical populations have memory deficits linked to sleep oscillations that can potentially be treated with sleep medications. Eszopiclone and zolpidem (two non-benzodiazepine hypnotics) both enhance sleep spindles. Zolpidem improved sleep-dependent memory consolidation in humans, but eszopiclone did not. These divergent results may reflect that the two drugs have different effects on hippocampal ripple oscillations, which correspond to the reactivation of neuronal ensembles that represent previous waking activity and contribute to memory consolidation. We used extracellular recordings in the CA1 region of rats and systemic dosing of eszopiclone and zolpidem to test the hypothesis that these two drugs differentially affect hippocampal ripples and spike activity. We report evidence that eszopiclone makes ripples sparser, while zolpidem increases ripple density. In addition, eszopiclone led to a drastic decrease in spike firing, both in putative pyramidal cells and interneurons, while zolpidem did not substantially alter spiking. These results provide an explanation of the different effects of eszopiclone and zolpidem on memory in human studies and suggest that sleep medications can be used to regulate hippocampal ripple oscillations, which are causally linked to sleep-dependent memory consolidation.

Published

2022

16. A low-cost 3D printed microfluidic bioreactor and imaging chamber for live-organoid imaging

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Khan, Ikram, Prabhakar, Anil, Delepine, Chloe, Tsang, Hayley, Pham, Vincent, Sur, Mriganka, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Khan, Ikram, Prabhakar, Anil, Delepine, Chloe, Tsang, Hayley, Pham, Vincent, and Sur, Mriganka

Abstract

Organoids are biological systems grown in vitro and are observed to self-organize into 3D cellular tissues of specific organs. Brain organoids have emerged as valuable models for the study of human brain development in health and disease. Researchers are now in need of improved culturing and imaging tools to capture the in vitro dynamics of development processes in the brain. Here, we describe the design of a microfluidic chip and bioreactor, to enable in situ tracking and imaging of brain organoids on-chip. The low-cost 3D printed microfluidic bioreactor supports organoid growth and provides an optimal imaging chamber for live-organoid imaging, with drug delivery support. This fully isolated design of a live-cell imaging and culturing platform enables long-term live-imaging of the intact live brain organoids as it grows. We can thus analyze their self-organization in a controlled environment with high temporal and spatial resolution.

Published

2022

17. Spine Dynamics: Are They All the Same?

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Berry, Kalen Paul, Nedivi, Elly, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Biology, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Berry, Kalen Paul, and Nedivi, Elly

Abstract

© 2017 Elsevier Inc. Since Cajal's first drawings of Golgi stained neurons, generations of researchers have been fascinated by the small protrusions, termed spines, studding many neuronal dendrites. Most excitatory synapses in the mammalian CNS are located on dendritic spines, making spines convenient proxies for excitatory synaptic presence. When in vivo imaging revealed that dendritic spines are dynamic structures, their addition and elimination were interpreted as excitatory synapse gain and loss, respectively. Spine imaging has since become a popular assay for excitatory circuit remodeling. In this review, we re-evaluate the validity of using spine dynamics as a straightforward reflection of circuit rewiring. Recent studies tracking both spines and synaptic markers in vivo reveal that 20% of spines lack PSD-95 and are short lived. Although they account for most spine dynamics, their remodeling is unlikely to impact long-term network structure. We discuss distinct roles that spine dynamics can play in circuit remodeling depending on synaptic content. Dendritic spines are often viewed as proxies for glutamatergic synapses, and their addition or elimination as indicative of changes in circuit structure. In this review, Berry and Nedivi examine synaptic heterogeneity in the dendritic spine population and its implications for interpreting spine dynamics., NIH Pre-Doctoral Training Grant (T32GM007287), NIH grant (EY025437), NIH grant (EY011894)

Published

2022

18. Mechanisms of DNA damage‐mediated neurotoxicity in neurodegenerative disease

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Welch, Gwyneth, Tsai, Li‐Huei, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Welch, Gwyneth, and Tsai, Li‐Huei

Abstract

Neurons are highly susceptible to DNA damage accumulation due to their large energy requirements, elevated transcriptional activity, and long lifespan. While newer research has shown that DNA breaks and mutations may facilitate neuron diversity during development and neuronal function throughout life, a wealth of evidence indicates deficient DNA damage repair underlies many neurological disorders, especially age-associated neurodegenerative diseases. Recently, efforts to clarify the molecular link between DNA damage and neurodegeneration have improved our understanding of how the genomic location of DNA damage and defunct repair proteins impact neuron health. Additionally, work establishing a role for senescence in the aging and diseased brain reveals DNA damage may play a central role in neuroinflammation associated with neurodegenerative disease.

Published

2022

19. Brain‐wide mapping of inputs to the mouse lateral posterior (LP/Pulvinar) thalamus–anterior cingulate cortex network

Author

Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, McGovern Institute for Brain Research at MIT, Leow, Yi Ning, Zhou, Blake, Sullivan, Heather A, Barlowe, Alexandria R, Wickersham, Ian R, Sur, Mriganka, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, McGovern Institute for Brain Research at MIT, Leow, Yi Ning, Zhou, Blake, Sullivan, Heather A, Barlowe, Alexandria R, Wickersham, Ian R, and Sur, Mriganka

Abstract

The rodent homolog of the primate pulvinar, the lateral posterior (LP) thalamus, is extensively interconnected with multiple cortical areas. While these cortical interactions can span the entire LP, subdivisions of the LP are characterized by differential connections with specific cortical regions. In particular, the medial LP has reciprocal connections with frontoparietal cortical areas, including the anterior cingulate cortex (ACC). The ACC plays an integral role in top-down sensory processing and attentional regulation, likely exerting some of these functions via the LP. However, little is known about how ACC and LP interact, and about the information potentially integrated in this reciprocal network. Here, we address this gap by employing a projection-specific monosynaptic rabies tracing strategy to delineate brain-wide inputs to bottom-up LP→ACC and top-down ACC→LP neurons. We find that LP→ACC neurons receive inputs from widespread cortical regions, including primary and higher order sensory and motor cortical areas. LP→ACC neurons also receive extensive subcortical inputs, particularly from the intermediate and deep layers of the superior colliculus (SC). Sensory inputs to ACC→LP neurons largely arise from visual cortical areas. In addition, ACC→LP neurons integrate cross-hemispheric prefrontal cortex inputs as well as inputs from higher order medial cortex. Our brain-wide anatomical mapping of inputs to the reciprocal LP-ACC pathways provides a roadmap for understanding how LP and ACC communicate different sources of information to mediate attentional control and visuomotor functions.

Published

2022

20. Locus Coeruleus Norepinephrine in Learned Behavior: Anatomical Modularity and Spatiotemporal Integration in Targets

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Breton-Provencher, Vincent, Drummond, Gabrielle, Sur, Mriganka, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Breton-Provencher, Vincent, Drummond, Gabrielle, and Sur, Mriganka

Abstract

The locus coeruleus (LC), a small brainstem nucleus, is the primary source of the neuromodulator norepinephrine (NE) in the brain. The LC receives input from widespread brain regions, and projects throughout the forebrain, brainstem, cerebellum, and spinal cord. LC neurons release NE to control arousal, but also in the context of a variety of sensory-motor and behavioral functions. Despite its brain-wide effects, much about the role of LC-NE in behavior and the circuits controlling LC activity is unknown. New evidence suggests that the modular input-output organization of the LC could enable transient, task-specific modulation of distinct brain regions. Future work must further assess whether this spatial modularity coincides with functional differences in LC-NE subpopulations acting at specific times, and how such spatiotemporal specificity might influence learned behaviors. Here, we summarize the state of the field and present new ideas on the role of LC-NE in learned behaviors., NIH grant (R01EY028219), NIH grant (R01MH085802), NSERC (PDF-48724-2016)

Published

2022

21. Single-cell dissection of the human brain vasculature

Author

Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Garcia, Francisco J, Sun, Na, Lee, Hyeseung, Godlewski, Brianna, Mathys, Hansruedi, Galani, Kyriaki, Zhou, Blake, Jiang, Xueqiao, Ng, Ayesha P, Mantero, Julio, Tsai, Li-Huei, Bennett, David A, Sahin, Mustafa, Kellis, Manolis, Heiman, Myriam, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Computer Science and Artificial Intelligence Laboratory, Garcia, Francisco J, Sun, Na, Lee, Hyeseung, Godlewski, Brianna, Mathys, Hansruedi, Galani, Kyriaki, Zhou, Blake, Jiang, Xueqiao, Ng, Ayesha P, Mantero, Julio, Tsai, Li-Huei, Bennett, David A, Sahin, Mustafa, Kellis, Manolis, and Heiman, Myriam

Abstract

Despite the importance of the cerebrovasculature in maintaining normal brain physiology and in understanding neurodegeneration and drug delivery to the central nervous system1, human cerebrovascular cells remain poorly characterized owing to their sparsity and dispersion. Here we perform single-cell characterization of the human cerebrovasculature using both ex vivo fresh tissue experimental enrichment and post mortem in silico sorting of human cortical tissue samples. We capture 16,681 cerebrovascular nuclei across 11 subtypes, including endothelial cells, mural cells and three distinct subtypes of perivascular fibroblast along the vasculature. We uncover human-specific expression patterns along the arteriovenous axis and determine previously uncharacterized cell-type-specific markers. We use these human-specific signatures to study changes in 3,945 cerebrovascular cells from patients with Huntington's disease, which reveal activation of innate immune signalling in vascular and glial cell types and a concomitant reduction in the levels of proteins critical for maintenance of blood-brain barrier integrity. Finally, our study provides a comprehensive molecular atlas of the human cerebrovasculature to guide future biological and therapeutic studies.

Published

2022

22. An amygdala circuit that suppresses social engagement

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, McGovern Institute for Brain Research at MIT, Kwon, Jeong-Tae, Ryu, Changhyeon, Lee, Hyeseung, Sheffield, Alec, Fan, Jingxuan, Cho, Daniel H, Bigler, Shivani, Sullivan, Heather A, Choe, Han Kyung, Wickersham, Ian R, Heiman, Myriam, Choi, Gloria B, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, McGovern Institute for Brain Research at MIT, Kwon, Jeong-Tae, Ryu, Changhyeon, Lee, Hyeseung, Sheffield, Alec, Fan, Jingxuan, Cho, Daniel H, Bigler, Shivani, Sullivan, Heather A, Choe, Han Kyung, Wickersham, Ian R, Heiman, Myriam, and Choi, Gloria B

Abstract

Innate social behaviours, such as mating and fighting, are fundamental to animal reproduction and survival1. However, social engagements can also put an individual at risk2. Little is known about the neural mechanisms that enable appropriate risk assessment and the suppression of hazardous social interactions. Here we identify the posteromedial nucleus of the cortical amygdala (COApm) as a locus required for the suppression of male mating when a female mouse is unhealthy. Using anatomical tracing, functional imaging and circuit-level epistatic analyses, we show that suppression of mating with an unhealthy female is mediated by the COApm projections onto the glutamatergic population of the medial amygdalar nucleus (MEA). We further show that the role of the COApm-to-MEA connection in regulating male mating behaviour relies on the neuromodulator thyrotropin-releasing hormone (TRH). TRH is expressed in the COApm, whereas the TRH receptor (TRHR) is found in the postsynaptic MEA glutamatergic neurons. Manipulating neural activity of TRH-expressing neurons in the COApm modulated male mating behaviour. In the MEA, activation of the TRHR pathway by ligand infusion inhibited mating even towards healthy female mice, whereas genetic ablation of TRHR facilitated mating with unhealthy individuals. In summary, we reveal a neural pathway that relies on the neuromodulator TRH to modulate social interactions according to the health status of the reciprocating individual. Individuals must balance the cost of social interactions relative to the benefit, as deficits in the ability to select healthy mates may lead to the spread of disease.

Published

2022

23. Imprinted Maternally Expressed microRNAs Antagonize Paternally Driven Gene Programs in Neurons

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Koch Institute for Integrative Cancer Research at MIT, Whipple, Amanda Joy, Breton-Provencher, Vincent, Jacobs, Hannah N., Patra, Chitta Ranjan, Sur, Mriganka, Sharp, Phillip A., Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Koch Institute for Integrative Cancer Research at MIT, Whipple, Amanda Joy, Breton-Provencher, Vincent, Jacobs, Hannah N., Patra, Chitta Ranjan, Sur, Mriganka, and Sharp, Phillip A.

Abstract

Imprinted genes with parental-biased allelic expression are frequently co-regulated and enriched in common biological pathways. Here, we functionally characterize a large cluster of microRNAs (miRNAs) expressed from the maternally inherited allele (“maternally expressed”) to explore the molecular and cellular consequences of imprinted miRNA activity. Using an induced neuron (iN) culture system, we show that maternally expressed miRNAs from the miR-379/410 cluster direct the RNA-induced silencing complex (RISC) to transcriptional and developmental regulators, including paternally expressed transcripts like Plagl1. Maternal deletion of this imprinted miRNA cluster resulted in increased protein levels of several targets and upregulation of a broader transcriptional program regulating synaptic transmission and neuronal function. A subset of the transcriptional changes resulting from miR-379/410 deletion can be attributed to de-repression of Plagl1. These data suggest maternally expressed miRNAs antagonize paternally driven gene programs in neurons., National Institutes of Health (U.S.) (Grants P01-CA042063, R01-GM034277, R01-CA133404, R01-EY007023, R01-EY028219, R01-NS090473), National Cancer Institute (U.S.) (Grant P30-CA14051), National Institutes of Health (U.S.) (Postdoctoral fellowships NIH F32HD090833), National Institutes of Health (U.S.) (Grant FRQS 31677), Natural Sciences and Engineering Research Council Canada (Grant PDF-48724-2016)

Published

2022

24. Stimulus-Selective Response Plasticity in Primary Visual Cortex: Progress and Puzzles

Author

Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Montgomery, Daniel P, Hayden, Dustin J., Chaloner, Francesca A., Cooke, Samuel F., Bear, Mark F, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Montgomery, Daniel P, Hayden, Dustin J., Chaloner, Francesca A., Cooke, Samuel F., and Bear, Mark F

Abstract

Stimulus-selective response plasticity (SRP) is a robust and lasting modification of primary visual cortex (V1) that occurs in response to exposure to novel visual stimuli. It is readily observed as a pronounced increase in the magnitude of visual evoked potentials (VEPs) recorded in response to phase-reversing grating stimuli in neocortical layer 4. The expression of SRP at the individual neuron level is equally robust, but the qualities vary depending on the neuronal type and how activity is measured. This form of plasticity is highly selective for stimulus features such as stimulus orientation, spatial frequency, and contrast. Several key insights into the significance and underlying mechanisms of SRP have recently been made. First, it occurs concomitantly and shares core mechanisms with behavioral habituation, indicating that SRP reflects the formation of long-term familiarity that can support recognition of innocuous stimuli. Second, SRP does not manifest within a recording session but only emerges after an off-line period of several hours that includes sleep. Third, SRP requires not only canonical molecular mechanisms of Hebbian synaptic plasticity within V1, but also the opposing engagement of two key subclasses of cortical inhibitory neuron: the parvalbumin- and somatostatin-expressing GABAergic interneurons. Fourth, pronounced shifts in the power of cortical oscillations from high frequency (gamma) to low frequency (alpha/beta) oscillations provide respective readouts of the engagement of these inhibitory neuronal subtypes following familiarization. In this article we will discuss the implications of these findings and the outstanding questions that remain to gain a deeper understanding of this striking form of experience-dependent plasticity., NIH (R01 EY023037), Wellcome Trust (207727/Z/17/Z), Biotechnology and Biological Sciences Research Council - BBSRC (BB/S008276/1)

Published

2022

25. Active control of arousal by a locus coeruleus GABAergic circuit

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Breton-Provencher, Vincent, Sur, Mriganka, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Breton-Provencher, Vincent, and Sur, Mriganka

Abstract

© 2019, The Author(The Author(s), under exclusive licence to Springer Nature America, Inc. Arousal responses linked to locus coeruleus noradrenergic (LC-NA) activity affect cognition. However, the mechanisms that control modes of LC-NA activity remain unknown. Here, we reveal a local population of GABAergic neurons (LC-GABA) capable of modulating LC-NA activity and arousal. Retrograde tracing shows that inputs to LC-GABA and LC-NA neurons arise from similar regions, though a few regions provide differential inputs to one subtype over the other. Recordings in the locus coeruleus demonstrate two modes of LC-GABA responses whereby spiking is either correlated or broadly anticorrelated with LC-NA responses, reflecting anatomically similar and functionally coincident inputs, or differential and non-coincident inputs, to LC-NA and LC-GABA neurons. Coincident inputs control the gain of LC-NA-mediated arousal responses, whereas non-coincident inputs, such as from the prefrontal cortex to the locus coeruleus, alter global arousal levels. These findings demonstrate distinct modes by which an inhibitory locus coeruleus circuit regulates arousal in the brain.

Published

2022

26. Artificial intelligence insights into hippocampal processing

Author

Massachusetts Institute of Technology. Department of Biology, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Wirtshafter, Hannah S., Wilson, Matthew A., Massachusetts Institute of Technology. Department of Biology, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Wirtshafter, Hannah S., and Wilson, Matthew A.

Abstract

Advances in artificial intelligence, machine learning, and deep neural networks have led to new discoveries in human and animal learning and intelligence. A recent artificial intelligence agent in the DeepMind family, muZero, can complete a variety of tasks with limited information about the world in which it is operating and with high uncertainty about features of current and future space. To perform, muZero uses only three functions that are general yet specific enough to allow learning across a variety of tasks without overgeneralization across different contexts. Similarly, humans and animals are able to learn and improve in complex environments while transferring learning from other contexts and without overgeneralizing. In particular, the mammalian extrahippocampal system (eHPCS) can guide spatial decision making while simultaneously encoding and processing spatial and contextual information. Like muZero, the eHPCS is also able to adjust contextual representations depending on the degree and significance of environmental changes and environmental cues. In this opinion, we will argue that the muZero functions parallel those of the hippocampal system. We will show that the different components of the muZero model provide a framework for thinking about generalizable learning in the eHPCS, and that the evaluation of how transitions in cell representations occur between similar and distinct contexts can be informed by advances in artificial intelligence agents such as muZero. We additionally explain how advances in AI agents will provide frameworks and predictions by which to investigate the expected link between state changes and neuronal firing. Specifically, we will discuss testable predictions about the eHPCS, including the functions of replay and remapping, informed by the mechanisms behind muZero learning. We conclude with additional ways in which agents such as muZero can aid in illuminating prospective questions about neural functioning, as well as

Published

2022

27. Reliable Sensory Processing in Mouse Visual Cortex through Cooperative Interactions between Somatostatin and Parvalbumin Interneurons

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Rikhye, Rajeev Vijay, Yildirim, Murat, Han, Ming-Hu, Breton-Provencher, Vincent, Sur, Mriganka, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Rikhye, Rajeev Vijay, Yildirim, Murat, Han, Ming-Hu, Breton-Provencher, Vincent, and Sur, Mriganka

Abstract

Intrinsic neuronal variability significantly limits information encoding in the primary visual cortex (V1). However, under certain conditions, neurons can respond reliably with highly precise responses to the same visual stimuli from trial to trial. This suggests that there exists intrinsic neural circuit mechanisms that dynamically modulate the intertrial variability of visual cortical neurons. Here, we sought to elucidate the role of different inhibitory interneurons (INs) in reliable coding in mouse V1. To study the interactions between somatostatin-expressing interneurons (SST-INs) and parvalbumin-expressing interneurons (PV-INs), we used a dual-color calcium imaging technique that allowed us to simultaneously monitor these two neural ensembles while awake mice, of both sexes, passively viewed natural movies. SST neurons were more active during epochs of reliable pyramidal neuron firing, whereas PV neurons were more active during epochs of unreliable firing. SST neuron activity lagged that of PV neurons, consistent with a feedback inhibitory SST→PV circuit. To dissect the role of this circuit in pyramidal neuron activity, we used temporally limited optogenetic activation and inactivation of SST and PV interneurons during periods of reliable and unreliable pyramidal cell firing. Transient firing of SST neurons increased pyramidal neuron reliability by actively suppressing PV neurons, a proposal that was supported by a rate-based model of V1 neurons. These results identify a cooperative functional role for the SST→PV circuit in modulating the reliability of pyramidal neuron activity.SIGNIFICANCE STATEMENT Cortical neurons often respond to identical sensory stimuli with large variability. However, under certain conditions, the same neurons can also respond highly reliably. The circuit mechanisms that contribute to this modulation remain unknown. Here, we used novel dual-wavelength calcium imaging and temporally selective optical perturbation to identify an inhibito, National Institute of Biomedical Imaging and Bioengineering (Award K99EB027706), National Institutes of Health (Grants EY007023, NS090473, and EY028219)

Published

2021

28. Working Memory: Delay Activity, Yes! Persistent Activity? Maybe Not

Author

Picower Institute for Learning and Memory, Lundqvist, Lars Mikael, Herman, Pawel, Miller, Earl K, Picower Institute for Learning and Memory, Lundqvist, Lars Mikael, Herman, Pawel, and Miller, Earl K

Abstract

© 2018 the authors. Persistent spiking has been thought to underlie working memory (WM). However, virtually all of the evidence for this comes from studies that averaged spiking across time and across trials, which masks the details. On single trials, activity often occurs in sparse transient bursts. This has important computational and functional advantages. In addition, examination of more complex tasks reveals neural coding in WM is dynamic over the course of a trial. All this suggests that spiking is important for WM, but that its role is more complex than simply persistent spiking.

Published

2021

29. A cortical-brainstem circuit predicts and governs compulsive alcohol drinking

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Siciliano, Cody A, Noamany, Habiba, Chang, Chia-Jung, Brown, Alex R, Chen, Xinhong, Leible, Daniel, Lee, Jennifer J, Wang, Joyce, Vernon, Amanda N, Vander Weele, Caitlin M, Kimchi, Eyal Y, Heiman, Myriam, Tye, Kay M, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Siciliano, Cody A, Noamany, Habiba, Chang, Chia-Jung, Brown, Alex R, Chen, Xinhong, Leible, Daniel, Lee, Jennifer J, Wang, Joyce, Vernon, Amanda N, Vander Weele, Caitlin M, Kimchi, Eyal Y, Heiman, Myriam, and Tye, Kay M

Abstract

© 2019 American Association for the Advancement of Science. All rights reserved. What individual differences in neural activity predict the future escalation of alcohol drinking from casual to compulsive? The neurobiological mechanisms that gate the transition from moderate to compulsive drinking remain poorly understood. We longitudinally tracked the development of compulsive drinking across a binge-drinking experience in male mice. Binge drinking unmasked individual differences, revealing latent traits in alcohol consumption and compulsive drinking despite equal prior exposure to alcohol. Distinct neural activity signatures of cortical neurons projecting to the brainstem before binge drinking predicted the ultimate emergence of compulsivity. Mimicry of activity patterns that predicted drinking phenotypes was sufficient to bidirectionally modulate drinking. Our results provide a mechanistic explanation for individual variance in vulnerability to compulsive alcohol drinking.

Published

2021

30. Stability of extemporaneously prepared preservative-free methylphenidate 5 mg/mL intravenous solution

Author

Picower Institute for Learning and Memory, Barra, Megan E, Edlow, Brian L, Lund, James T, DeSanctis, Katherine S, Vetrano, John, Reilly-Tremblay, Cherylann, Zhang, Edlyn R, Bodien, Yelena G, Brown, Emery N, Solt, Ken, Picower Institute for Learning and Memory, Barra, Megan E, Edlow, Brian L, Lund, James T, DeSanctis, Katherine S, Vetrano, John, Reilly-Tremblay, Cherylann, Zhang, Edlyn R, Bodien, Yelena G, Brown, Emery N, and Solt, Ken

Abstract

Purpose To advance the implementation of consciousness-promoting therapies in patients with acute disorders of consciousness, the availability of potential therapeutic agents in formulations suitable for administration in hospitalized patients in the presence of complex comorbid conditions is paramount. The purpose of this study is to evaluate the long-term stability of extemporaneously prepared preservative-free methylphenidate hydrochloride (HCl) 5 mg/mL intravenous solution for experimental use. Methods A methylphenidate 5 mg/mL solution was prepared under proper aseptic techniques with Methylphenidate Hydrochloride, USP, powder mixed in sterile water for solution. Methylphenidate HCl 5 mg/mL solution was sterilized by filtration technique under USP <797>–compliant conditions. Samples were stored refrigerated (2-8°C) and analyzed at approximately days 1, 30, 60, 90, 180, and 365. At each time point, chemical and physical stability were evaluated by visual inspection, pH measurement, membrane filtration procedure, turbidometric or photometric technique, and high-performance liquid chromatography analysis. Results Over the 1-year study period, the samples retained 96.76% to 102.04% of the initial methylphenidate concentration. There was no significant change in the visual appearance, pH level, or particulate matter during the study period. The sterility of samples was maintained and endotoxin levels were undetectable throughout the 1-year stability period. Conclusion Extemporaneously prepared preservative-free methylphenidate 5 mg/mL intravenous solution was physically and chemically stable at 32, 61, 95, 186, and 365 days when stored in amber glass vials at refrigerated temperatures (2-8°C).

Published

2021

31. Behavioral States

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences., Flavell, Steven W, Raizen, David M, You, Young-Jai, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences., Flavell, Steven W, Raizen, David M, and You, Young-Jai

Abstract

© 2020 Genetics Society of America. All rights reserved. Caenorhabditis elegans' behavioral states, like those of other animals, are shaped by its immediate environment, its past experiences, and by internal factors. We here review the literature on C. elegans behavioral states and their regulation. We discuss dwelling and roaming, local and global search, mate finding, sleep, and the interaction between internal metabolic states and behavior., NIH (NS104892), NIH (GM135413), NSF (IOS 1845663), NIH (R01NS107969), NIH (R01NS088432)

Published

2021

32. Three decades of Cdk5

Author

Picower Institute for Learning and Memory, Pao, Ping-Chieh, Tsai, Li-Huei, Picower Institute for Learning and Memory, Pao, Ping-Chieh, and Tsai, Li-Huei

Abstract

Cdk5 is a proline-directed serine/threonine protein kinase that governs a variety of cellular processes in neurons, the dysregulation of which compromises normal brain function. The mechanisms underlying the modulation of Cdk5, its modes of action, and its effects on the nervous system have been a great focus in the field for nearly three decades. In this review, we provide an overview of the discovery and regulation of Cdk5, highlighting recent findings revealing its role in neuronal/synaptic functions, circadian clocks, DNA damage, cell cycle reentry, mitochondrial dysfunction, as well as its non-neuronal functions under physiological and pathological conditions. Moreover, we discuss evidence underscoring aberrant Cdk5 activity as a common theme observed in many neurodegenerative diseases.

Published

2021

33. High-content image-based analysis and proteomic profiling identifies Tau phosphorylation inhibitors in a human iPSC-derived glutamatergic neuronal model of tauopathy

Author

Picower Institute for Learning and Memory, Cheng, Chialin, Reis, Surya A, Adams, Emily T, Fass, Daniel M, Angus, Steven P, Stuhlmiller, Timothy J, Richardson, Jared, Olafson, Hailey, Wang, Eric T, Patnaik, Debasis, Beauchamp, Roberta L, Feldman, Danielle A, Silva, M Catarina, Sur, Mriganka, Johnson, Gary L, Ramesh, Vijaya, Miller, Bruce L, Temple, Sally, Kosik, Kenneth S, Dickerson, Bradford C, Haggarty, Stephen J, Picower Institute for Learning and Memory, Cheng, Chialin, Reis, Surya A, Adams, Emily T, Fass, Daniel M, Angus, Steven P, Stuhlmiller, Timothy J, Richardson, Jared, Olafson, Hailey, Wang, Eric T, Patnaik, Debasis, Beauchamp, Roberta L, Feldman, Danielle A, Silva, M Catarina, Sur, Mriganka, Johnson, Gary L, Ramesh, Vijaya, Miller, Bruce L, Temple, Sally, Kosik, Kenneth S, Dickerson, Bradford C, and Haggarty, Stephen J

Abstract

Mutations in MAPT (microtubule-associated protein tau) cause frontotemporal dementia (FTD). MAPT mutations are associated with abnormal tau phosphorylation levels and accumulation of misfolded tau protein that can propagate between neurons ultimately leading to cell death (tauopathy). Recently, a p.A152T tau variant was identifed as a risk factor for FTD, Alzheimer’s disease, and synucleinopathies. Here we used induced pluripotent stem cells (iPSC) from a patient carrying this p.A152T variant to create a robust, functional cellular assay system for probing pathophysiological tau accumulation and phosphorylation. Using stably transduced iPSC-derived neural progenitor cells engineered to enable inducible expression of the pro-neural transcription factor Neurogenin 2 (Ngn2), we generated disease-relevant, cortical-like glutamatergic neurons in a scalable, high-throughput screening compatible format. Utilizing automated confocal microscopy, and an advanced imageprocessing pipeline optimized for analysis of morphologically complex human neuronal cultures, we report quantitative, subcellular localization-specifc efects of multiple kinase inhibitors on tau, including ones under clinical investigation not previously reported to afect tau phosphorylation. These results demonstrate the potential for using patient iPSC-derived ex vivo models of tauopathy as genetically accurate, disease-relevant systems to probe tau biochemistry and support the discovery of novel therapeutics for tauopathies.

Published

2021

34. Heterosynaptic Plasticity and the Experience-Dependent Refinement of Developing Neuronal Circuits

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Jenks, Kyle R., Tsimring, Katya, Ip, Jacque Pak Kan, Zepeda, Jose C., Sur, Mriganka, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Jenks, Kyle R., Tsimring, Katya, Ip, Jacque Pak Kan, Zepeda, Jose C., and Sur, Mriganka

Abstract

Neurons remodel the structure and strength of their synapses during critical periods of development in order to optimize both perception and cognition. Many of these developmental synaptic changes are thought to occur through synapse-specific homosynaptic forms of experience-dependent plasticity. However, homosynaptic plasticity can also induce or contribute to the plasticity of neighboring synapses through heterosynaptic interactions. Decades of research in vitro have uncovered many of the molecular mechanisms of heterosynaptic plasticity that mediate local compensation for homosynaptic plasticity, facilitation of further bouts of plasticity in nearby synapses, and cooperative induction of plasticity by neighboring synapses acting in concert. These discoveries greatly benefited from new tools and technologies that permitted single synapse imaging and manipulation of structure, function, and protein dynamics in living neurons. With the recent advent and application of similar tools for in vivo research, it is now feasible to explore how heterosynaptic plasticity contribute to critical periods and the development of neuronal circuits. In this review, we will first define the forms heterosynaptic plasticity can take and describe our current understanding of their molecular mechanisms. Then, we will outline how heterosynaptic plasticity may lead to meaningful refinement of neuronal responses and observations that suggest such mechanisms are indeed at work in vivo. Finally, we will use a well-studied model of cortical plasticity—ocular dominance plasticity during a critical period of visual cortex development—to highlight the molecular overlap between heterosynaptic and developmental forms of plasticity, and suggest potential avenues of future research., NIH (Grant R01EY028219)

Published

2021

35. Selective Neuronal Vulnerability in Alzheimer’s Disease: A Network-Based Analysis

Author

Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Roussarie, Jean-Pierre, Yao, Vicky, Rodriguez-Rodriguez, Patricia, Oughtred, Rose, Rust, Jennifer, Plautz, Zakary, Kasturia, Shirin, Albornoz, Christian, Wang, Wei, Schmidt, Eric F, Dannenfelser, Ruth, Tadych, Alicja, Brichta, Lars, Barnea-Cramer, Alona, Heintz, Nathaniel, Hof, Patrick R, Heiman, Myriam, Dolinski, Kara, Flajolet, Marc, Troyanskaya, Olga G, Greengard, Paul, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Roussarie, Jean-Pierre, Yao, Vicky, Rodriguez-Rodriguez, Patricia, Oughtred, Rose, Rust, Jennifer, Plautz, Zakary, Kasturia, Shirin, Albornoz, Christian, Wang, Wei, Schmidt, Eric F, Dannenfelser, Ruth, Tadych, Alicja, Brichta, Lars, Barnea-Cramer, Alona, Heintz, Nathaniel, Hof, Patrick R, Heiman, Myriam, Dolinski, Kara, Flajolet, Marc, Troyanskaya, Olga G, and Greengard, Paul

Abstract

© 2020 The Authors Neurons display different levels of vulnerability to Alzheimer's pathology. Roussarie et al. experimentally profile and computationally model several relevant neuron types. Using a mouse-human framework, they identify genes linking Aß, aging, and tau in vulnerable neurons. Finally, they show experimentally that PTB, a regulator of tau splicing, contributes to vulnerability.

Published

2021

36. Extracellular Spike Waveform Dissociates Four Functionally Distinct Cell Classes in Primate Cortex

Author

Picower Institute for Learning and Memory, Trainito, Caterina, von Nicolai, Constantin, Miller, Earl K, Siegel, Markus, Picower Institute for Learning and Memory, Trainito, Caterina, von Nicolai, Constantin, Miller, Earl K, and Siegel, Markus

Abstract

© 2019 Elsevier Ltd Trainito et al. use a data-driven approach to robustly identify four cell classes from extracellular spike waveforms recorded in three cortical regions of macaque monkeys. The four cell classes are functionally distinct in terms of firing statistics, response dynamics, and information coding.

Published

2021

37. An easy-to-assemble, robust, and lightweight drive implant for chronic tetrode recordings in freely moving animals

Author

Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, McGovern Institute for Brain Research at MIT, Picower Institute for Learning and Memory, Voigts, Jakob, Newman, Jonathan P., Wilson, Matthew A., Harnett, Mark T., Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, McGovern Institute for Brain Research at MIT, Picower Institute for Learning and Memory, Voigts, Jakob, Newman, Jonathan P., Wilson, Matthew A., and Harnett, Mark T.

Abstract

© 2020 IOP Publishing Ltd. Tetrode arrays are a standard method for neuronal recordings in behaving animals, especially for chronic recordings of many neurons in freely-moving animals. Objective. We sought to simplify tetrode drive designs with the aim of enabling building and implanting a 16-tetrode drive in a single day. Approach. Our design makes use of recently developed technologies to reduce the complexity of the drive while maintaining a low weight. Main results. The design presents an improvement over existing implants in terms of robustness, weight, and ease of use. We describe two variants: a 16 tetrode implant weighing ∼2 g for mice, bats, tree shrews and similar animals, and a 64 tetrode implant weighing ∼16 g for rats and similar animals. These designs were co-developed and optimized alongside a new class of drive-mounted feature-rich amplifier boards with ultra-thin radio-frequency tethers, as described in an upcoming paper (Newman, Zhang et al in prep). Significance. This design significantly improves the data yield of chronic electrophysiology experiments., NIH (Grants R01NS106-031 and R21NS103-098), Simons Center for the Social Brain at MIT (Fellowship R21-EY028-381), NSF (Award CCF-1231216), NIH (Awards 1F32MH107-086-01,TR01-GM104-948, R01-MH092-638)

Published

2021

38. Adverse Ocular Events following COVID-19 Vaccination

Author

Picower Institute for Learning and Memory, Eleiwa, Taher K., Gaier, Eric D., Haseeb, Abid, ElSheikh, Reem H., Sallam, Ahmed B., Elhusseiny, Abdelrahman M., Picower Institute for Learning and Memory, Eleiwa, Taher K., Gaier, Eric D., Haseeb, Abid, ElSheikh, Reem H., Sallam, Ahmed B., and Elhusseiny, Abdelrahman M.

Published

2021

39. De-scattering with Excitation Patterning enables rapid wide-field imaging through scattering media

Author

Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Laser Biomedical Research Center, Massachusetts Institute of Technology. Department of Biological Engineering, Picower Institute for Learning and Memory, Zheng, Cheng, Park, Jong Kang, Yildirim, Murat, Boivin, Josiah R, Xue, Yi, Sur, Mriganka, So, Peter TC, Wadduwage, Dushan N, Massachusetts Institute of Technology. Department of Mechanical Engineering, Massachusetts Institute of Technology. Laser Biomedical Research Center, Massachusetts Institute of Technology. Department of Biological Engineering, Picower Institute for Learning and Memory, Zheng, Cheng, Park, Jong Kang, Yildirim, Murat, Boivin, Josiah R, Xue, Yi, Sur, Mriganka, So, Peter TC, and Wadduwage, Dushan N

Abstract

Nonlinear optical microscopy has enabled in vivo deep tissue imaging on the millimeter scale. A key unmet challenge is its limited throughput especially compared to rapid wide-field modalities that are used ubiquitously in thin specimens. Wide-field imaging methods in tissue specimens have found successes in optically cleared tissues and at shallower depths, but the scattering of emission photons in thick turbid samples severely degrades image quality at the camera. To address this challenge, we introduce a novel technique called De-scattering with Excitation Patterning or "DEEP," which uses patterned nonlinear excitation followed by computational imaging-assisted wide-field detection. Multiphoton temporal focusing allows high-resolution excitation patterns to be projected deep inside specimen at multiple scattering lengths due to the use of long wavelength light. Computational reconstruction allows high-resolution structural features to be reconstructed from tens to hundreds of DEEP images instead of millions of point-scanning measurements.

Published

2021

40. Close-range vocal interaction in the common marmoset (Callithrix jacchus)

Author

McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Simons Center for the Social Brain (Massachusetts Institute of Technology), Landman, Rogier, Sharma, Jitendra, Hyman, Julia B, Fanucci-Kiss, Adrian, Meisner, Olivia, Parmar, Shivangi, Feng, Guoping, Desimone, Robert, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Simons Center for the Social Brain (Massachusetts Institute of Technology), Landman, Rogier, Sharma, Jitendra, Hyman, Julia B, Fanucci-Kiss, Adrian, Meisner, Olivia, Parmar, Shivangi, Feng, Guoping, and Desimone, Robert

Abstract

© 2020 Landman et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited. Vocal communication in animals often involves taking turns vocalizing. In humans, turn-taking is a fundamental rule in conversation. Among non-human primates, the common marmoset is known to engage in antiphonal calling using phee calls and trill calls. Calls of the trill type are the most common, yet difficult to study, because they are not very loud and uttered in conditions when animals are in close proximity to one another. Here we recorded trill calls in captive pair-housed marmosets using wearable microphones, while the animals were together with their partner or separated, but within trill call range. Trills were exchanged mainly with the partner and not with other animals in the room. Animals placed outside the home cage increased their trill call rate and uttered more trills in response to their partner compared to strangers. The fundamental frequency, F0, of trills increased when animals were placed outside the cage. Our results indicate that trill calls can be monitored using wearable audio equipment and that minor changes in social context affect trill call interactions and spectral properties of trill calls.

Published

2021

41. Adaptive and multifunctional hydrogel hybrid probes for long-term sensing and modulation of neural activity

Author

Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Mechanical Engineering, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Park, Seongjun, Yuk, Hyunwoo, Zhao, Ruike, Yim, Yeong Shin, Woldeghebriel, Eyob W, Kang, Jeewoo, Canales, Andres, Fink, Yoel, Choi, Gloria B, Zhao, Xuanhe, Anikeeva, Polina, Massachusetts Institute of Technology. Department of Electrical Engineering and Computer Science, Massachusetts Institute of Technology. Research Laboratory of Electronics, Massachusetts Institute of Technology. Department of Mechanical Engineering, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Department of Chemical Engineering, Massachusetts Institute of Technology. Department of Materials Science and Engineering, Massachusetts Institute of Technology. Institute for Soldier Nanotechnologies, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Civil and Environmental Engineering, Park, Seongjun, Yuk, Hyunwoo, Zhao, Ruike, Yim, Yeong Shin, Woldeghebriel, Eyob W, Kang, Jeewoo, Canales, Andres, Fink, Yoel, Choi, Gloria B, Zhao, Xuanhe, and Anikeeva, Polina

Abstract

To understand the underlying mechanisms of progressive neurophysiological phenomena, neural interfaces should interact bi-directionally with brain circuits over extended periods of time. However, such interfaces remain limited by the foreign body response that stems from the chemo-mechanical mismatch between the probes and the neural tissues. To address this challenge, we developed a multifunctional sensing and actuation platform consisting of multimaterial fibers intimately integrated within a soft hydrogel matrix mimicking the brain tissue. These hybrid devices possess adaptive bending stiffness determined by the hydration states of the hydrogel matrix. This enables their direct insertion into the deep brain regions, while minimizing tissue damage associated with the brain micromotion after implantation. The hydrogel hybrid devices permit electrophysiological, optogenetic, and behavioral studies of neural circuits with minimal foreign body responses and tracking of stable isolated single neuron potentials in freely moving mice over 6 months following implantation.

Published

2021

42. Representations of Sensory Signals and Abstract Categories in Brain Networks

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Pinotsis, Dimitrios, Siegel, Markus, Miller, Earl K, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Pinotsis, Dimitrios, Siegel, Markus, and Miller, Earl K

Abstract

Many recent advances in artificial intelligence (AI) are rooted in visual neuroscience. However, ideas from more complicated paradigms like decision-making are less used. Although automated decision-making systems are ubiquitous (driverless cars, pilot support systems, medical diagnosis algorithms etc.), achieving human-level performance in decision making tasks is still a challenge. At the same time, these tasks that are hard for AI are easy for humans. Thus, understanding human brain dynamics during these decision-making tasks and modeling them using deep neural networks could improve AI performance. Here we modelled some of the complex neural interactions during a sensorimotor decision making task. We investigated how brain dynamics flexibly represented and distinguished between sensory processing and categorization in two sensory domains: motion direction and color. We found that neural representations changed depending on context. We also trained deep recurrent neural networks to perform the same tasks as the animals. By comparing brain dynamics with network predictions, we found that computations in different brain areas also changed flexibly depending on context. Color computations appeared to rely more on sensory processing, while motion computations more on abstract categories. Overall, our results shed light to the biological basis of categorization and differences in selectivity and computations in different brain areas., NIMH (Grant R37MH087027)

Published

2021

43. Twister3: a simple and fast microwire twister

Author

Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, McGovern Institute for Brain Research at MIT, Newman, Jonathan P, Voigts, Jakob, Borius, Maxim, Karlsson, Mattias, Harnett, Mark T, Wilson, Matthew A, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, McGovern Institute for Brain Research at MIT, Newman, Jonathan P, Voigts, Jakob, Borius, Maxim, Karlsson, Mattias, Harnett, Mark T, and Wilson, Matthew A

Abstract

© 2020 IOP Publishing Ltd. Objective. Twisted wire probes (TWPs, e.g. stereotrodes and tetrodes) provide a cheap and reliable method for obtaining high quality, multiple single-unit neural recordings in freely moving animals. Despite their ubiquity, TWPs are constructed using a tedious procedure consisting of manually folding, turning, and fusing microwire. This imposes a significant labor burden on research personnel who use TWPs in their experiments. Approach. To address this issue, we created Twister3, an open-source microwire twisting machine. This machine features a quick-draw wire feeder that eliminates manual wire folding, an auto-aligning motor attachment mechanism which results in consistently straight probes, and a high speed motor for rapid probe turning. Main results. Twister3 greatly increases the speed and repeatability of constructing twisted microwire probes compared to existing options. Users with less than one hour of experience using the device were able to make ∼70 tetrodes per hour, on average. It is cheap, well documented, and all associated designs and source code are open-source. Significance. Twister3 significantly reduces the labor burden of creating high-quality TWPs so electrophysiologists can spend more of their time performing recordings rather than making probes. Therefore, this device is of interest to any lab performing TWP neural recordings, for example, using microdrives.

Published

2021

44. Gamma Entrainment Binds Higher-Order Brain Regions and Offers Neuroprotection

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Media Laboratory, Massachusetts Institute of Technology. Department of Biological Engineering, Harvard University--MIT Division of Health Sciences and Technology, Adaikkan, Chinnakkaruppan, Middleton, Steven J, Marco, Asaf, Pao, Ping-Chieh, Mathys, Hansruedi, Kim, David Nam-Woo, Gao, Fan, Young, Jennie Z, Suk, Ho-Jun, Boyden, Edward S, McHugh, Thomas J, Tsai, Li-Huei, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, McGovern Institute for Brain Research at MIT, Massachusetts Institute of Technology. Media Laboratory, Massachusetts Institute of Technology. Department of Biological Engineering, Harvard University--MIT Division of Health Sciences and Technology, Adaikkan, Chinnakkaruppan, Middleton, Steven J, Marco, Asaf, Pao, Ping-Chieh, Mathys, Hansruedi, Kim, David Nam-Woo, Gao, Fan, Young, Jennie Z, Suk, Ho-Jun, Boyden, Edward S, McHugh, Thomas J, and Tsai, Li-Huei

Abstract

© 2019 Elsevier Inc. Chronic application of patterned visual stimulation in neurodegeneration mouse models to entrain gamma oscillations results in preservation of neuronal and synaptic density across multiple brain regions.

Published

2021

45. Shape deformation analysis reveals the temporal dynamics of cell-type-specific homeostatic and pathogenic responses to mutant huntingtin

Author

Picower Institute for Learning and Memory, Megret, Lucile, Gris, Barbara, Sasidharan Nair, Satish, Cevost, Jasmin, Wertz, Mary, Aaronson, Jeff, Rosinski, Jim, Vogt, Thomas F, Wilkinson, Hilary, Heiman, Myriam, Neri, Christian, Picower Institute for Learning and Memory, Megret, Lucile, Gris, Barbara, Sasidharan Nair, Satish, Cevost, Jasmin, Wertz, Mary, Aaronson, Jeff, Rosinski, Jim, Vogt, Thomas F, Wilkinson, Hilary, Heiman, Myriam, and Neri, Christian

Abstract

© Megret et al. Loss of cellular homeostasis has been implicated in the etiology of several neurodegenerative diseases (NDs). However, the molecular mechanisms that underlie this loss remain poorly understood on a systems level in each case. Here, using a novel computational approach to integrate dimensional RNA-seq and in vivo neuron survival data, we map the temporal dynamics of homeostatic and pathogenic responses in four striatal cell types of Huntington’s disease (HD) model mice. This map shows that most pathogenic responses are mitigated and most homeostatic responses are decreased over time, suggesting that neuronal death in HD is primarily driven by the loss of homeostatic responses. Moreover, different cell types may lose similar homeostatic processes, for example, endosome biogenesis and mitochondrial quality control in Drd1-expressing neurons and astrocytes. HD relevance is validated by human stem cell, genome-wide association study, and post-mortem brain data. These findings provide a new paradigm and framework for therapeutic discovery in HD and other NDs.

Published

2021

46. Distinct Laminar Requirements for NMDA Receptors in Experience-Dependent Visual Cortical Plasticity

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Fong, Ming-fai, Finnie, Peter Sb, Kim, Taekeun, Thomazeau, Aurore, Kaplan, Eitan S, Cooke, Samuel F, Bear, Mark F, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Fong, Ming-fai, Finnie, Peter Sb, Kim, Taekeun, Thomazeau, Aurore, Kaplan, Eitan S, Cooke, Samuel F, and Bear, Mark F

Abstract

© 2020 Oxford University Press. All rights reserved. Primary visual cortex (V1) is the locus of numerous forms of experience-dependent plasticity. Restricting visual stimulation to one eye at a time has revealed that many such forms of plasticity are eye-specific, indicating that synaptic modification occurs prior to binocular integration of thalamocortical inputs. A common feature of these forms of plasticity is the requirement for NMDA receptor (NMDAR) activation in V1.We therefore hypothesized that NMDARs in cortical layer 4 (L4), which receives the densest thalamocortical input, would be necessary for all forms of NMDAR-dependent and input-specific V1 plasticity.We tested this hypothesis in awake mice using a genetic approach to selectively delete NMDARs from L4 principal cells.We found, unexpectedly, that both stimulus-selective response potentiation and potentiation of open-eye responses following monocular deprivation (MD) persist in the absence of L4 NMDARs. In contrast, MD-driven depression of deprived-eye responses was impaired in mice lacking L4 NMDARs, as was L4 long-term depression in V1 slices. Our findings reveal a crucial requirement for L4 NMDARs in visual cortical synaptic depression, and a surprisingly negligible role for them in cortical response potentiation. These results demonstrate that NMDARs within distinct cellular subpopulations support different forms of experience-dependent plasticity.

Published

2021

47. Broadband slow-wave modulation in posterior and anterior cortex tracks distinct states of propofol-induced unconsciousness

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Harvard University--MIT Division of Health Sciences and Technology, Stephen, Emily P, Hotan, Gladia C, Pierce, Eric T, Harrell, P Grace, Walsh, John L, Brown, Emery N, Purdon, Patrick L, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology. Institute for Medical Engineering & Science, Harvard University--MIT Division of Health Sciences and Technology, Stephen, Emily P, Hotan, Gladia C, Pierce, Eric T, Harrell, P Grace, Walsh, John L, Brown, Emery N, and Purdon, Patrick L

Abstract

© 2020, The Author(s). A controversy has developed in recent years over the roles of frontal and posterior cortices in mediating consciousness and unconsciousness. Disruption of posterior cortex during sleep appears to suppress the contents of dreaming, yet activation of frontal cortex appears necessary for perception and can reverse unconsciousness under anesthesia. We used anesthesia to study how regional cortical disruption, mediated by slow wave modulation of broadband activity, changes during unconsciousness in humans. We found that broadband slow-wave modulation enveloped posterior cortex when subjects initially became unconscious, but later encompassed both frontal and posterior cortex when subjects were more deeply anesthetized and likely unarousable. Our results suggest that unconsciousness under anesthesia comprises several distinct shifts in brain state that disrupt the contents of consciousness distinct from arousal and awareness of those contents.

Published

2021

48. Visual recognition is heralded by shifts in local field potential oscillations and inhibitory networks in primary visual cortex

Author

Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Hayden, Dustin J, Montgomery, Daniel P, Cooke, Samuel F, Bear, Mark F, Picower Institute for Learning and Memory, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Hayden, Dustin J, Montgomery, Daniel P, Cooke, Samuel F, and Bear, Mark F

Abstract

Learning to recognize and filter familiar, irrelevant sensory stimuli eases the computational burden on the cerebral cortex. Inhibition is a candidate mechanism in this filtration process, and oscillations in the cortical local field potential (LFP) serve as markers of the engagement of different inhibitory neurons. We show here that LFP oscillatory activity in visual cortex is profoundly altered as male and female mice learn to recognize an oriented grating stimulus-low frequency (∼15 Hz peak) power sharply increases while high frequency (∼65 Hz peak) power decreases. These changes report recognition of the familiar pattern, as they disappear when the stimulus is rotated to a novel orientation. Two-photon imaging of neuronal activity reveals that parvalbumin-expressing inhibitory neurons disengage with familiar stimuli and reactivate to novelty, whereas somatostatin-expressing inhibitory neurons show opposing activity patterns. We propose a model in which the balance of two interacting interneuron circuits shifts as novel stimuli become familiar.SIGNIFICANCE STATEMENT:Habituation, familiarity and novelty detection are fundamental cognitive processes that enable organisms to adaptively filter meaningless stimuli and focus attention on potentially important elements of their environment. We have shown that this process can be studied fruitfully in the mouse primary visual cortex by using simple grating stimuli for which novelty and familiarity are defined by orientation, and by measuring stimulus-evoked and continuous local field potentials. Altered event-related and spontaneous potentials, and deficient habituation, are well-documented features of several neurodevelopmental psychiatric disorders. The paradigm described here will be valuable to interrogate the origins of these signals and the meaning of their disruption more deeply.

Published

2021

49. Personalized Connectome Mapping to Guide Targeted Therapy and Promote Recovery of Consciousness in the Intensive Care Unit

Author

Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Edlow, Brian L, Barra, Megan E, Zhou, David W, Foulkes, Andrea S, Snider, Samuel B, Threlkeld, Zachary D, Chakravarty, Sourish, Kirsch, John E, Chan, Suk-tak, Meisler, Steven L, Bleck, Thomas P, Fins, Joseph J, Giacino, Joseph T, Hochberg, Leigh R, Massachusetts Institute of Technology. Department of Brain and Cognitive Sciences, Picower Institute for Learning and Memory, Edlow, Brian L, Barra, Megan E, Zhou, David W, Foulkes, Andrea S, Snider, Samuel B, Threlkeld, Zachary D, Chakravarty, Sourish, Kirsch, John E, Chan, Suk-tak, Meisler, Steven L, Bleck, Thomas P, Fins, Joseph J, Giacino, Joseph T, and Hochberg, Leigh R

Abstract

There are currently no therapies proven to promote early recovery of consciousness in patients with severe brain injuries in the intensive care unit (ICU). For patients whose families face time-sensitive, life-or-death decisions, treatments that promote recovery of consciousness are needed to reduce the likelihood of premature withdrawal of life-sustaining therapy, facilitate autonomous self-expression, and increase access to rehabilitative care. Here, we present the Connectome-based Clinical Trial Platform (CCTP), a new paradigm for developing and testing targeted therapies that promote early recovery of consciousness in the ICU. We report the protocol for STIMPACT (Stimulant Therapy Targeted to Individualized Connectivity Maps to Promote ReACTivation of Consciousness), a CCTP-based trial in which intravenous methylphenidate will be used for targeted stimulation of dopaminergic circuits within the subcortical ascending arousal network (ClinicalTrials.gov NCT03814356). The scientific premise of the CCTP and the STIMPACT trial is that personalized brain network mapping in the ICU can identify patients whose connectomes are amenable to neuromodulation. Phase 1 of the STIMPACT trial is an open-label, safety and dose-finding study in 22 patients with disorders of consciousness caused by acute severe traumatic brain injury. Patients in Phase 1 will receive escalating daily doses (0.5–2.0 mg/kg) of intravenous methylphenidate over a 4-day period and will undergo resting-state functional magnetic resonance imaging and electroencephalography to evaluate the drug’s pharmacodynamic properties. The primary outcome measure for Phase 1 relates to safety: the number of drug-related adverse events at each dose. Secondary outcome measures pertain to pharmacokinetics and pharmacodynamics: (1) time to maximal serum concentration; (2) serum half-life; (3) effect of the highest tolerated dose on resting-state functional MRI biomarkers of connectivity; and (4) effect of each do

Published

2021

50. Prefrontal oscillations modulate the propagation of neuronal activity required for working memory

Author

Picower Institute for Learning and Memory, Sherfey, Jason, Ardid, Salva, Miller, Earl K, Hasselmo, Michael E, Kopell, Nancy J, Picower Institute for Learning and Memory, Sherfey, Jason, Ardid, Salva, Miller, Earl K, Hasselmo, Michael E, and Kopell, Nancy J

Abstract

© 2020 The Author(s) Cognition involves using attended information, maintained in working memory (WM), to guide action. During a cognitive task, a correct response requires flexible, selective gating so that only the appropriate information flows from WM to downstream effectors that carry out the response. In this work, we used biophysically-detailed modeling to explore the hypothesis that network oscillations in prefrontal cortex (PFC), leveraging local inhibition, can independently gate responses to items in WM. The key role of local inhibition was to control the period between spike bursts in the outputs, and to produce an oscillatory response no matter whether the WM item was maintained in an asynchronous or oscillatory state. We found that the WM item that induced an oscillatory population response in the PFC output layer with the shortest period between spike bursts was most reliably propagated. The network resonant frequency (i.e., the input frequency that produces the largest response) of the output layer can be flexibly tuned by varying the excitability of deep layer principal cells. Our model suggests that experimentally-observed modulation of PFC beta-frequency (15–30 Hz) and gamma-frequency (30–80 Hz) oscillations could leverage network resonance and local inhibition to govern the flexible routing of signals in service to cognitive processes like gating outputs from working memory and the selection of rule-based actions. Importantly, we show for the first time that nonspecific changes in deep layer excitability can tune the output gate's resonant frequency, enabling the specific selection of signals encoded by populations in asynchronous or fast oscillatory states. More generally, this represents a dynamic mechanism by which adjusting network excitability can govern the propagation of asynchronous and oscillatory signals throughout neocortex.

Published

2021