Your search keyword '"Kelley, Douglas H."' showing total 10 results

1. Emergent dynamics of laboratory insect swarms

Author

Massachusetts Institute of Technology. Department of Materials Science and Engineering, Kelley, Douglas H., Ouellette, Nicholas T., Massachusetts Institute of Technology. Department of Materials Science and Engineering, Kelley, Douglas H., and Ouellette, Nicholas T.

Abstract

Collective animal behaviour occurs at nearly every biological size scale, from single-celled organisms to the largest animals on earth. It has long been known that models with simple interaction rules can reproduce qualitative features of this complex behaviour. But determining whether these models accurately capture the biology requires data from real animals, which has historically been difficult to obtain. Here, we report three-dimensional, time-resolved measurements of the positions, velocities, and accelerations of individual insects in laboratory swarms of the midge Chironomus riparius. Even though the swarms do not show an overall polarisation, we find statistical evidence for local clusters of correlated motion. We also show that the swarms display an effective large-scale potential that keeps individuals bound together, and we characterize the shape of this potential. Our results provide quantitative data against which the emergent characteristics of animal aggregation models can be benchmarked., United States. Army Research Office (Grant W911Nf-12-1-0517)

Published

2014

2. Emergent dynamics of laboratory insect swarms

Author

Douglas H. Kelley, Nicholas T. Ouellette, Massachusetts Institute of Technology. Department of Materials Science and Engineering, and Kelley, Douglas H.

Subjects

Male, Chironomus riparius, Multidisciplinary, Behavior, Animal, Ecology, ved/biology, ved/biology.organism_classification_rank.species, Dynamics (mechanics), Biology, Article, Chironomidae, Animals, Scale (map), Biological system, Statistical evidence

Abstract

Collective animal behaviour occurs at nearly every biological size scale, from single-celled organisms to the largest animals on earth. It has long been known that models with simple interaction rules can reproduce qualitative features of this complex behaviour. But determining whether these models accurately capture the biology requires data from real animals, which has historically been difficult to obtain. Here, we report three-dimensional, time-resolved measurements of the positions, velocities, and accelerations of individual insects in laboratory swarms of the midge Chironomus riparius. Even though the swarms do not show an overall polarisation, we find statistical evidence for local clusters of correlated motion. We also show that the swarms display an effective large-scale potential that keeps individuals bound together, and we characterize the shape of this potential. Our results provide quantitative data against which the emergent characteristics of animal aggregation models can be benchmarked., United States. Army Research Office (Grant W911Nf-12-1-0517)

Published

2012

3. Potentiating glymphatic drainage minimizes post-traumatic cerebral oedema.

Author

Hussain R, Tithof J, Wang W, Cheetham-West A, Song W, Peng W, Sigurdsson B, Kim D, Sun Q, Peng S, Plá V, Kelley DH, Hirase H, Castorena-Gonzalez JA, Weikop P, Goldman SA, Davis MJ, and Nedergaard M

Subjects

Animals, Mice, Adrenergic Antagonists pharmacology, Adrenergic Antagonists therapeutic use, Disease Models, Animal, Inflammation complications, Inflammation drug therapy, Inflammation metabolism, Inflammation prevention & control, Lymphatic Vessels metabolism, Phosphorylation, Receptors, Adrenergic metabolism, Brain Edema complications, Brain Edema drug therapy, Brain Edema metabolism, Brain Edema prevention & control, Brain Injuries, Traumatic complications, Brain Injuries, Traumatic drug therapy, Brain Injuries, Traumatic metabolism, Glymphatic System drug effects, Glymphatic System metabolism, Norepinephrine metabolism

Abstract

Cerebral oedema is associated with morbidity and mortality after traumatic brain injury (TBI) 1 . Noradrenaline levels are increased after TBI 2-4 , and the amplitude of the increase in noradrenaline predicts both the extent of injury 5 and the likelihood of mortality 6 . Glymphatic impairment is both a feature of and a contributor to brain injury 7,8 , but its relationship with the injury-associated surge in noradrenaline is unclear. Here we report that acute post-traumatic oedema results from a suppression of glymphatic and lymphatic fluid flow that occurs in response to excessive systemic release of noradrenaline. This post-TBI adrenergic storm was associated with reduced contractility of cervical lymphatic vessels, consistent with diminished return of glymphatic and lymphatic fluid to the systemic circulation. Accordingly, pan-adrenergic receptor inhibition normalized central venous pressure and partly restored glymphatic and cervical lymphatic flow in a mouse model of TBI, and these actions led to substantially reduced brain oedema and improved functional outcomes. Furthermore, post-traumatic inhibition of adrenergic signalling boosted lymphatic export of cellular debris from the traumatic lesion, substantially reducing secondary inflammation and accumulation of phosphorylated tau. These observations suggest that targeting the noradrenergic control of central glymphatic flow may offer a therapeutic approach for treating acute TBI., (© 2023. The Author(s), under exclusive licence to Springer Nature Limited.)

Published

2023

4. Publisher Correction: Glymphatic influx and clearance are accelerated by neurovascular coupling.

Author

Holstein-Rønsbo S, Gan Y, Giannetto MJ, Rasmussen MK, Sigurdsson B, Beinlich FRM, Rose L, Untiet V, Hablitz LM, Kelley DH, and Nedergaard M

Published

2023

5. Glymphatic influx and clearance are accelerated by neurovascular coupling.

Author

Holstein-Rønsbo S, Gan Y, Giannetto MJ, Rasmussen MK, Sigurdsson B, Beinlich FRM, Rose L, Untiet V, Hablitz LM, Kelley DH, and Nedergaard M

Subjects

Mice, Animals, Hemodynamics, Brain metabolism, Neurovascular Coupling, Hyperemia metabolism, Glymphatic System metabolism

Abstract

Functional hyperemia, also known as neurovascular coupling, is a phenomenon that occurs when neural activity increases local cerebral blood flow. Because all biological activity produces metabolic waste, we here sought to investigate the relationship between functional hyperemia and waste clearance via the glymphatic system. The analysis showed that whisker stimulation increased both glymphatic influx and clearance in the mouse somatosensory cortex with a 1.6-fold increase in periarterial cerebrospinal fluid (CSF) influx velocity in the activated hemisphere. Particle tracking velocimetry revealed a direct coupling between arterial dilation/constriction and periarterial CSF flow velocity. Optogenetic manipulation of vascular smooth muscle cells enhanced glymphatic influx in the absence of neural activation. We propose that impedance pumping allows arterial pulsatility to drive CSF in the same direction as blood flow, and we present a simulation that supports this idea. Thus, functional hyperemia boosts not only the supply of metabolites but also the removal of metabolic waste., (© 2023. The Author(s), under exclusive licence to Springer Nature America, Inc.)

Published

2023

6. Author Correction: Dispersion as a waste-clearance mechanism in flow through penetrating perivascular spaces in the brain.

Author

Troyetsky DE, Tithof J, Thomas JH, and Kelley DH

Published

2021

7. Dispersion as a waste-clearance mechanism in flow through penetrating perivascular spaces in the brain.

Author

Troyetsky DE, Tithof J, Thomas JH, and Kelley DH

Subjects

Alzheimer Disease metabolism, Diffusion, Humans, Brain metabolism, Glymphatic System metabolism

Abstract

Accumulation of metabolic wastes in the brain is correlated with several neurodegenerative disorders, including Alzheimer's disease. Waste transport and clearance occur via dispersion, the combined effect of diffusion and advection by flow of fluid. We examine the relative contributions of diffusion and advection in the perivascular spaces (PVSs) that surround penetrating cortical blood vessels and are filled with cerebrospinal fluid (CSF). To do so, we adapt prior analytic predictions of dispersion to the context of PVSs. We also perform advection-diffusion simulations in PVS-like geometries with parameters relevant to transport of amyloid-[Formula: see text] (associated with Alzheimer's) in a variety of flows, motivated by in vivo measurements. Specifically, we examine solute transport in steady and unsteady Poiseuille flows in an open (not porous) concentric circular annulus. We find that a purely oscillatory flow enhances dispersion only weakly and does not produce significant transport, whereas a steady flow component, even if slow, clears waste more effectively.

Published

2021

8. Mechanically facilitated micro-fluid mixing in the organ of Corti.

Author

Shokrian M, Knox C, Kelley DH, and Nam JH

Subjects

Animals, Cell Movement, Humans, Mice, Potassium metabolism, Hearing, Microfluidics, Models, Anatomic, Organ of Corti physiology, Organ of Corti ultrastructure, Sound

Abstract

The cochlea is filled with two lymphatic fluids. Homeostasis of the cochlear fluids is essential for healthy hearing. The sensory epithelium called the organ of Corti separates the two fluids. Corti fluid space, extracellular fluid space within the organ of Corti, looks like a slender micro-tube. Substantial potassium ions are constantly released into the Corti fluid by sensory receptor cells. Excess potassium ions in the Corti fluid are resorbed by supporting cells to maintain fluid homeostasis. Through computational simulations, we investigated fluid mixing within the Corti fluid space. Two assumptions were made: first, there exists a longitudinal gradient of potassium ion concentration; second, outer hair cell motility causes organ of Corti deformations that alter the cross-sectional area of the Corti fluid space. We hypothesized that mechanical agitations can accelerate longitudinal mixing of Corti fluid. Corti fluid motion was determined by solving the Navier-Stokes equations incorporating nonlinear advection term. Advection-diffusion equation determined the mixing dynamics. Simulating traveling boundary waves, we found that advection and diffusion caused comparable mixing when the wave amplitude and speed were 25 nm and 7 m/s, respectively. Higher-amplitude and faster waves caused stronger advection. When physiological traveling waves corresponding to 70 dB sound pressure level at 9 kHz were simulated, advection speed was as large as 1 mm/s in the region basal to the peak responding location. Such physiological agitation accelerated longitudinal mixing by more than an order of magnitude, compared to pure diffusion. Our results suggest that fluid motion due to outer hair cell motility can help maintain longitudinal homeostasis of the Corti fluid.

Published

2020

9. Searching for effective forces in laboratory insect swarms.

Author

Puckett JG, Kelley DH, and Ouellette NT

Subjects

Animals, Female, Male, Models, Theoretical, Behavior, Animal, Chironomidae

Abstract

Collective animal behaviour is often modeled by systems of agents that interact via effective social forces, including short-range repulsion and long-range attraction. We search for evidence of such effective forces by studying laboratory swarms of the flying midge Chironomus riparius. Using multi-camera stereoimaging and particle-tracking techniques, we record three-dimensional trajectories for all the individuals in the swarm. Acceleration measurements show a clear short-range repulsion, which we confirm by considering the spatial statistics of the midges, but no conclusive long-range interactions. Measurements of the mean free path of the insects also suggest that individuals are on average very weakly coupled, but that they are also tightly bound to the swarm itself. Our results therefore suggest that some attractive interaction maintains cohesion of the swarms, but that this interaction is not as simple as an attraction to nearest neighbours.

Published

2014

10. Emergent dynamics of laboratory insect swarms.

Author

Kelley DH and Ouellette NT

Subjects

Animals, Male, Behavior, Animal, Chironomidae physiology

Abstract

Collective animal behaviour occurs at nearly every biological size scale, from single-celled organisms to the largest animals on earth. It has long been known that models with simple interaction rules can reproduce qualitative features of this complex behaviour. But determining whether these models accurately capture the biology requires data from real animals, which has historically been difficult to obtain. Here, we report three-dimensional, time-resolved measurements of the positions, velocities, and accelerations of individual insects in laboratory swarms of the midge Chironomus riparius. Even though the swarms do not show an overall polarisation, we find statistical evidence for local clusters of correlated motion. We also show that the swarms display an effective large-scale potential that keeps individuals bound together, and we characterize the shape of this potential. Our results provide quantitative data against which the emergent characteristics of animal aggregation models can be benchmarked.

Published

2013