Your search keyword '"Nordström, Karin"' showing total 60 results

1. Temperature during pupal development affects hoverfly developmental time, adult life span, and wing length.

Author

Daňková K, Nicholas S, and Nordström K

Abstract

Hoverflies (Diptera, Syrphidae) are cosmopolitan, generalist flower visitors and among the most important pollinators after bees and bumblebees. The dronefly Eristalis tenax can be found in temperate and continental climates across the globe, often synanthropically. Eristalis tenax pupae of different generations and different climate zones are thus exposed to vastly different temperatures. In many insects, the ambient temperature during the pupal stage affects development, adult size, and survival; however, the effect of developmental temperature on these traits in hoverflies is comparatively poorly understood. We here reared E . tenax pupae at different temperatures, from 10°C to 25°C, and quantified the effect on adult hoverflies. We found that pupal rearing at 17°C appeared to be optimal, with high eclosion rates, longer wings, and increased adult longevity. Rearing temperatures above or below this optimum led to decreased eclosion rates, wing size, and adult survival. Similar thermal dependence has been observed in other insects. We found that rearing temperature had no significant effect on locomotor activity, coloration or weight, despite evidence of strong sexual dimorphism for each of these traits. Our findings are important as hoverflies are key pollinators, and understanding the effects of developmental temperature could potentially be useful for horticulture., Competing Interests: The authors declare no conflict of interest., (© 2023 The Authors. Ecology and Evolution published by John Wiley & Sons Ltd.)

Published

2023

2. Descending neurons of the hoverfly respond to pursuits of artificial targets.

Author

Ogawa Y, Nicholas S, Thyselius M, Leibbrandt R, Nowotny T, Knight JC, and Nordström K

Subjects

Animals, Male, Neurons physiology, Visual Fields, Vision, Ocular, Photic Stimulation, Motion Perception physiology, Diptera physiology

Abstract

Many animals use motion vision information to control dynamic behaviors. Predatory animals, for example, show an exquisite ability to detect rapidly moving prey, followed by pursuit and capture. Such target detection is not only used by predators but is also important in conspecific interactions, such as for male hoverflies defending their territories against conspecific intruders. Visual target detection is believed to be subserved by specialized target-tuned neurons found in a range of species, including vertebrates and arthropods. However, how these target-tuned neurons respond to actual pursuit trajectories is currently not well understood. To redress this, we recorded extracellularly from target-selective descending neurons (TSDNs) in male Eristalis tenax hoverflies. We show that they have dorso-frontal receptive fields with a preferred direction up and away from the visual midline. We reconstructed visual flow fields as experienced during pursuits of artificial targets (black beads). We recorded TSDN responses to six reconstructed pursuits and found that each neuron responded consistently at remarkably specific time points but that these time points differed between neurons. We found that the observed spike probability was correlated with the spike probability predicted from each neuron's receptive field and size tuning. Interestingly, however, the overall response rate was low, with individual neurons responding to only a small part of each reconstructed pursuit. In contrast, the TSDN population responded to substantially larger proportions of the pursuits but with lower probability. This large variation between neurons could be useful if different neurons control different parts of the behavioral output., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2023

3. Dual Receptive Fields Underlying Target and Wide-Field Motion Sensitivity in Looming-Sensitive Descending Neurons.

Author

Nicholas S, Ogawa Y, and Nordström K

Subjects

Animals, Male, Neurons physiology, Retina, Photic Stimulation, Motion Perception physiology, Diptera physiology

Abstract

Responding rapidly to visual stimuli is fundamental for many animals. For example, predatory birds and insects alike have amazing target detection abilities, with incredibly short neural and behavioral delays, enabling efficient prey capture. Similarly, looming objects need to be rapidly avoided to ensure immediate survival, as these could represent approaching predators. Male Eristalis tenax hoverflies are nonpredatory, highly territorial insects that perform high-speed pursuits of conspecifics and other territorial intruders. During the initial stages of the pursuit, the retinal projection of the target is very small, but this grows to a larger object before physical interaction. Supporting such behaviors, E. tenax and other insects have both target-tuned and loom-sensitive neurons in the optic lobes and the descending pathways. We here show that these visual stimuli are not necessarily encoded in parallel. Indeed, we describe a class of descending neurons that respond to small targets, to looming and to wide-field stimuli. We show that these descending neurons have two distinct receptive fields where the dorsal receptive field is sensitive to the motion of small targets and the ventral receptive field responds to larger objects or wide-field stimuli. Our data suggest that the two receptive fields have different presynaptic input, where the inputs are not linearly summed. This novel and unique arrangement could support different behaviors, including obstacle avoidance, flower landing, and target pursuit or capture., Competing Interests: The authors declare no competing financial interests., (Copyright © 2023 Nicholas et al.)

Published

2023

4. Hoverfly (Eristalis tenax) pursuit of artificial targets.

Author

Thyselius M, Ogawa Y, Leibbrandt R, Wardill TJ, Gonzalez-Bellido PT, and Nordström K

Subjects

Animals, Male, Insecta, Territoriality, Predatory Behavior, Odonata, Diptera

Abstract

The ability to visualize small moving objects is vital for the survival of many animals, as these could represent predators or prey. For example, predatory insects, including dragonflies, robber flies and killer flies, perform elegant, high-speed pursuits of both biological and artificial targets. Many non-predatory insects, including male hoverflies and blowflies, also pursue targets during territorial or courtship interactions. To date, most hoverfly pursuits have been studied outdoors. To investigate hoverfly (Eristalis tenax) pursuits under more controlled settings, we constructed an indoor arena that was large enough to encourage naturalistic behavior. We presented artificial beads of different sizes, moving at different speeds, and filmed pursuits with two cameras, allowing subsequent 3D reconstruction of the hoverfly and bead position as a function of time. We show that male E. tenax hoverflies are unlikely to use strict heuristic rules based on angular size or speed to determine when to start pursuit, at least in our indoor setting. We found that hoverflies pursued faster beads when the trajectory involved flying downwards towards the bead. Furthermore, we show that target pursuit behavior can be broken down into two stages. In the first stage, the hoverfly attempts to rapidly decreases the distance to the target by intercepting it at high speed. During the second stage, the hoverfly's forward speed is correlated with the speed of the bead, so that the hoverfly remains close, but without catching it. This may be similar to dragonfly shadowing behavior, previously coined 'motion camouflage'., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2023. Published by The Company of Biologists Ltd.)

Published

2023

5. Vision: Flies move their eyes.

Author

Nordström K and Barron AB

Subjects

Animals, Vision, Ocular, Movement, Retina, Eye Movements, Diptera

Abstract

As you are reading this text, your eyes scan across the page, even if you keep your head perfectly still. New research reveals that flies can perform analogous retinal movements, despite their eyes being rigidly fixed to their heads., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2022 Elsevier Inc. All rights reserved.)

Published

2023

6. The impulse response of optic flow-sensitive descending neurons to roll m-sequences.

Author

Leibbrandt R, Nicholas S, and Nordström K

Subjects

Animals, Male, Movement, Neurons, Diptera, Motion Perception, Optic Flow

Abstract

When animals move through the world, their own movements generate widefield optic flow across their eyes. In insects, such widefield motion is encoded by optic lobe neurons. These lobula plate tangential cells (LPTCs) synapse with optic flow-sensitive descending neurons, which in turn project to areas that control neck, wing and leg movements. As the descending neurons play a role in sensorimotor transformation, it is important to understand their spatio-temporal response properties. Recent work shows that a relatively fast and efficient way to quantify such response properties is to use m-sequences or other white noise techniques. Therefore, here we used m-sequences to quantify the impulse responses of optic flow-sensitive descending neurons in male Eristalis tenax hoverflies. We focused on roll impulse responses as hoverflies perform exquisite head roll stabilizing reflexes, and the descending neurons respond particularly well to roll. We found that the roll impulse responses were fast, peaking after 16.5-18.0 ms. This is similar to the impulse response time to peak (18.3 ms) to widefield horizontal motion recorded in hoverfly LPTCs. We found that the roll impulse response amplitude scaled with the size of the stimulus impulse, and that its shape could be affected by the addition of constant velocity roll or lift. For example, the roll impulse response became faster and stronger with the addition of excitatory stimuli, and vice versa. We also found that the roll impulse response had a long return to baseline, which was significantly and substantially reduced by the addition of either roll or lift., Competing Interests: Competing interests The authors declare no competing or financial interests., (© 2021. Published by The Company of Biologists Ltd.)

Published

2021

7. Efference copies: Context matters when ignoring self-induced motion.

Author

Nicholas S and Nordström K

Subjects

Animals, Neurons physiology

Abstract

Across the animal kingdom, efference copies of neuronal motor commands are used to ensure our senses ignore stimuli generated by our own actions. New work shows that the underlying motivation for an action affects whether visual neurons are responsive to self-generated stimuli., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

8. Facilitation of neural responses to targets moving against optic flow.

Author

Nicholas S and Nordström K

Subjects

Animals, Diptera genetics, Insecta physiology, Motion Perception physiology, Vision, Ocular physiology, Visual Perception physiology, Diptera physiology, Neurons physiology, Optic Flow physiology

Abstract

For the human observer, it can be difficult to follow the motion of small objects, especially when they move against background clutter. In contrast, insects efficiently do this, as evidenced by their ability to capture prey, pursue conspecifics, or defend territories, even in highly textured surrounds. We here recorded from target selective descending neurons (TSDNs), which likely subserve these impressive behaviors. To simulate the type of optic flow that would be generated by the pursuer's own movements through the world, we used the motion of a perspective corrected sparse dot field. We show that hoverfly TSDN responses to target motion are suppressed when such optic flow moves syn-directional to the target. Indeed, neural responses are strongly suppressed when targets move over either translational sideslip or rotational yaw. More strikingly, we show that TSDNs are facilitated by optic flow moving counterdirectional to the target, if the target moves horizontally. Furthermore, we show that a small, frontal spatial window of optic flow is enough to fully facilitate or suppress TSDN responses to target motion. We argue that such TSDN response facilitation could be beneficial in modulating corrective turns during target pursuit., Competing Interests: The authors declare no competing interest., (Copyright © 2021 the Author(s). Published by PNAS.)

Published

2021

9. Karin Nordström.

Author

Nordström K

Subjects

Animals, Diptera physiology, Faculty, Female, Humans, Locomotion physiology, Universities, Vision, Ocular physiology, Biology, Research Personnel

Abstract

Interview with Karin Nordström, who studies hoverfly motion vision at Flinders University., (Copyright © 2020.)

Published

2021

10. Persistent Firing and Adaptation in Optic-Flow-Sensitive Descending Neurons.

Author

Nicholas S and Nordström K

Subjects

Animals, Behavior, Animal physiology, Calcium Signaling physiology, Optic Lobe, Nonmammalian physiology, Adaptation, Ocular physiology, Diptera physiology, Motion Perception physiology, Optic Flow physiology, Photic Stimulation, Sensory Receptor Cells physiology, Visual Cortex physiology, Visual Perception physiology

Abstract

A general principle of sensory systems is that they adapt to prolonged stimulation by reducing their response over time. Indeed, in many visual systems, including higher-order motion sensitive neurons in the fly optic lobes and the mammalian visual cortex, a reduction in neural activity following prolonged stimulation occurs. In contrast to this phenomenon, the response of the motor system controlling flight maneuvers persists following the offset of visual motion. It has been suggested that this gap is caused by a lingering calcium signal in the output synapses of fly optic lobe neurons. However, whether this directly affects the responses of the post-synaptic descending neurons, leading to the observed behavioral output, is not known. We use extracellular electrophysiology to record from optic-flow-sensitive descending neurons in response to prolonged wide-field stimulation. We find that, as opposed to most sensory and visual neurons, and in particular to the motion vision sensitive neurons in the brains of both flies and mammals, the descending neurons show little adaption during stimulus motion. In addition, we find that the optic-flow-sensitive descending neurons display persistent firing, or an after-effect, following the cessation of visual stimulation, consistent with the lingering calcium signal hypothesis. However, if the difference in after-effect is compensated for, subsequent presentation of stimuli in a test-adapt-test paradigm reveals adaptation to visual motion. Our results thus show a combination of adaptation and persistent firing in the neurons that project to the thoracic ganglia and thereby control behavioral output., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2020 The Author(s). Published by Elsevier Inc. All rights reserved.)

Published

2020

11. Visual motion sensitivity in descending neurons in the hoverfly.

Author

Nicholas S, Leibbrandt R, and Nordström K

Subjects

Animals, Brain cytology, Diptera cytology, Optic Flow, Optic Lobe, Nonmammalian cytology, Phenotype, Photic Stimulation, Visual Pathways physiology, Brain physiology, Diptera physiology, Motion Perception, Neurons physiology, Optic Lobe, Nonmammalian physiology, Vision, Ocular

Abstract

Many animals use motion vision information to control dynamic behaviors. For example, flying insects must decide whether to pursue a prey or not, to avoid a predator, to maintain their current flight trajectory, or to land. The neural mechanisms underlying the computation of visual motion have been particularly well investigated in the fly optic lobes. However, the descending neurons, which connect the optic lobes with the motor command centers of the ventral nerve cord, remain less studied. To address this deficiency, we describe motion vision sensitive descending neurons in the hoverfly Eristalis tenax. We describe how the neurons can be identified based on their receptive field properties, and how they respond to moving targets, looming stimuli and to widefield optic flow. We discuss their similarities with previously published visual neurons, in the optic lobes and ventral nerve cord, and suggest that they can be classified as target-selective, looming sensitive and optic flow sensitive, based on these similarities. Our results highlight the importance of using several visual stimuli as the neurons can rarely be identified based on only one response characteristic. In addition, they provide an understanding of the neurophysiology of visual neurons that are likely to affect behavior.

Published

2020

12. Insect Vision: Novel Mechanism for Contrast Constancy in Dim Light.

Author

Fabian J, Nordström K, and Ogawa Y

Subjects

Animals, Insecta, Vision, Ocular

Abstract

A general problem of sensory systems is how to simultaneously encode prevailing input as well as deviations from this baseline. A new study shows how the fly visual system has solved this by using parallel processing., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2020

13. Acute sleep loss induces signs of visual discomfort in young men.

Author

Dyakova O, Rångtell FH, Tan X, Nordström K, and Benedict C

Subjects

Adult, Cross-Over Studies, Humans, Male, Pilot Projects, Sleep Deprivation diagnosis, Young Adult, Emotions physiology, Photic Stimulation methods, Sleep Deprivation psychology, Visual Perception physiology

Abstract

Acute sleep loss influences visual processes in humans, such as recognizing facial emotions. However, to the best of our knowledge, no study till date has examined whether acute sleep loss alters visual comfort when looking at images. One image statistic that can be used to investigate the level of visual comfort experienced under visual encoding is the slope of the amplitude spectrum, also referred to as the slope constant. The slope constant describes the spatial distribution of pixel intensities and deviations from the natural slope constant can induce visual discomfort. In the present counterbalanced crossover design study, 11 young men with normal or corrected-to-normal vision participated in two experimental conditions: one night of sleep loss and one night of sleep. In the morning after each intervention, subjects performed a computerized psychophysics task. Specifically, they were required to adjust the slope constant of images depicting natural landscapes and close-ups with a randomly chosen initial slope constant until they perceived each image as most natural looking. Subjects also rated the pleasantness of each selected image. Our analysis showed that following sleep loss, higher slope constants were perceived as most natural looking when viewing images of natural landscapes. Images with a higher slope constant are generally perceived as blurrier. The selected images were also rated as less pleasant after sleep loss. No such differences between the experimental conditions were noted for images of close-ups. The results suggest that sleep loss induces signs of visual discomfort in young men. Possible implications of these findings are discussed., (© 2019 The Authors. Journal of Sleep Research published by John Wiley & Sons Ltd on behalf of European Sleep Research Society.)

Published

2019

14. Image statistics of the environment surrounding freely behaving hoverflies.

Author

Dyakova O, Müller MM, Egelhaaf M, and Nordström K

Subjects

Animals, Behavior, Animal physiology, Flight, Animal physiology, Diptera physiology, Visual Perception physiology

Abstract

Natural scenes are not as random as they might appear, but are constrained in both space and time. The 2-dimensional spatial constraints can be described by quantifying the image statistics of photographs. Human observers perceive images with naturalistic image statistics as more pleasant to view, and both fly and vertebrate peripheral and higher order visual neurons are tuned to naturalistic image statistics. However, for a given animal, what is natural differs depending on the behavior, and even if we have a broad understanding of image statistics, we know less about the scenes relevant for particular behaviors. To mitigate this, we here investigate the image statistics surrounding Episyrphus balteatus hoverflies, where the males hover in sun shafts created by surrounding trees, producing a rich and dense background texture and also intricate shadow patterns on the ground. We quantified the image statistics of photographs of the ground and the surrounding panorama, as the ventral and lateral visual field is particularly important for visual flight control, and found differences in spatial statistics in photos where the hoverflies were hovering compared to where they were flying. Our results can, in the future, be used to create more naturalistic stimuli for experimenter-controlled experiments in the laboratory.

Published

2019

15. A scoping review of empirical evidence on the impacts of the DRG introduction in Germany and Switzerland.

Author

Koné I, Maria Zimmermann B, Nordström K, Simone Elger B, and Wangmo T

Subjects

Economics, Hospital, Germany, Switzerland, Diagnosis-Related Groups, Empirical Research, Reimbursement Mechanisms

Abstract

Context: Germany and Switzerland have introduced diagnosis-related groups (DRGs) for hospital reimbursement. This scoping review aims to evaluate if empirical evidence exists on the effect of the DRG introduction., Methods: Medline via PubMed, Embase (Elsevier), CINAHL, PsychINFO, and Psyndex were systematically screened for studies from 2003 onwards using keywords-DRG, prospective payment system, and lump sum-in English, German, and French. Abstracts were screened for alignment with our inclusion criteria and classified as editorial/commentary, review, or empirical study. The full-text extraction included data on country, study design, collected data, study population, specialty, comparison group, and outcome measures., Results: Our literature search yielded 1944 references, of which 1405 references were included in the abstract screening after removal of duplicates. 135 articles were relevant to DRG, including 94 editorials/comments/reviews and 41 empirical articles from 36 different samples. The most frequently used outcome parameters were length of stay (12), reimbursement/cost (9), and case numbers (9)., Conclusions: Only a minority of identified articles (30.4%; 41 of 135) presented empirical data. This indicates that discussion on the topic is not totally evidence-based. The only common trend was a decrease in length of stay., (© 2018 John Wiley & Sons, Ltd.)

Published

2019

16. Integration of Small- and Wide-Field Visual Features in Target-Selective Descending Neurons of both Predatory and Nonpredatory Dipterans.

Author

Nicholas S, Supple J, Leibbrandt R, Gonzalez-Bellido PT, and Nordström K

Subjects

Animals, Diptera, Female, Male, Odonata, Species Specificity, Motion Perception physiology, Neurons physiology, Optic Lobe, Nonmammalian physiology, Photic Stimulation methods, Predatory Behavior physiology, Visual Fields physiology

Abstract

For many animals, target motion carries high ecological significance as this may be generated by a predator, prey, or potential mate. Indeed, animals whose survival depends on early target detection are often equipped with a sharply tuned visual system, yielding robust performance in challenging conditions. For example, many fast-flying insects use visual cues for identifying targets, such as prey (e.g., predatory dragonflies and robberflies) or conspecifics (e.g., nonpredatory hoverflies), and can often do so against self-generated background optic flow. Supporting these behaviors, the optic lobes of insects that pursue targets harbor neurons that respond robustly to the motion of small moving objects, even when displayed against syn-directional background clutter. However, in diptera, the encoding of target information by the descending neurons, which are more directly involved in generating the behavioral output, has received less attention. We characterized target-selective neurons by recording in the ventral nerve cord of male and female predatory Holcocephala fusca robberflies and of male nonpredatory Eristalis tenax hoverflies. We show that both species have dipteran target-selective descending neurons that only respond to target motion if the background is stationary or moving slowly, moves in the opposite direction, or has un-naturalistic spatial characteristics. The response to the target is suppressed when background and target move at similar velocities, which is strikingly different to the response of target neurons in the optic lobes. As the neurons we recorded from are premotor, our findings affect our interpretation of the neurophysiology underlying target-tracking behaviors. SIGNIFICANCE STATEMENT Many animals use sensory cues to detect moving targets that may represent predators, prey, or conspecifics. For example, birds of prey show superb sensitivity to the motion of small prey, and intercept these at high speeds. In a similar manner, predatory insects visually track moving prey, often against cluttered backgrounds. Accompanying this behavior, the brains of insects that pursue targets contain neurons that respond exclusively to target motion. We here show that dipteran insects also have target-selective descending neurons in the part of their nervous system that corresponds to the vertebrate spinal cord. Surprisingly, and in contrast to the neurons in the brain, these premotor neurons are inhibited by background patterns moving in the same direction as the target., (Copyright © 2018 Nicholas, Supple et al.)

Published

2018

17. Caring for elder patients: Mutual vulnerabilities in professional ethics.

Author

Nordström K and Wangmo T

Subjects

Adult, Aged, Ambulatory Care, Elder Abuse, Female, Homes for the Aged, Humans, Male, Middle Aged, Nursing Homes, Nursing Staff statistics & numerical data, Qualitative Research, Quality of Health Care, Switzerland, Young Adult, Geriatric Nursing ethics, Nurse-Patient Relations ethics, Nursing Staff psychology, Vulnerable Populations

Abstract

Background:: Neglect and abuse of elders in care institutions is a recurring issue in the media. Elders in care institutions are vulnerable due to their physical, cognitive, and verbal limitations. Such vulnerabilities may make them more susceptible to mistreatment by caregivers on whom they are heavily dependent., Objectives:: The goal was to understand caregivers' concerns about ensuring correct and proper treatment, as well as their experiences with neglect and abuse of older patients. This article examines resources and challenges of professional ethics within the care setting., Research Design:: A study was conducted to explore the quality of care provided to older patients in nursing homes, geriatrics institutions, and ambulant care in the northwest region of Switzerland., Participants and Research Context:: A total of 23 semi-structured interviews were conducted with nursing staff of varying experience levels., Ethical Considerations:: Ethical approval was granted by the competent regional ethics commission, Ethikkomission Nordwest-und Zentralschweiz EKNZ [Ethics Commission Northwest and Central Switzerland] (2014-015)., Findings:: Three themes emerged from our data analysis: professional identity, professional context, and professional relationships. Our findings indicate mutual vulnerabilities within these three themes, characterizing the interactions between nursing staff and older patients. Study participants believe that incidences of error, neglect, and abuse are consequences of their own vulnerability since they are not able to meet the demands of an overstraining work situation., Discussion:: Different aspects of this mutual vulnerability are described and critically discussed as challenges for professional ethics., Conclusion:: Early education, continuous training as well as better management and response from the institution are necessary to maintain professionalism while handling mutual vulnerabilities.

Published

2018

18. Visual approach computation in feeding hoverflies.

Author

Thyselius M, Gonzalez-Bellido PT, Wardill TJ, and Nordström K

Subjects

Animals, Bees, Female, Flight, Animal, Flowers, Predatory Behavior, Video Recording, Wasps, Diptera physiology, Feeding Behavior, Vision, Ocular

Abstract

On warm sunny days, female hoverflies are often observed feeding from a wide range of wild and cultivated flowers. In doing so, hoverflies serve a vital role as alternative pollinators, and are suggested to be the most important pollinators after bees and bumblebees. Unless the flower hoverflies are feeding from is large, they do not readily share the space with other insects, but instead opt to leave if another insect approaches. We used high-speed videography followed by 3D reconstruction of flight trajectories to quantify how female Eristalis hoverflies respond to approaching bees, wasps and two different hoverfly species. We found that, in 94% of the interactions, the occupant female left the flower when approached by another insect. We found that compared with spontaneous take-offs, the occupant hoverfly's escape response was performed at ∼3 times higher speed (spontaneous take-off at 0.2±0.05 m s -1 compared with 0.55±0.08 m s -1 when approached by another Eristalis ). The hoverflies tended to take off upward and forward, while taking the incomer's approach angle into account. Intriguingly, we found that, when approached by wasps, the occupant Eristalis took off at a higher speed and when the wasp was further away. This suggests that feeding hoverflies may be able to distinguish these predators, demanding impressive visual capabilities. Our results, including quantification of the visual information available before occupant take-off, provide important insight into how freely behaving hoverflies perform escape responses from competitors and predators (e.g. wasps) in the wild., Competing Interests: Competing interestsThe authors declare no competing or financial interests., (© 2018. Published by The Company of Biologists Ltd.)

Published

2018

19. Rearing and Long-Term Maintenance of Eristalis tenax Hoverflies for Research Studies.

Author

Nicholas S, Thyselius M, Holden M, and Nordström K

Subjects

Animals, Research Design, Diptera genetics, Insecta genetics, Polymers metabolism

Abstract

With an estimated 6000 species worldwide, hoverflies are ecologically important as alternative pollinators to domesticated honeybees. However, they are also a useful scientific model to study motion vision and flight dynamics in a controlled laboratory setting. As the larvae develop in organically polluted water, they are useful models for investigating investment in microbial immunity. While large scale commercial breeding for agriculture already occurs, there are no standardized protocols for maintaining captive populations for scientific studies. This is important as commercial captive breeding programs focusing on mass output during peak pollination periods may fail to provide a population that is consistent, stable and robust throughout the year, as is often needed for other research purposes. Therefore, a method to establish, maintain and refresh a captive research population is required. Here, we describe the utilization of an artificial hibernation cycle, in addition to the nutritional and housing requirements, for long term maintenance of Eristalis tenax. Using these methods, we have significantly increased the health and longevity of captive populations of E. tenax compared to previous reports. We furthermore discuss small scale rearing methods and options for optimizing yields and manipulating population demographics.

Published

2018

20. In situ modeling of multimodal floral cues attracting wild pollinators across environments.

Author

Nordström K, Dahlbom J, Pragadheesh VS, Ghosh S, Olsson A, Dyakova O, Suresh SK, and Olsson SB

Subjects

Animals, Cues, Rhododendron physiology, Diptera physiology, Environment, Flowers physiology, Models, Biological, Pollination

Abstract

With more than 80% of flowering plant species specialized for animal pollination, understanding how wild pollinators utilize resources across environments can encourage efficient planting and maintenance strategies to maximize pollination and establish resilience in the face of environmental change. A fundamental question is how generalist pollinators recognize "flower objects" in vastly different ecologies and environments. On one hand, pollinators could employ a specific set of floral cues regardless of environment. Alternatively, wild pollinators could recognize an exclusive signature of cues unique to each environment or flower species. Hoverflies, which are found across the globe, are one of the most ecologically important alternative pollinators after bees and bumblebees. Here, we have exploited their cosmopolitan status to understand how wild pollinator preferences change across different continents. Without employing any a priori assumptions concerning the floral cues, we measured, predicted, and finally artificially recreated multimodal cues from individual flowers visited by hoverflies in three different environments (hemiboreal, alpine, and tropical) using a field-based methodology. We found that although "flower signatures" were unique for each environment, some multimodal lures were ubiquitously attractive, despite not carrying any reward, or resembling real flowers. While it was unexpected that cue combinations found in real flowers were not necessary, the robustness of our lures across insect species and ecologies could reflect a general strategy of resource identification for generalist pollinators. Our results provide insights into how cosmopolitan pollinators such as hoverflies identify flowers and offer specific ecologically based cues and strategies for attracting pollinators across diverse environments., Competing Interests: The authors declare no conflict of interest., (Copyright © 2017 the Author(s). Published by PNAS.)

Published

2017

21. Image statistics and their processing in insect vision.

Author

Dyakova O and Nordström K

Subjects

Animals, Insecta physiology, Neurophysiology methods, Vision, Ocular, Visual Perception

Abstract

Natural scenes may appear random, but are not only constrained in space and time, but also show strong spatial and temporal correlations. Spatial constraints and correlations can be described by quantifying image statistics, which include intuitive measures such as contrast, color and luminance, but also parameters that need some type of transformation of the image. In this review we will discuss some common tools used to quantify spatial and temporal parameters of naturalistic visual input, and how these tools have been used to inform us about visual processing in insects. In particular, we will review findings that would not have been possible using conventional, experimenter defined stimuli., (Copyright © 2017 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2017

22. Preventing elder abuse and neglect in geriatric institutions: Solutions from nursing care providers.

Author

Wangmo T, Nordström K, and Kressig RW

Subjects

Adult, Aged, Female, Humans, Male, Quality of Health Care, Switzerland, Elder Abuse prevention & control, Nursing Homes, Nursing Staff education, Problem Solving

Abstract

This study explores how and why abuse and neglect occurs in geriatric institutions and presents practical prevention measures. Exploratory qualitative interviews were carried out with purposive sample of 23 nursing staff members. They were recruited from different institutions caring for older patients in the north-western region of Switzerland. These interviews were analyzed using thematic analysis. Participating nursing staff members reported several factors pertaining to the care provider, the older patient, and the institution that precipitated abuse and neglect. They mentioned different solutions that could help them address their responsibilities in a reasonable manner. The solutions included, for example, ensuring proper education and training, better management nursing care provider's responsibilities and timely intervention to address abuse and neglect, as well as rotating care provider. Implementing these suggestions will allow geriatric institutions, its managers, and nursing care providers to improve quality of care and reduce such negative occurrences in these settings., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published

2017

23. Factors Affecting Women's Autonomous Decision Making In Research Participation Amongst Yoruba Women Of Western Nigeria.

Author

Princewill CW, Jegede AS, Nordström K, Lanre-Abass B, and Elger BS

Subjects

Biomedical Research, Female, Humans, Interviews as Topic, Male, Nigeria, Power, Psychological, Qualitative Research, Culture, Decision Making, Family Characteristics, Personal Autonomy, Spouses psychology

Abstract

Research is a global enterprise requiring participation of both genders for generalizable knowledge; advancement of science and evidence based medical treatment. Participation of women in research is necessary to reduce the current bias that most empirical evidence is obtained from studies with men to inform health care and related policy interventions. Various factors are assumed to limit autonomy amongst the Yoruba women of western Nigeria. This paper seeks to explore the experience and understanding of autonomy by the Yoruba women in relation to research participation. Focus is on factors that affect women's autonomous decision making in research participation. An exploratory qualitative approach comprising four focus group discussions, 42 in-depth interviews and 14 key informant interviews was used. The study permits a significant amount of triangulation, as opinions of husbands and religious leaders are also explored. Interviews and discussions were audiotaped and transcribed verbatim. Content analysis was employed for data analysis. Findings show that concepts of autonomy varied amongst the Yoruba women. Patriarchy, religion and culture are conceived to have negative impact on the autonomy of women in respect to research participation. Among the important findings are: 1) male dominance is strongly emphasized by religious leaders who should teach equality, 2) while men feel that by making decisions for women, they are protecting them, the women on the other hand see this protection as a way of limiting their autonomy. We recommend further studies to develop culturally appropriate and workable recruitment methods to increase women's participation in research., (© 2016 John Wiley & Sons Ltd.)

Published

2017

24. A Novel Interception Strategy in a Miniature Robber Fly with Extreme Visual Acuity.

Author

Wardill TJ, Fabian ST, Pettigrew AC, Stavenga DG, Nordström K, and Gonzalez-Bellido PT

Subjects

Animals, Psychomotor Performance, Diptera physiology, Motion Perception, Visual Acuity

Abstract

Our visual system allows us to rapidly identify and intercept a moving object. When this object is far away, we base the trajectory on the target's location relative to an external frame of reference [1]. This process forms the basis for the constant bearing angle (CBA) model, a reactive strategy that ensures interception since the bearing angle, formed between the line joining pursuer and target (called the range vector) and an external reference line, is held constant [2-4]. The CBA model may be a fundamental and widespread strategy, as it is also known to explain the interception trajectories of bats and fish [5, 6]. Here, we show that the aerial attack of the tiny robber fly Holcocephala fusca is consistent with the CBA model. In addition, Holcocephala fusca displays a novel proactive strategy, termed "lock-on" phase, embedded with the later part of the flight. We found the object detection threshold for this species to be 0.13°, enabled by an extremely specialized, forward pointing fovea (∼5 ommatidia wide, interommatidial angle Δφ = 0.28°, photoreceptor acceptance angle Δρ = 0.27°). This study furthers our understanding of the accurate performance that a miniature brain can achieve in highly demanding sensorimotor tasks and suggests the presence of equivalent mechanisms for target interception across a wide range of taxa. VIDEO ABSTRACT., (Copyright © 2017 The Author(s). Published by Elsevier Ltd.. All rights reserved.)

Published

2017

25. Target detection in insects: optical, neural and behavioral optimizations.

Author

Gonzalez-Bellido PT, Fabian ST, and Nordström K

Subjects

Animals, Motion Perception physiology, Neurons physiology, Vision, Ocular physiology, Behavior, Animal physiology, Insecta physiology

Abstract

Motion vision provides important cues for many tasks. Flying insects, for example, may pursue small, fast moving targets for mating or feeding purposes, even when these are detected against self-generated optic flow. Since insects are small, with size-constrained eyes and brains, they have evolved to optimize their optical, neural and behavioral target visualization solutions. Indeed, even if evolutionarily distant insects display different pursuit strategies, target neuron physiology is strikingly similar. Furthermore, the coarse spatial resolution of the insect compound eye might actually be beneficial when it comes to detection of moving targets. In conclusion, tiny insects show higher than expected performance in target visualization tasks., (Copyright © 2016 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published

2016

26. Sickness absence in workplaces: Does it reflect a healthy hire effect?

Author

Nordström K, Hemmingsson T, Ekberg K, and Johansson G

Subjects

Adolescent, Adult, Female, Follow-Up Studies, Humans, Male, Middle Aged, Odds Ratio, Sweden, Young Adult, Absenteeism, Employment organization & administration, Health Status, Personnel Selection methods, Sick Leave statistics & numerical data, Workplace organization & administration

Abstract

Objectives: Sickness absence in workplaces may reflect working conditions. It may also reflect a "healthy hire effect," i.e., that workplaces recruit individuals with experience of sickness absence differently. The purpose of the study was to determine if a history of sickness absence among recruits is associated with the average level of sickness absence in workplaces., Material and Methods: In a register-based follow-up study, Swedish workplaces with at least 5 employees in 2006 were selected (approximately 127 000 workplaces with 3.9 million employees). The workplaces were categorized according to the average workplace sickness absence in 2006 and the recruits were categorized according to the individual sickness absence in 2005. The workplaces with a high average level of sickness absence were more likely than those with a low level to hire employees with high sickness absence in the year preceding employment: men - odds ratio (OR) = 7.2, 95% confidence interval (CI): 6.6-7.8, women - OR = 7.5, 95% CI: 6.9-8.1., Results: The results show that there is a greater likelihood of employing individuals with high levels of sickness absence in the workplaces with many days of the average sickness absence than in the workplaces with few days of the average sickness absence., Conclusions: The results suggest that sickness absence in workplaces may reflect a healthy hire effect., (This work is available in Open Access model and licensed under a CC BY-NC 3.0 PL license.)

Published

2016

27. Hoverfly locomotor activity is resilient to external influence and intrinsic factors.

Author

Thyselius M and Nordström K

Subjects

Actigraphy, Adaptation, Physiological, Animals, Female, Male, Photic Stimulation, Photoperiod, Social Behavior, Starvation physiopathology, Aging physiology, Diet, Diptera physiology, Light, Motor Activity physiology, Sex Characteristics

Abstract

Hoverflies are found across the globe, with approximately 6000 species described worldwide. Many hoverflies are being used in agriculture and some are emerging as model species for laboratory experiments. As such it is valuable to know more about their activity. Like many other dipteran flies, Eristalis hoverflies have been suggested to be strongly diurnal, but this is based on qualitative visualization by human observers. To quantify how hoverfly activity depends on internal and external factors, we here utilize a locomotor activity monitoring system. We show that Eristalis hoverflies are active during the entire light period when exposed to a 12 h light:12 h dark cycle, with a lower activity if exposed to light during the night. We show that the hoverflies' locomotor activity is stable over their lifetime and that it does not depend on the diet provided. Surprisingly, we find no difference in activity between males and females, but the activity is significantly affected by the sex of an accompanying conspecific. Finally, we show that female hoverflies are more resilient to starvation than males. In summary, Eristalis hoverflies are resilient to a range of internal and external factors, supporting their use in long-term laboratory experiments.

Published

2016

28. A higher order visual neuron tuned to the spatial amplitude spectra of natural scenes.

Author

Dyakova O, Lee YJ, Longden KD, Kiselev VG, and Nordström K

Subjects

Animals, Fourier Analysis, Photic Stimulation, Visual Cortex physiology, Visual Perception physiology, Diptera physiology, Motion Perception physiology, Neurons physiology, Space Perception physiology

Abstract

Animal sensory systems are optimally adapted to those features typically encountered in natural surrounds, thus allowing neurons with limited bandwidth to encode challengingly large input ranges. Natural scenes are not random, and peripheral visual systems in vertebrates and insects have evolved to respond efficiently to their typical spatial statistics. The mammalian visual cortex is also tuned to natural spatial statistics, but less is known about coding in higher order neurons in insects. To redress this we here record intracellularly from a higher order visual neuron in the hoverfly. We show that the cSIFE neuron, which is inhibited by stationary images, is maximally inhibited when the slope constant of the amplitude spectrum is close to the mean in natural scenes. The behavioural optomotor response is also strongest to images with naturalistic image statistics. Our results thus reveal a close coupling between the inherent statistics of natural scenes and higher order visual processing in insects.

Published

2015

29. The Killer Fly Hunger Games: Target Size and Speed Predict Decision to Pursuit.

Author

Wardill TJ, Knowles K, Barlow L, Tapia G, Nordström K, Olberg RM, and Gonzalez-Bellido PT

Subjects

Animals, Photic Stimulation, Probability, Time Factors, Time Perception, Video Recording, Decision Making physiology, Insecta physiology, Predatory Behavior physiology, Size Perception physiology, Spatial Behavior

Abstract

Predatory animals have evolved to optimally detect their prey using exquisite sensory systems such as vision, olfaction and hearing. It may not be so surprising that vertebrates, with large central nervous systems, excel at predatory behaviors. More striking is the fact that many tiny insects, with their miniscule brains and scaled down nerve cords, are also ferocious, highly successful predators. For predation, it is important to determine whether a prey is suitable before initiating pursuit. This is paramount since pursuing a prey that is too large to capture, subdue or dispatch will generate a substantial metabolic cost (in the form of muscle output) without any chance of metabolic gain (in the form of food). In addition, during all pursuits, the predator breaks its potential camouflage and thus runs the risk of becoming prey itself. Many insects use their eyes to initially detect and subsequently pursue prey. Dragonflies, which are extremely efficient predators, therefore have huge eyes with relatively high spatial resolution that allow efficient prey size estimation before initiating pursuit. However, much smaller insects, such as killer flies, also visualize and successfully pursue prey. This is an impressive behavior since the small size of the killer fly naturally limits the neural capacity and also the spatial resolution provided by the compound eye. Despite this, we here show that killer flies efficiently pursue natural (Drosophila melanogaster) and artificial (beads) prey. The natural pursuits are initiated at a distance of 7.9 ± 2.9 cm, which we show is too far away to allow for distance estimation using binocular disparities. Moreover, we show that rather than estimating absolute prey size prior to launching the attack, as dragonflies do, killer flies attack with high probability when the ratio of the prey's subtended retinal velocity and retinal size is 0.37. We also show that killer flies will respond to a stimulus of an angular size that is smaller than that of the photoreceptor acceptance angle, and that the predatory response is strongly modulated by the metabolic state. Our data thus provide an exciting example of a loosely designed matched filter to Drosophila, but one which will still generate successful pursuits of other suitable prey., (© 2015 The Author(s) Published by S. Karger AG, Basel.)

Published

2015

30. Spatio-temporal dynamics of impulse responses to figure motion in optic flow neurons.

Author

Lee YJ, Jönsson HO, and Nordström K

Subjects

Acoustic Stimulation, Animals, Female, Male, Motion Perception physiology, Neurons cytology, Optic Flow physiology, Pattern Recognition, Visual physiology, Diptera physiology, Neurons physiology

Abstract

White noise techniques have been used widely to investigate sensory systems in both vertebrates and invertebrates. White noise stimuli are powerful in their ability to rapidly generate data that help the experimenter decipher the spatio-temporal dynamics of neural and behavioral responses. One type of white noise stimuli, maximal length shift register sequences (m-sequences), have recently become particularly popular for extracting response kernels in insect motion vision. We here use such m-sequences to extract the impulse responses to figure motion in hoverfly lobula plate tangential cells (LPTCs). Figure motion is behaviorally important and many visually guided animals orient towards salient features in the surround. We show that LPTCs respond robustly to figure motion in the receptive field. The impulse response is scaled down in amplitude when the figure size is reduced, but its time course remains unaltered. However, a low contrast stimulus generates a slower response with a significantly longer time-to-peak and half-width. Impulse responses in females have a slower time-to-peak than males, but are otherwise similar. Finally we show that the shapes of the impulse response to a figure and a widefield stimulus are very similar, suggesting that the figure response could be coded by the same input as the widefield response.

Published

2015

31. Identification of the Reichardt elementary motion detector model.

Author

Hidayat E, Medvedev A, and Nordström K

Subjects

Animals, Diptera physiology, Humans, Motion, Photic Stimulation, Spatial Navigation physiology, Visual Perception physiology, Algorithms, Models, Neurological, Motion Perception physiology, Neurons physiology

Abstract

The classical Hassenstein-Reichardt mathematical elementary motion detector (EMD) model is treated analytically. The EMD is stimulated with drifting sinusoidal gratings, which are often used in motion vision research, thus enabling direct comparison with neural responses from motion-sensitive neurones in the fly brain. When sinusoidal gratings are displayed on a cathode ray tube monitor, they are modulated by the refresh rate of the monitor. This generates a pulsatile signature of the visual stimulus, which is also seen in the neural response. Such pulsatile signals make a Laguerre domain identification method for estimating the parameters of a single EMD suitable, allowing estimation of both finite and infinite-dimensional dynamics. To model the response of motion-sensitive neurones with large receptive fields, a pool of spatially distributed EMDs is considered, with the weights of the contributing EMDs fitted to the neural data by a sparse estimation method. Such an EMD-array is more reliably estimated by stimulating with multiple sinusoidal gratings, since these provide higher spatial excitation than a single sinusoidal grating. Consequently, a way of designing the visual stimuli for a certain order of spatial resolution is suggested.

Published

2015

32. Sick leave and the impact of job-to-job mobility on the likelihood of remaining on the labour market--a longitudinal Swedish register study.

Author

Nordström K, Ekberg K, Hemmingsson T, and Johansson G

Subjects

Adult, Cohort Studies, Educational Status, Female, Humans, Income statistics & numerical data, Longitudinal Studies, Male, Marital Status statistics & numerical data, Middle Aged, Multivariate Analysis, Odds Ratio, Probability, Rehabilitation, Vocational statistics & numerical data, Sweden, Women, Working statistics & numerical data, Young Adult, Employment statistics & numerical data, Personnel Turnover statistics & numerical data, Sick Leave statistics & numerical data

Abstract

Background: Change of job could be a strategy in vocational rehabilitation when return to the original job is not possible, but research is very limited concerning the effects of job mobility on the future vocational situation. The aim of the study was to investigate whether job-to-job mobility affects the likelihood of remaining on the labour market over time among persons who are employed and have experienced long-term sick leave., Methods: In a longitudinal register study, cohorts from three base years (1994, 1999 and 2004) were created, based on the Swedish population who were 20-60 years old, had sickness allowance insurance, and were employed in the base year and the following year (n>3,000,000). The likelihood that individuals on long-term sick leave were employed later depending on whether or not they changed workplace during the present or next year of long-term sick leave was analyzed using logistic regression analysis. Age, sector, industry, children, marital status, education, income, rate of sick leave and earlier sick leave and earlier mobility were taken into consideration., Results: Women with more than 180 days' sick leave who changed workplaces were more likely to have a job later compared with those who did not change jobs. For men, the association was statistically significant with 1994 and 2004 as base years, but not in the cohort from 1999., Conclusions: The present study indicates that for those on long-term sick leave that changed workplaces, the opportunities to stay on the labour market might increase. However, the study has methodological limitations and the results for men are ambiguous. We do not therefore have enough evidence for recommending job change as a strategy for vocational rehabilitation.

Published

2014

33. Invertebrate vision: peripheral adaptation to repeated object motion.

Author

Nordström K and Gonzalez-Bellido PT

Subjects

Animals, Behavior, Animal physiology, Brachyura physiology, Neuronal Plasticity, Neurons physiology, Optic Lobe, Nonmammalian cytology

Abstract

Visual systems adapt rapidly to objects moving repeatedly within the visual field, because such objects are likely irrelevant. In the crab, the neural switch for such adaptation has been found to take place at a surprisingly early stage of the visual processing pathway., (Copyright © 2013 Elsevier Ltd. All rights reserved.)

Published

2013

34. Food and health: individual, cultural, or scientific matters?

Author

Nordström K, Coff C, Jönsson H, Nordenfelt L, and Görman U

Abstract

In personalized nutrition, food is a tool for good health, implying an instrumental relationship between food and health. Food receives a secondary value, while health would appear to be a descriptive biological concept. This article gives an introduction to cultural understandings of food and health. The wider definition of food and health is explored in relation to the commonly used scientific approach that tends to take a more reductionist approach to food and health. The different discourses on food and health are being discussed in relation to ethical aspects of personalized nutrition. The success of personalized nutrition is likely dependent upon the ability to integrate the scientific approach with everyday cultural, emotional, ethical, and sensual understandings of food. Health theories can be divided into two principal rival types-biostatistical and holistic. Biostatistical focuses on survival, while holistic focuses on ability as a precondition for health. Arguments in favor of a holistic and individualistic theory of health and illness are presented. This implies a focus on the ability of the individual to realize his or her "vital goals." A holistic and individualistic health concept may have a reinforcing effect on the individualized approach in personalized nutrition. It allows focus on individual health premises and related dietary means of health promotion, as well as an individualized perspective on the objectives of health promotion. An individualistic notion of health also indicates that people with high levels of vital goals benefit more easily. To reach beyond these groups is likely difficult. This potential injustice should be balanced with global preventive medical programs.

Published

2013

35. Do we know enough? A scientific and ethical analysis of the basis for genetic-based personalized nutrition.

Author

Görman U, Mathers JC, Grimaldi KA, Ahlgren J, and Nordström K

Abstract

This article discusses the prospects and limitations of the scientific basis for offering personalized nutrition advice based upon individual genetic information. Two divergent scientific positions are presented, with an ethical comment. The crucial question is whether the current knowledge base is sufficiently strong for taking an ethically responsible decision to offer personalized nutrition advice based upon gene-diet-health interaction. According to the first position, the evidence base for translating the outcomes of nutrigenomics research into personalized nutritional advice is as yet immature. There is also limited evidence that genotype-based dietary advice will motivate appropriate behavior changes. Filling the gaps in our knowledge will require larger and better randomized controlled trials. According to the second position, personalized nutrition must be evaluated in relation to generally accepted standard dietary advice-partly derived from epidemiological observations and usually not proven by clinical trials. With personalized nutrition, we cannot demand stronger evidence. In several specific cases of gene-diet interaction, it may be more beneficial for individuals with specific genotypes to follow personalized advice rather than general dietary recommendations. The ethical comment, finally, considers the ethical aspects of deciding how to proceed in the face of such uncertainty. Two approaches for an ethically responsible way forward are proposed. Arguing from a precautionary approach, it is suggested that personalized dietary advice should be offered only when there is strong scientific evidence for health effects, followed by stepwise evaluation of unforeseen behavioral and psychological effects. Arguing from theoretical and applied ethics as well as psychology, it is also suggested that personalized advice should avoid paternalism and instead focus on supporting the autonomous choice of each person.

Published

2013

36. Values at stake: autonomy, responsibility, and trustworthiness in relation to genetic testing and personalized nutrition advice.

Author

Nordström K, Juth N, Kjellström S, Meijboom FL, and Görman U

Abstract

Personalized nutrition has the potential to enhance individual health control. It could be seen as a means to strengthen people's autonomy as they learn more about their personal health risks, and receive dietary advice accordingly. We examine in what sense personalized nutrition strengthens or weakens individual autonomy. The impact of personalized nutrition on autonomy is analyzed in relation to responsibility and trustworthiness. On a societal level, individualization of health promotion may be accompanied by the attribution of extended individual responsibility for one's health. This constitutes a dilemma of individualization, caused by a conflict between the right to individual freedom and societal interests. The extent to which personalized nutrition strengthens autonomy is consequently influenced by how responsibility for health is allocated to individuals. Ethically adequate allocation of responsibility should focus on prospective responsibility and be differentiated with regard to individual differences concerning the capacity of adults to take responsibility. The impact of personalized nutrition on autonomy also depends on its methodological design. Owing to the complexity of information received, personalized nutrition through genetic testing (PNTGT) is open to misinterpretation and may not facilitate informed choices and autonomy. As new technologies, personalized nutrition and PNTGT are subject to issues of trust. To strengthen autonomy, trust should be approached in terms of trustworthiness. Trustworthiness implies that an organization that develops or introduces personalized nutrition can show that it is competent to deal with both the technical and moral dimensions at stake and that its decisions are motivated by the interests and expectations of the truster.

Published

2013

37. Consumers on the Internet: ethical and legal aspects of commercialization of personalized nutrition.

Author

Ahlgren J, Nordgren A, Perrudin M, Ronteltap A, Savigny J, van Trijp H, Nordström K, and Görman U

Abstract

Consumers often have a positive attitude to the option of receiving personalized nutrition advice based upon genetic testing, since the prospect of enhancing or maintaining one's health can be perceived as empowering. Current direct-to-consumer services over the Internet, however, suffer from a questionable level of truthfulness and consumer protection, in addition to an imbalance between far-reaching promises and contrasting disclaimers. Psychological and behavioral studies indicate that consumer acceptance of a new technology is primarily explained by the end user's rational and emotional interpretation as well as moral beliefs. Results from such studies indicate that personalized nutrition must create true value for the consumer. Also, the freedom to choose is crucial for consumer acceptance. From an ethical point of view, consumer protection is crucial, and caution must be exercised when putting nutrigenomic-based tests and advice services on the market. Current Internet offerings appear to reveal a need to further guaranty legal certainty by ensuring privacy, consumer protection and safety. Personalized nutrition services are on the borderline between nutrition and medicine. Current regulation of this area is incomplete and undergoing development. This situation entails the necessity for carefully assessing and developing existing rules that safeguard fundamental rights and data protection while taking into account the sensitivity of data, the risks posed by each step in their processing, and sufficient guarantees for consumers against potential misuse.

Published

2013

38. Novel flicker-sensitive visual circuit neurons inhibited by stationary patterns.

Author

de Haan R, Lee YJ, and Nordström K

Subjects

Action Potentials, Animals, Diptera, Electrophysiology, Optic Flow, Photic Stimulation, Sensory Receptor Cells classification, Motion Perception physiology, Sensory Receptor Cells physiology, Visual Fields physiology, Visual Pathways cytology

Abstract

Many animals use visual motion cues for navigating within their surroundings. Both flies and vertebrates compute local motion by temporal correlation of neighboring photoreceptors, via so-called elementary motion detectors (EMDs). In the fly lobula plate and the vertebrate visual cortex the output from many EMDs is pooled in neurons sensitive to wide-field optic flow. Although the EMD has been the preferred model for more than 50 years, recent work has highlighted its limitations in describing some visual behaviors, such as responses to higher-order motion stimuli. Non-EMD motion processing may therefore serve an important function in vision. Here, we describe a novel neuron class in the fly lobula plate that clearly does not derive its input from classic EMDs. The centrifugal stationary inhibited flicker excited (cSIFE) neuron is strongly excited by flicker, up to very high temporal frequencies. The non-EMD driven flicker sensitivity leads to strong, nondirectional responses to high-speed, wide-field motion. Furthermore, cSIFE is strongly inhibited by stationary patterns, within a narrow wavelength band. cSIFE's outputs overlap with the inputs of well described optic flow-sensitive lobula plate tangential cells (LPTCs). Driving cSIFE affects the active dendrites of LPTCs, and cSIFE may therefore play a large role in motion vision.

Published

2013

39. [Necessary to strengthen care and research on mental illness].

Author

Flyckt L, Bergerlind LL, Nilsson G, Krakau I, Nordström KT, and Widäng K

Subjects

Biomedical Research, Humans, Sweden, Workforce, General Practice standards, Mental Disorders diagnosis, Mental Disorders therapy, Psychiatry standards

Published

2013

40. Robust prey detection in a small nervous system.

Author

Nordström K

Subjects

Animals, Flight, Animal physiology, Motion Perception physiology, Odonata physiology, Predatory Behavior physiology, Retinal Neurons physiology

Published

2013

41. Temporal and spatial adaptation of transient responses to local features.

Author

O'Carroll DC, Barnett PD, and Nordström K

Abstract

Interpreting visual motion within the natural environment is a challenging task, particularly considering that natural scenes vary enormously in brightness, contrast and spatial structure. The performance of current models for the detection of self-generated optic flow depends critically on these very parameters, but despite this, animals manage to successfully navigate within a broad range of scenes. Within global scenes local areas with more salient features are common. Recent work has highlighted the influence that local, salient features have on the encoding of optic flow, but it has been difficult to quantify how local transient responses affect responses to subsequent features and thus contribute to the global neural response. To investigate this in more detail we used experimenter-designed stimuli and recorded intracellularly from motion-sensitive neurons. We limited the stimulus to a small vertically elongated strip, to investigate local and global neural responses to pairs of local "doublet" features that were designed to interact with each other in the temporal and spatial domain. We show that the passage of a high-contrast doublet feature produces a complex transient response from local motion detectors consistent with predictions of a simple computational model. In the neuron, the passage of a high-contrast feature induces a local reduction in responses to subsequent low-contrast features. However, this neural contrast gain reduction appears to be recruited only when features stretch vertically (i.e., orthogonal to the direction of motion) across at least several aligned neighboring ommatidia. Horizontal displacement of the components of elongated features abolishes the local adaptation effect. It is thus likely that features in natural scenes with vertically aligned edges, such as tree trunks, recruit the greatest amount of response suppression. This property could emphasize the local responses to such features vs. those in nearby texture within the scene.

Published

2012

42. Octopaminergic modulation of contrast sensitivity.

Author

de Haan R, Lee YJ, and Nordström K

Abstract

Sensory systems adapt to prolonged stimulation by decreasing their response to continuous stimuli. Whereas visual motion adaptation has traditionally been studied in immobilized animals, recent work indicates that the animal's behavioral state influences the response properties of higher-order motion vision-sensitive neurons. During insect flight octopamine is released, and pharmacological octopaminergic activation can induce a fictive locomotor state. In the insect optic ganglia, lobula plate tangential cells (LPTCs) spatially pool input from local elementary motion detectors (EMDs) that correlate luminosity changes from two spatially discrete inputs after delaying the signal from one. The LPTC velocity optimum thereby depends on the spatial separation of the inputs and on the EMD's delay properties. Recently it was shown that behavioral activity increases the LPTC velocity optimum, with modeling suggesting this to originate in the EMD's temporal delay filters. However, behavior induces an additional post-EMD effect: the LPTC membrane conductance increases in flying flies. To physiologically investigate the degree to which activity causes presynaptic and postsynaptic effects, we conducted intracellular recordings of Eristalis horizontal system (HS) neurons. We constructed contrast response functions before and after adaptation at different temporal frequencies, with and without the octopamine receptor agonist chlordimeform (CDM). We extracted three motion adaptation components, where two are likely to be generated presynaptically of the LPTCs, and one within them. We found that CDM affected the early, EMD-associated contrast gain reduction, temporal frequency dependently. However, a CDM-induced change of the HS membrane conductance disappeared during and after visual stimulation. This suggests that physical activity mainly affects motion adaptation presynaptically of LPTCs, whereas post-EMD effects have a minimal effect.

Published

2012

43. Higher-order motion sensitivity in fly visual circuits.

Author

Lee YJ and Nordström K

Subjects

Animals, Cues, Electrophysiology, Female, Humans, Male, Models, Neurological, Motion, Neurons physiology, Photic Stimulation, Diptera physiology, Motion Perception physiology, Vision, Ocular physiology, Visual Pathways physiology

Abstract

In higher-order motion stimuli, the direction of object motion does not follow the direction of luminance change. Such stimuli could be generated by the wing movements of a flying butterfly and further complicated by its motion in and out of shadows. Human subjects readily perceive the direction of higher-order motion, although this stands in stark contrast to prevailing motion vision models. Flies and humans compute motion in similar ways, and because flies behaviorally track bars containing higher-order motion cues, they become an attractive model system for investigating the neurophysiology underlying higher-order motion sensitivity. We here use intracellular electrophysiology of motion-vision-sensitive neurons in the hoverfly lobula plate to quantify responses to stimuli containing higher-order motion. We show that motion sensitivity can be broken down into two separate streams, directionally coding for elementary motion and figure motion, respectively, and that responses to Fourier and theta motion can be predicted from these. The sensitivity is affected both by the stimulus' time course and by the neuron's underlying receptive field. Responses to preferred-direction theta motion are sexually dimorphic and particularly robust along the visual midline.

Published

2012

44. Neural specializations for small target detection in insects.

Author

Nordström K

Subjects

Animals, Behavior, Animal physiology, Brain physiology, Insecta physiology, Models, Neurological, Motion Perception physiology

Abstract

Despite being equipped with low-resolution eyes and tiny brains, many insects show exquisite abilities to detect and pursue targets even in highly textured surrounds. Target tracking behavior is subserved by neurons that are sharply tuned to the motion of small high-contrast targets. These neurons respond robustly to target motion, even against self-generated optic flow. A recent model, supported by neurophysiology, generates target selectivity by being sharply tuned to the unique spatiotemporal profile associated with target motion. Target neurons are likely connected in a complex network where some provide more direct output to behavior, whereas others serve an inter-regulatory role. These interactions may regulate attention and aid in the robust detection of targets in clutter observed in behavior., (Copyright © 2012 Elsevier Ltd. All rights reserved.)

Published

2012

45. Local and global responses of insect motion detectors to the spatial structure of natural scenes.

Author

O'Carroll DC, Barnett PD, and Nordström K

Subjects

Animals, Male, Signal Detection, Psychological, Diptera physiology, Models, Neurological, Motion Perception physiology, Neurons physiology, Pattern Recognition, Visual physiology

Abstract

As a consequence of the non-linear correlation mechanism underlying motion detection, the variability in local pattern structure and contrast inherent within natural scenes profoundly influences local motion responses. To accurately interpret optic flow induced by self-motion, neurons in many dipteran flies smooth this "pattern noise" by wide-field spatial integration. We investigated the role that size and shape of the receptive field plays in smoothing out pattern noise in two unusual hoverfly optic flow neurons: one (HSN) with an exceptionally small receptive field and one (HSNE) with a larger receptive field. We compared the local and global responses to a sequence of panoramic natural images in these two neurons with a parsimonious model for elementary motion detection weighted for their spatial receptive fields. Combined with manipulation of size and contrast of the stimulus images, this allowed us to separate spatial integration properties arising from the receptive field, from other local and global non-linearities, such as motion adaptation and dendritic gain control. We show that receptive field properties alone are poor predictors of the response to natural scenes. If anything, additional non-linearity enhances the pattern dependence of HSN's response, particularly to vertically elongated features, suggesting that it may serve a role in forward fixation during hovering.

Published

2011

46. Rapid contrast gain reduction following motion adaptation.

Author

Nordström K, Moyer de Miguel I, and O'Carroll DC

Subjects

Animals, Electrophysiological Phenomena, Adaptation, Ocular physiology, Contrast Sensitivity physiology, Diptera physiology, Motion

Abstract

Neural and sensory systems adapt to prolonged stimulation to allow signaling across broader input ranges than otherwise possible with the limited bandwidth of single neurons and receptors. In the visual system, adaptation takes place at every stage of processing, from the photoreceptors that adapt to prevailing luminance conditions, to higher-order motion-sensitive neurons that adapt to prolonged exposure to motion. Recent experiments using dynamic, fluctuating visual stimuli indicate that adaptation operates on a time scale similar to that of the response itself. Further work from our own laboratory has highlighted the role for rapid motion adaptation in reliable encoding of natural image motion. Physiologically, motion adaptation can be broken down into four separate components. It is not clear from the previous studies which of these motion adaptation components are involved in the fast and dynamic response changes. To investigate the adapted response in more detail, we therefore analyzed the effect of motion adaptation using a test-adapt-test protocol with adapting durations ranging from 20 ms to 20 s. Our results underscore the very rapid rate of motion adaptation, suggesting that under free flight, visual motion-sensitive neurons continuously adapt to the changing scenery. This might help explain recent observations of strong invariance in the response to natural scenes with highly variable contrast and image structure.

Published

2011

47. Spatial facilitation by a high-performance dragonfly target-detecting neuron.

Author

Nordström K, Bolzon DM, and O'Carroll DC

Subjects

Animals, Insecta physiology, Motion Perception physiology, Neurons physiology, Visual Perception physiology

Abstract

Many animals visualize and track small moving targets at long distances-be they prey, approaching predators or conspecifics. Insects are an excellent model system for investigating the neural mechanisms that have evolved for this challenging task. Specialized small target motion detector (STMD) neurons in the optic lobes of the insect brain respond strongly even when the target size is below the resolution limit of the eye. Many STMDs also respond robustly to small targets against complex stationary or moving backgrounds. We hypothesized that this requires a complex mechanism to avoid breakthrough responses by background features, and yet to adequately amplify the weak signal of tiny targets. We compared responses of dragonfly STMD neurons to small targets that begin moving within the receptive field with responses to targets that approach the same location along longer trajectories. We find that responses along longer trajectories are strongly facilitated by a mechanism that builds up slowly over several hundred milliseconds. This allows the neurons to give sustained responses to continuous target motion, thus providing a possible explanation for their extraordinary sensitivity., (This journal is © 2011 The Royal Society)

Published

2011

48. Motion adaptation and the velocity coding of natural scenes.

Author

Barnett PD, Nordström K, and O'Carroll DC

Subjects

Animals, Flight, Animal physiology, Models, Neurological, Motion, Neurons physiology, Adaptation, Physiological physiology, Diptera anatomy & histology, Diptera physiology, Environment, Motion Perception physiology

Abstract

Estimating relative velocity in the natural environment is challenging because natural scenes vary greatly in contrast and spatial structure. Widely accepted correlation-based models for elementary motion detectors (EMDs) are sensitive to contrast and spatial structure and consequently generate ambiguous estimates of velocity. Identified neurons in the third optic lobe of the hoverfly can reliably encode the velocity of natural images largely independent of contrast, despite receiving inputs directly from arrays of such EMDs. This contrast invariance suggests an important role for additional neural processes in robust encoding of image motion. However, it remains unclear which neural processes are contributing to contrast invariance. By recording from horizontal system neurons in the hoverfly lobula, we show two activity-dependent adaptation mechanisms acting as near-ideal normalizers for images of different contrasts that would otherwise produce highly variable response magnitudes. Responses to images that are initially weak neural drivers are boosted over several hundred milliseconds. Responses to images that are initially strong neural drivers are reduced over longer time scales. These adaptation mechanisms appear to be matched to higher-order natural image statistics reconciling the neurons' accurate encoding of image velocity with the inherent ambiguity of correlation-based motion detectors., (2010 Elsevier Ltd. All rights reserved.)

Published

2010

49. Local and large-range inhibition in feature detection.

Author

Bolzon DM, Nordström K, and O'Carroll DC

Subjects

Action Potentials, Animals, Microelectrodes, Models, Neurological, Pattern Recognition, Visual physiology, Compound Eye, Arthropod physiology, Insecta physiology, Neural Inhibition, Neurons physiology, Space Perception physiology, Visual Perception physiology

Abstract

Lateral inhibition is perhaps the most ubiquitous of neuronal mechanisms, having been demonstrated in early stages of processing in many different sensory pathways of both mammals and invertebrates. Recent work challenges the long-standing view that assumes that similar mechanisms operate to tune neuronal responses to higher order properties. Scant evidence for lateral inhibition exists beyond the level of the most peripheral stages of visual processing, leading to suggestions that many features of the tuning of higher order visual neurons can be accounted for by the receptive field and other intrinsic coding properties of visual neurons. Using insect target neurons as a model, we present unequivocal evidence that feature tuning is shaped not by intrinsic properties but by potent spatial lateral inhibition operating well beyond the first stages of visual processing. In addition, we present evidence for a second form of higher-order spatial inhibition--a long-range interocular transfer of information that we argue serves a role in establishing interocular rivalry and thus potentially a neural substrate for directing attention to single targets in the presence of distracters. In so doing, we demonstrate not just one, but two levels of spatial inhibition acting beyond the level of peripheral processing.

Published

2009

50. Evolution of vertebrate rod and cone phototransduction genes.

Author

Larhammar D, Nordström K, and Larsson TA

Subjects

Animals, Gene Duplication, Opsins genetics, Ploidies, Photoreceptor Cells, Vertebrate physiology, Retina physiology, Vertebrates genetics, Vision, Ocular genetics

Abstract

Vertebrate cones and rods in several cases use separate but related components for their signal transduction (opsins, G-proteins, ion channels, etc.). Some of these proteins are also used differentially in other cell types in the retina. Because cones, rods and other retinal cell types originated in early vertebrate evolution, it is of interest to see if their specific genes arose in the extensive gene duplications that took place in the ancestor of the jawed vertebrates (gnathostomes) by two tetraploidizations (genome doublings). The ancestor of teleost fishes subsequently underwent a third tetraploidization. Our previously reported analyses showed that several gene families in the vertebrate visual phototransduction cascade received new members in the basal tetraploidizations. We here expand these data with studies of additional gene families and vertebrate species. We conclude that no less than 10 of the 13 studied phototransduction gene families received additional members in the two basal vertebrate tetraploidizations. Also the remaining three families seem to have undergone duplications during the same time period but it is unclear if this happened as a result of the tetraploidizations. The implications of the many early vertebrate gene duplications for functional specialization of specific retinal cell types, particularly cones and rods, are discussed.

Published

2009