The stimulus movement effect: Allocation of attention or artifact?

Response properties of single neurons in the middle temporal visual area (MT) of anesthetized owl monkeys were determined and quantified for flashed and moving bars of light under computer control for position, orientation, direction of movement, and speed. Receptive-field sizes, ranging from 4 to 25 degrees in width, were considerably larger than receptive fields with corresponding eccentricities in the striate cortex. Neurons were highly binocular with most cells equally or nearly equally activated by either eye. Neurons varied in selectivity for axis and direction of moving bars. Some neurons demonstrated little or no selectivity, others were bidirectional on a single axis, while the largest group was highly selective for direction with little or no response to bar movement opposite to the preferred direction. Over 70% of neurons were classified as highly selective and 90% showed some preference for direction and/or axis of stimulus movement. Neurons typically responded to bar movement only over a restricted range of velocities. The majority of neurons responded best to a particular velocity within the 5-60 degrees/s range, with marked attenuation of the response for velocities greater or less than the preferred. Some neurons failed to show significant response attenuation even at the lowest tested velocity, while other neurons preferred velocities of 100 degrees/s or more and failed to attenuate to the highest velocities. Response magnitude varied with stimulus dimensions. Increasing the length of the moving bar typically increased the magnitude of the response slightly until the stimulus exceeded the receptive-field borders. Other neurons responded less to increases in bar length within the excitatory receptive field. Neurons preferred narrow bars less than 1 degree in width, and marked reductions in responses characteristically occurred with wider stimuli. Moving patterns of randomly placed small dots were often as effective as or more effective than single bars in activating neurons. Selectivity for direction of movement remained for the dot pattern. for the dot pattern. Poststimulus time (PST) histograms of responses to bars flashed at a series of 21 different positions across the receptive field, in the "response-plane" format, indicated a spatially and temporally homogeneous receptive-field structure for nearly all neurons. Cells characteristically showed transient excitation at both stimulus onset and offset for all effective stimulus locations. Some cells responded mainly at bright stimulus onset or offset.

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The Analysis on Difference Between Rotational Induced Movement Effect and Perception Effect in Various Forms

2018 1st IEEE International Conference on Knowledge Innovation and Invention (ICKII) ◽

10.1109/ickii.2018.8569163 ◽

2018 ◽

Author(s):

Chih-Wei Lin ◽

Wei-Min Chi ◽

Hsiwen Fan ◽

Guang-Dah Chen

Keyword(s):

Movement Effect

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Marcellus Shale Gas Boom and Forestry Employment: Evidence from West Virginia

Forest Science ◽

10.1093/forsci/fxab014 ◽

2021 ◽

Author(s):

Kathryn A Gazal ◽

Kathleen G Arano

Keyword(s):

West Virginia ◽

Shale Gas ◽

Marcellus Shale ◽

Growth Potential ◽

Adverse Impact ◽

Relative Wage ◽

Forestry Sector ◽

Movement Effect ◽

The Impact

Abstract Advancement in drilling technology has increased natural gas extraction activities from the Marcellus shale deposit resulting in a shale gas boom in many regions, including West Virginia. This boom has created a significant labor demand shock to local economies experiencing the boom. A number of studies have shown that a shale gas boom directly increases employment and the income of those working in the industry. However, the boom can also have an adverse impact on other sectors through the resource movement effect and intersector labor mobility, pulling workers away from a related sector like forestry. Thus, an econometric model of employment in the forestry sector was developed to investigate the impact of the Marcellus shale gas boom in West Virginia. There is evidence of a labor movement effect with forestry employment negatively affected by the Marcellus shale boom. Specifically, the overall marginal effect of the shale boom on forestry employment is approximately 435 fewer jobs. However, the extent of the decline is slightly moderated by a higher relative wage between gas and forestry, perhaps suggesting diminishing returns and overall slack in the local labor market. Study Implications Although a Marcellus shale gas boom directly increases employment and the income of those working in that industry, it can have an adverse impact on other sectors by pulling workers away from a related sector like forestry. This study showed that employment in the West Virginia forestry sector was negatively affected by the shale gas boom. An important policy issue is how to manage the cyclical nature of shale gas booms and the negative impacts on other industries with long-term growth potential, like the forestry sector. This sector does not suffer through boom-and-bust cycles, making it important for long-term economic stability.

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Directional Asymmetry of Neurons in Cortical Areas MT and MST Projecting to the NOT-DTN in Macaques

Journal of Neurophysiology ◽

10.1152/jn.00488.2001 ◽

2002 ◽

Vol 87 (4) ◽

pp. 2113-2123 ◽

Cited By ~ 36

Author(s):

K.-P. Hoffmann ◽

F. Bremmer ◽

A. Thiele ◽

C. Distler

Keyword(s):

Cortical Neurons ◽

Optic Tract ◽

Directional Asymmetry ◽

Projection Neurons ◽

Cortical Projection ◽

Directional Bias ◽

Stimulus Movement ◽

Equal Distribution ◽

Temporal Area ◽

Optokinetic Reflex

The cortical projection to the subcortical pathway underlying the optokinetic reflex was studied using antidromic electrical stimulation in the midbrain structures nucleus of the optic tract and dorsal terminal nucleus of the accessory optic system (NOT-DTN) while simultaneously recording from cortical neurons in the superior temporal sulcus (STS) of macaque monkeys. Projection neurons were found in all subregions of the middle temporal area (MT) as well as in the medial superior temporal area (MST). Antidromic latencies ranged from 0.9 to 6 ms with a median of 1.8 ms. There was a strong bias in the population of cortical neurons projecting to the NOT-DTN for ipsiversive stimulus movement (towards the recording side), whereas in the population of cortical neurons not projecting to the NOT-DTN a more or less equal distribution of stimulus directions was evident. Our data indicate that there is no special area in the posterior STS coding for ipsiversive horizontal stimulus movement. Instead, a specific selection of cortical neurons from areas MT and MST forms the projection to the NOT-DTN and as a subpopulation has the same directional bias as their subcortical target neurons. These findings are discussed in relation to the functional grouping of cortical output as an organizational principle for specific motor responses.

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Visual receptive field properties in kitten pretectal nucleus of the optic tract and dorsal terminal nucleus of the accessory optic tract

Journal of Neurophysiology ◽

10.1152/jn.1993.70.2.814 ◽

1993 ◽

Vol 70 (2) ◽

pp. 814-827 ◽

Cited By ~ 18

Author(s):

C. Distler ◽

K. P. Hoffmann

Keyword(s):

Discharge Rate ◽

Age Groups ◽

Optic Tract ◽

Visual Response ◽

Stimulus Movement ◽

Cortical Input ◽

Preferred Direction ◽

Pretectal Nucleus ◽

Adult Cats ◽

Contralateral Eye

1. Neurons in the pretectal nucleus of the optic tract (NOT) and dorsal terminal nucleus of the accessory optic tract (DTN) were recorded in anesthetized and paralyzed kittens on postnatal days 18 to 48 (P18-P48) as well as in adult cats. 2. Spontaneous as well as stimulus driven discharge rates of NOT-DTN neurons in the youngest kittens (P18-P23) are significantly lower than in older kittens (P27-P33) or adult cats. 3. Visual latencies of NOT-DTN neurons in P18-P23 kittens are significantly longer than in P27-P33 kittens. They further decrease as the animals reach adulthood. 4. Already in the youngest animals recorded in this experimental series (P18) NOT-DTN neurons were selective for ipsiversive horizontal stimulus movement. When expressed as the difference between response strength during stimulation in the preferred and the nonpreferred direction, P18-P23 NOT-DTN neurons are less direction selective than NOT-DTN cells in older animals. However, the normalized directional tuning expressed as percent change in discharge rate per degree change in stimulus direction away from the preferred direction (where discharge rate is set 100%) is about equal in all age groups. 5. NOT-DTN neurons in P18-P23 kittens respond to a rather limited range of stimulus speeds with an optimum at approximately 10 degrees/s. In P27-P33 kittens, NOT-DTN neurons increase their responsive range to higher stimulus speeds. As the animals approach adulthood, the range of effective stimulus speeds further broadens to include very low ones. 6. In P18-P23 kittens, the majority of NOT-DTN neurons is exclusively activated by the contralateral eye; only a few neurons receive an additional input from the ipsilateral eye. In P27-P48 kittens, the influence of the ipsilateral eye has significantly increased but with the majority of NOT-DTN cells still being dominated by the contralateral eye. Finally, in adults, a further strengthening of the ipsilateral input leads to a more binocularly balanced input to NOT-DTN cells. 7. Electrical stimulation in areas 17 and 18 did not elicit orthodromic action potentials in NOT-DTN neurons before P27. Thus the cortical input to the NOT-DTN in kittens becomes functional only at 4 wk of age. 8. In conclusion, the significant changes of visual response properties of NOT-DTN neurons coincide with the time when the cortical input to the NOT-DTN becomes functional.(ABSTRACT TRUNCATED AT 400 WORDS)

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Visual responses of pulvinar and collicular neurons during eye movements of awake, trained macaques

Journal of Neurophysiology ◽

10.1152/jn.1991.66.2.485 ◽

1991 ◽

Vol 66 (2) ◽

pp. 485-496 ◽

Cited By ~ 33

Author(s):

D. L. Robinson ◽

J. W. McClurkin ◽

C. Kertzman ◽

S. E. Petersen

Keyword(s):

Eye Movements ◽

Superior Colliculus ◽

Visual Stimulation ◽

Receptive Fields ◽

Visual Responses ◽

Stimulus Motion ◽

Stimulus Movement ◽

Pursuit Eye Movements ◽

Extraretinal Signal ◽

Wide Range

1. We recorded from single neurons in awake, trained rhesus monkeys in a lighted environment and compared responses to stimulus movement during periods of fixation with those to motion caused by saccadic or pursuit eye movements. Neurons in the inferior pulvinar (PI), lateral pulvinar (PL), and superior colliculus were tested. 2. Cells in PI and PL respond to stimulus movement over a wide range of speeds. Some of these cells do not respond to comparable stimulus motion, or discharge only weakly, when it is generated by saccadic or pursuit eye movements. Other neurons respond equivalently to both types of motion. Cells in the superficial layers of the superior colliculus have similar properties to those in PI and PL. 3. When tested in the dark to reduce visual stimulation from the background, cells in PI and PL still do not respond to motion generated by eye movements. Some of these cells have a suppression of activity after saccadic eye movements made in total darkness. These data suggest that an extraretinal signal suppresses responses to visual stimuli during eye movements. 4. The suppression of responses to stimuli during eye movements is not an absolute effect. Images brighter than 2.0 log units above background illumination evoke responses from cells in PI and PL. The suppression appears stronger in the superior colliculus than in PI and PL. 5. These experiments demonstrate that many cells in PI and PL have a suppression of their responses to stimuli that cross their receptive fields during eye movements. These cells are probably suppressed by an extraretinal signal. Comparable effects are present in the superficial layers of the superior colliculus. These properties in PI and PL may reflect the function of the ascending tectopulvinar system.

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Exploring the hyphen in ideo-motor action

Behavioral and Brain Sciences ◽

10.1017/s0140525x01340104 ◽

2001 ◽

Vol 24 (5) ◽

pp. 891-892 ◽

Cited By ~ 2

Author(s):

Wilfried Kunde

Keyword(s):

Action Planning ◽

Action Control ◽

Motor Action ◽

Movement Effect ◽

Feature Based

This commentary focuses on Hommel et al.'s inferences on action planning. It discusses the relevance of anticipated extrinsic movement effects for action control, the problems of a feature-based representation of actions, and the necessity of the acquisition of conditional movement-effect associations.

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