Your search keyword '"Dennis, Robert G."' showing total 21 results

1. Methodological Problems With Online Concussion Testing.

Author

Holden, Jameson, Francisco, Eric, Tommerdahl, Anna, Lensch, Rachel, Kirsch, Bryan, Zai, Laila, Pearce, Alan J., Favorov, Oleg V., Dennis, Robert G., and Tommerdahl, Mark

Subjects

BRAIN concussion, COMPUTER operating systems, COMPUTER monitors, MICE (Computers), VISUAL perception, TREATMENT delay (Medicine)

Abstract

Reaction time testing is widely used in online computerized concussion assessments, and most concussion studies utilizing the metric have demonstrated varying degrees of difference between concussed and non-concussed individuals. The problem with most of these online concussion assessments is that they predominantly rely on consumer grade technology. Typical administration of these reaction time tests involves presenting a visual stimulus on a computer monitor and prompting the test subject to respond as quickly as possible via keypad or computer mouse. However, inherent delays and variabilities are introduced to the reaction time measure by both computer and associated operating systems that the concussion assessment tool is installed on. The authors hypothesized systems that are typically used to collect concussion reaction time data would demonstrate significant errors in reaction time measurements. To remove human bias, a series of experiments was conducted robotically to assess timing errors introduced by reaction time tests under four different conditions. In the first condition, a visual reaction time test was conducted by flashing a visual stimulus on a computer monitor. Detection was via photodiode and mechanical response was delivered via computer mouse. The second condition employed a mobile device for the visual stimulus, and the mechanical response was delivered to the mobile device's touchscreen. The third condition simulated a tactile reaction time test, and mechanical response was delivered via computer mouse. The fourth condition also simulated a tactile reaction time test, but response was delivered to a dedicated device designed to store the interval between stimulus delivery and response, thus bypassing any problems hypothesized to be introduced by computer and/or computer software. There were significant differences in the range of responses recorded from the four different conditions with the reaction time collected from visual stimulus on a mobile device being the worst and the device with dedicated hardware designed for the task being the best. The results suggest that some of the commonly used visual tasks on consumer grade computers could be (and have been) introducing significant errors for reaction time testing and that dedicated hardware designed for the reaction time task is needed to minimize testing errors. [ABSTRACT FROM AUTHOR]

Published

2020

2. Roles of mucus adhesion and cohesion in cough clearance.

Author

Button, Brian, Goodell, Henry P., Atieh, Eyad, Yu-Cheng Chen, Williams, Robert, Shenoy, Siddharth, Lackey, Elijah, Shenkute, Nathan T., Li-Heng Cai, Dennis, Robert G., Boucher, Richard C., and Rubinstein, Michael

Subjects

MUCUS, COUGH, ASTHMA, CYSTIC fibrosis, ADHESIVES, BICARBONATE ions

Abstract

Clearance of intrapulmonary mucus by the high-velocity airflow generated by cough is the major rescue clearance mechanism in subjects with mucoobstructive diseases and failed cilial-dependent mucus clearance, e.g., subjects with cystic fibrosis (CF) or chronic obstructive pulmonary disease (COPD). Previous studies have investigated the mechanical forces generated at airway surfaces by cough but have not considered the effects of mucus biophysical properties on cough efficacy. Theoretically, mucus can be cleared by cough from the lung by an adhesive failure, i.e., breaking mucus-cell surface adhesive bonds and/or by cohesive failure, i.e., directly fracturing mucus. Utilizing peel-testing technologies, mucus-epithelial surface adhesive and mucus cohesive strengths were measured. Because both mucus concentration and pH have been reported to alter mucus biophysical properties in disease, the effects of mucus concentration and pH on adhesion and cohesion were compared. Both adhesive and cohesive strengths depended on mucus concentration, but neither on physiologically relevant changes in pH nor bicarbonate concentration. Mucus from bronchial epithelial cultures and patient sputum samples exhibited similar adhesive and cohesive properties. Notably, the magnitudes of both adhesive and cohesive strength exhibited similar velocity and concentration dependencies, suggesting that viscous dissipation of energy within mucus during cough determines the efficiency of cough clearance of diseased, hyperconcentrated, mucus. Calculations of airflow-induced shear forces on airway mucus related to mucus concentration predicted substantially reduced cough clearance in small versus large airways. Studies designed to improve cough clearance in subjects with mucoobstructive diseases identified reductions of mucus concentration and viscous dissipation as key therapeutic strategies. [ABSTRACT FROM AUTHOR]

Published

2018

3. Biochemical Properties of Tissue-Engineered Cartilage.

Author

Pappa, Andrew K., Caballero, Montserrat, Dennis, Robert G., Skancke, Matthew D., Narayan, Roger J., Dahl, John P., and van Aalst, John A.

Published

2014

4. Altered central sensitization in subgroups of women with vulvodynia.

Author

Zhang Z, Zolnoun DA, Francisco EM, Holden JK, Dennis RG, Tommerdahl M, Zhang, Zheng, Zolnoun, Denniz A, Francisco, Eric M, Holden, Jameson K, Dennis, Robert G, and Tommerdahl, Mark

Published

2011

5. Electrical stimulation prior to delayed reinnervation does not enhance recovery in muscles of rats.

Author

Dow, Douglas E., Cederna, Paul S., Hassett, Cheryl A., Dennis, Robert G., and Faulkner, John A.

Subjects

MUSCULAR atrophy, NEUROMUSCULAR diseases, DENERVATION, ELECTRIC stimulation, MUSCLES

Abstract

Purpose: Prolonged denervation of skeletal muscles results in atrophy and poor recovery of motor function following delayed reinnervation. Electrical stimulation reduces denervation atrophy. We hypothesized that electrical stimulation of denervated extensor digitorum longus (EDL) muscles during a prolonged period between nerve axotomy and opportunity for reinnervation by motoneurons after nerve-repair would enhance the recovery of muscle mass, force and motor-function. Methods: The EDL muscles of rats were denervated for 3.5 months by peroneal nerve axotomy, then repaired with an end-to-end neurorrhaphy, and allowed to recover for 6.5 months. During the period of denervation, some of the rats received a protocol of electrical stimulation that had previously been shown to dramatically attenuate the effects of denervation atrophy through 4 months. Other experimental groups included unoperated control muscles, denervated muscles, and axotomy followed immediately by nerve-repair. Final evaluations included walking track analysis, maximum force measured in situ by indirect stimulation of the nerve, and muscle mass. Results: The hypothesis was not supported. Electrical stimulation during the period of denervation did not enhance recovery of muscle mass, force or motor function. Conclusion: The primary factors that inhibited reinnervation and recovery following delayed reinnervation were not alleviated by the electrical stimulation during the period of muscle denervation. [ABSTRACT FROM AUTHOR]

Published

2007

6. Regional variation of tibialis anterior tendon mechanics is lost following denervation.

Author

Arruda, Ellen M., Calve, Sarah, Dennis, Robert G., Mundy, Kevin, and Baar, Keith

Subjects

MECHANICS (Physics), STRESS-strain curves, HYPOKINESIA, MOVEMENT disorders, TENDONS, MUSCLES

Abstract

Denervation or inactivity is known to decrease the mass and alter the phenotype of muscle. The mechanical response of tendon to inactivity that has been determined experimentally differs from what is reported by patients. We investigated the hypothesis that this difference was the result of artifacts of the testing process and did not represent what occurred in vivo. To test this hypothesis, a novel approach was used to determine the mechanical properties of the tibialis anterior (TA) tendon by optically measuring the end-to-end mechanical strains as well as the local strains at specific regions of excised TA tendon units. When the end-to-end strain of normal TA tendon is determined, stress-strain response curves show considerably more extensibility than when strain is measured across only the midsection of the tendon (mid-tendon). The strain experienced by the region close to the muscle (muscle tendon) is five times greater than the strain in either the mid-tendon or near the bone (bone-tendon). Five weeks of denervation decreased muscle mass by 67%; increased tendon mass by 10%; and changed the entire shape of the nonlinear response curve, including a loss in regional variation in strain, a 3.9-fold increase in end-to-end tangent modulus, and a 70% reduction in the toe region, as a result of a drastic reduction of the extensibility in the muscle-tendon region. The stress-strain response in the mid-tendon region of a normal TA tendon is therefore not indicative of its overall ability to deform in vivo as it transmits forces from muscle to bone. [ABSTRACT FROM AUTHOR]

Published

2006

7. Cultured slow vs. fast skeletal muscle cells differ in physiology and responsiveness to stimulation.

Author

Yen-Chih Huang, Dennis, Robert G., and Baar, Keith

Subjects

MUSCLE cells, MYOBLASTS, MYOSIN, PHYSIOLOGY, ELECTRIC stimulation, MEMBRANE proteins

Abstract

ln vitro studies have used protein markers to distinguish between myogenic cells isolated from fast and slow skeletal muscles. The protein markers provide some support for the hypothesis that satellite cells from fast and slow muscles are different, but the data are equivocal. To test this hypothesis directly, three-dimensional skeletal muscle constructs were engineered from myogenic cells isolated from fast tibialis anterior (TA) and slow soleus (SQL) muscles of rats and functionality was tested. Time to peak twitch tension (TPT) and half relaxation time (RT½) were ~30% slower in constructs from the SOL. The slower contraction and relaxation times for the SOL constructs resulted in left shift of the force-frequency curve compared with those from the TA. Western blot analysis showed a 60% greater quantity of fast myosin heavy chain in the TA constructs. 14 days of chronic low-frequency electrical stimulation resulted in a 15% slower TPT and a 14% slower RT112, but no change in absolute force production in the TA constructs. In SOL constructs, slow electrical stimulation resulted in an 80% increase in absolute force production with no change in TPT or RT½. The addition of cyclosporine A did not prevent the increase in force in SQL constructs after chronic low-frequency electrical stimulation, suggesting that calcineurin is not responsible for the increase in force. We conclude that myogenic cells associated with a slow muscle are imprinted to produce muscle that contracts and relaxes slowly and that calcineurin activity cannot explain the response to a slow pattern of electrical stimulation. [ABSTRACT FROM AUTHOR]

Published

2006

8. Electrical stimulation of denervated muscles of rats maintains mass and force, but not recovery following grafting.

Author

Dow, Douglas E., Carlson, Bruce M., Hassett, Cheryl A., Dennis, Robert G., and Faulkner, John A.

Subjects

NERVE grafting, MUSCLES, DENERVATION, CONTRACTILITY (Biology), ELECTRIC stimulation, NEUROSURGERY

Abstract

Purpose: Denervated skeletal muscles lack contractile activity and subsequently lose mass and force generation. Prolonged periods of denervation prior to nerve-implant grafting limit the recovery of mass and force. We hypothesized that electrical stimulation during a period of denervation that maintains mass and force above the levels of denervated muscles enhances the recovery of mass and force following nerve-implant grafting. Methods: The extensor digitorum longus (EDL) muscles of anesthetized rats were denervated, and a stimulator was implanted. Following 4 or 7 months of denervation, with or without electrical stimulation, the EDL muscles were removed, evaluated in vitro for mass and contractile properties, and then nerve-implant grafted into syngeneic rats. Unoperated, contralateral muscles were also evaluated and grafted. Results: The hypothesis was not supported by the experimental data. Compared with values for 4- or 7-month denervated muscles, the stimulated-denervated muscles maintained higher mass and force, less prolonged time-to-peak tensions and half-relaxation times, and higher excitability. Nevertheless, the recovery of mass and force following grafting was not improved. Conclusion: The factors within long-term denervated muscles that hinder recovery following grafting appear to be related primarily to factors associated with the duration of denervation and not to the level of atrophy and weakness prior to grafting. [ABSTRACT FROM AUTHOR]

Published

2006

9. In Vivo Conditioning of Tissue-engineered Heart Muscle Improves Contractile Performance.

Author

Birla, Ravi K., Borschel, Gregory H., and Dennis, Robert G.

Subjects

CARDIOID, EOSIN, MICROGRAPHICS, ADRENALINE, MYOCARDIUM, NEOVASCULARIZATION, VON Willebrand factor

Abstract

The ability to engineer cardiac tissue in vitro is limited by the absence of a vasculature. In this study we describe an in vivo model which allows neovascularization of engineered cardiac tissue. Three-dimensional cardiac tissue, termed “cardioids,” was engineered in vitro from the spontaneous delamination of a confluent monolayer of cardiac cells. Cardioids were sutured onto a support framework and then implanted in a subcutaneous pocket in syngeneic recipient rats. Three weeks after implantation, cardioids were recovered for in vitro force testing and histological evaluation. Staining for hematoxylin and eosin demonstrated the presence of viable cells within explanted cardioids. Immunostaining with von Willebrand factor showed the presence of vascularization. Electron micrographs revealed the presence of large amounts of aligned contractile proteins and a high degree of intercellular connectivity. The peak active force increased from an average value of 57 µN for control cardioids to 447 µN for explanted cardioids. There was also a significant increase in the specific force. There was a significant decrease in the time to peak tension and half relaxation time. Explanted cardioids could be electrically paced at frequencies of 1–5 Hz. Explanted cardioids exhibited a sigmoidal response to calcium and positive chronotropy in response to epinephrine. As the field of cardiac tissue engineering progresses, it becomes desirable to engineer larger diameter tissue equivalents and to induce angiogenesis within tissue constructs. This study describes a relatively simple in vivo model, which promotes the neovascularization of tissue-engineered heart muscle and subsequent improvement in contractile performance. [ABSTRACT FROM AUTHOR]

Published

2005

10. Development of a three-dimensional physiological model of the internal anal sphincter bioengineered in vitro from isolated smooth muscle cells.

Author

Hecker, Louise, Baar, Keith, Dennis, Robert G., and Bitar, Khalil N.

Subjects

FECAL incontinence, DEFECATION disorders, SPHINCTERS, SMOOTH muscle, MUSCLE cells, CELLS

Abstract

Fecal incontinence affects people of all ages and social backgrounds and can have devastating psychological and economic consequences. This disorder is largely attributed to decreased mechanical efficiency of the internal anal sphincter (IAS), yet little is known about the pathophysiological mechanisms responsible for the malfunction of sphincteric smooth muscle at the cellular level. The object of this study was to develop a three-dimensional (3-D) physiological model of the IAS bioengineered in vitro from isolated smooth muscle cells. Smooth muscle cells isolated from the IAS of rabbits were seeded in culture on top of a loose fibrin gel, where they migrated and self-assembled in circumferential alignment. As the cells proliferated, the fibrin gel contracted around a 5-mm-diameter SYLGARD mold, resulting in a 3-D cylindrical ring of sphincteric tissue. We found that 1) the bioengineered IAS rings generated a spontaneous basal tone, 2) stimulation with 8-bromo-cAMP (8-Br-cAMP) caused a sustained decrease in the basal tone (relaxation) that was calcium-independent, 3) upon stimulation with ACh, bioengineered IAS rings showed a calcium- and concentration-dependent peak contraction at 30 s that was sustained for 4 min, 4) addition of 8-Br-cAMP induced rapid relaxation of ACh-induced contraction and force generation of IAS rings, and 5) bioengineered sphincter rings show striking functional differences when compared with bioengineered rings made from isolated colonic smooth muscle cells. This is the first report of a 3-D in vitro model of a gastrointestinal smooth muscle IAS. Bioengineered IAS rings demonstrate physiological functionality and may be used in the elucidation of the mechanisms causing sphincter malfunction. [ABSTRACT FROM AUTHOR]

Published

2005

11. Comparison of gene expression of 2-mo denervated, 2-mo stimulated-denervated, and control rat skeletal muscles.

Author

Kostrominova, Tatiana Y., Dow, Douglas E., Dennis, Robert G., Miller, Richard A., and Faulkner, John A.

Published

2005

12. Distribution of Rest Periods Between Electrically Generated Contractions in Denervated Muscles of Rats.

Author

Dow, Douglas E., Faulkner, John A., and Dennis, Robert G.

Subjects

ELECTRIC stimulation, ELECTRICITY in medicine, ELECTROPHYSIOLOGY, ELECTROTHERAPEUTICS, MUSCLES, MEDICAL research

Abstract

Stimulation protocols for denervated muscles distribute the generated contractions either within treatment sessions followed by hours of rest, or repeated 24 h per day with each contraction followed by a constant interval of rest. Our purpose was to directly compare the effects of the same number of identically generated contractions having different temporal daily distributions. For 5 weeks in denervated extensor digitorum longus muscles of rats, between 100 and 800 contractions were generated daily, distributed either within worksets that alternated periods of activity and rest, or separated by constant intervals of rest. Most of the tested protocols maintained muscle mass and maximum force near values of innervated controls. Although 100 contractions daily generated at constant intervals were sufficient to maintain mass and force, 100 contractions during a 4-h treatment session followed by 20 h of rest were not sufficient, and mass and force were not different from values of denervated muscles. [ABSTRACT FROM AUTHOR]

Published

2005

13. Electrical stimulation attenuates denervation and age-related atrophy in extensor digitorum longus muscles of old rats.

Author

Dow, Douglas E., Dennis, Robert G., Faulkner, John A., and Smith, James R.

Subjects

ELECTRIC stimulation, AGING, DENERVATION, MUSCULAR atrophy, LABORATORY rats

Abstract

Skeletal muscles of old rats and elderly humans lose muscle mass and maximum force. Denervation is a major cause of age-related muscle atrophy and weakness, because denervated fibers do not contract, and undergo atrophy. At any age, surgical denervation causes even more dramatic muscle atrophy and loss in force than aging does. Electrical stimulation that generates tetanic contractions of denervated muscles reduces the denervation-induced declines. We investigated whether a stimulation protocol that maintains mass and force of denervated extensor digitorum longus muscles of adult rats would also maintain these properties in denervated muscles of old rats during a 2-month period of age-induced declines in these properties. Contractile activity generated by the electrical stimulation eliminated age-related losses in muscle mass and reduced the deficit in force by 50%. These data provide support for the hypothesis that during aging, lack of contractile activity in fibers contributes to muscle atrophy and weakness. [ABSTRACT FROM AUTHOR]

Published

2005

14. Rapid formation of functional muscle in vitro using fibrin gels.

Author

Yen-Chih Huang, Dennis, Robert G., Larkin, Lisa, and Baar, Keith

Subjects

TISSUE engineering, FIBRIN, MUSCLES, GELATION, BIOMEDICAL engineering, TISSUE culture, DEVELOPMENTAL biology

Abstract

The transition of a muscle cell from a differentiated myotube into an adult myofiber is largely unstudied. This is primarily due to the difficulty of isolating specific developmental stimuli in vivo and the inability to maintain viable myotubes in culture for sufficient lengths of time. To address these limitations, a novel method for rapidly generating three-dimensional engineered muscles using fibrin gel casting has been developed. Myoblasts were seeded and differentiated on top of a fibrin gel. Cell-mediated contraction of the gel around artificial anchors placed 12 mm apart culminates 10 days after plating in a tubular structure of small myotubes (10-μm diameter) surrounded by a fibrin gel matrix. These tissues can be connected to a force transducer and electrically stimulated between parallel platinum electrodes to monitor physiological function. Three weeks after plating, the three-dimensional engineered muscle generated a maximum twitch force of 329 ± 26.3 μN and a maximal tetanic force of 805.8 ± 55 μN. The engineered muscles demonstrated normal physiological function including length-tension and force-frequency relationships. Treatment with IGF-I resulted in a 50% increase in force production, demonstrating that these muscles responded to hormonal interventions. Although the force production was maximal at 3 wk, constructs can be maintained in culture for up to 6 wk with no intervention. We conclude that fibrin-based gels provide a novel method to engineer three-dimensional functional muscle tissue and that these tissues may be used to model the development of skeletal muscle in vitro. [ABSTRACT FROM AUTHOR]

Published

2005

15. A swimming robot actuated by living muscle tissue.

Author

Herr, Hugh and Dennis, Robert G.

Subjects

ROBOTS, ROBOTICS, AUTOMATION, TECHNOLOGY, MUSCLES

Abstract

Biomechatronics is the integration of biological components with artificial devices, in which the biological component confers a significant functional capability to the system, and the artificial component provides specific cellular and tissue interfaces that promote the maintenance and functional adaptation of the biological component. Based upon functional performance, muscle is potentially an excellent mechanical actuator, but the larger challenge of developing muscleactuated, biomechatronic devices poses many scientific and engineering challenges. As a demonstratory proof of concept, we designed, built, and characterized a swimming robot actuated by two explanted frog semitendinosus muscles and controlled by an embedded microcontroller. Using open loop stimulation protocols, the robot performed basic swimming maneuvers such as starting, stopping, turning (turning radius ∼400 mm) and straight-line swimming (max speed >1/3 body lengths/second). A broad spectrum antibiotic/antimycotic ringer solution surrounded the muscle actuators for long term maintenance, ex vivo. The robot swam for a total of 4 hours over a 42 hour lifespan (10% duty cycle) before its velocity degraded below 75% of its maximum. The development of functional biomechatronic prototypes with integrated musculoskeletal tissues is the first critical step toward the long term objective of controllable, adaptive and robust biomechatronic robots and prostheses. [ABSTRACT FROM AUTHOR]

Published

2004

16. Recovery of Muscle Contractile Function Following Nerve Gap Repair with Chemically Acellularized Peripheral Nerve Grafts.

Author

Haase, Steven C., Rovak, Jason M., Dennis, Robert G., Kuzon, Jr., William M., and Cederna, Paul S.

Published

2003

17. Excitability and contractility of skeletal muscle engineered from primary cultures and cell lines.

Author

Dennis, Robert G. and Kosnik II, Paul E.

Subjects

MUSCLE cells, TISSUE culture, MICE physiology, RAT physiology, MYOBLASTS

Abstract

Compares the cross-sectional area, excitability, and contractility of myooids engineered from cocultures of C[sub 2]C[sub 12] myoblast and 10T1/2 fibrolast cell lines, primary muscle cultures from adult C3H mice, and neonatal and adult Sprague-Dawley rats. Tissue engineering; Primary cell Isolation and culture; Isometric force; Rodent tissue culture.

Published

2001

18. Self-organization of rat cardiac cells into contractile 3-D cardiac tissue.

Author

Baar, Keith, Birla, Ravi, Boluyt, Marvin O., Borschel, Gregory H., Arruda, Ellen M., and Dennis, Robert G.

Subjects

HEART cells, LABORATORY rats, TISSUES, MYOCARDIUM, CARDIAC contraction

Abstract

Deals with a study which described a method for culturing cardiomyocytes and fibroblasts in such a way as to promote the self-organization of rat cardiac cells into contractile cardiac tissue. Delamination of a monolayer of cardiac cells into a three-dimensional tissue; Ultrastructure of cardioids; Similarity between cardioids and cardiac tissue in terms of contraction.

Published

2005

19. Discussion.

Author

Kuzon Jr., William M., Dennis, Robert G., and Soroosh, Naomi E.

Published

1997

20. Distance errors: Pointing to the range effect.

Author

Worringham, Charles J. and Dennis, Robert G.

Published

1992

21. A quantitative method for determining spatial discriminative capacity.

Author

Zhang Z, Tannan V, Holden JK, Dennis RG, Tommerdahl M, Zhang, Zheng, Tannan, Vinay, Holden, Jameson K, Dennis, Robert G, and Tommerdahl, Mark

Abstract

Background: The traditional two-point discrimination (TPD) test, a widely used tactile spatial acuity measure, has been criticized as being imprecise because it is based on subjective criteria and involves a number of non-spatial cues. The results of a recent study showed that as two stimuli were delivered simultaneously, vibrotactile amplitude discrimination became worse when the two stimuli were positioned relatively close together and was significantly degraded when the probes were within a subject's two-point limen. The impairment of amplitude discrimination with decreasing inter-probe distance suggested that the metric of amplitude discrimination could possibly provide a means of objective and quantitative measurement of spatial discrimination capacity.Methods: A two alternative forced-choice (2AFC) tracking procedure was used to assess a subject's ability to discriminate the amplitude difference between two stimuli positioned at near-adjacent skin sites. Two 25 Hz flutter stimuli, identical except for a constant difference in amplitude, were delivered simultaneously to the hand dorsum. The stimuli were initially spaced 30 mm apart, and the inter-stimulus distance was modified on a trial-by-trial basis based on the subject's performance of discriminating the stimulus with higher intensity. The experiment was repeated via sequential, rather than simultaneous, delivery of the same vibrotactile stimuli.Results: Results obtained from this study showed that the performance of the amplitude discrimination task was significantly degraded when the stimuli were delivered simultaneously and were near a subject's two-point limen. In contrast, subjects were able to correctly discriminate between the amplitudes of the two stimuli when they were sequentially delivered at all inter-probe distances (including those within the two-point limen), and improved when an adapting stimulus was delivered prior to simultaneously delivered stimuli.Conclusion: Subjects' capacity to discriminate the amplitude difference between two vibrotactile stimulations was degraded as the inter-stimulus distance approached the limit of their two-point spatial discriminative capacity. This degradation of spatial discriminative capacity lessened when an adapting stimulus was used. Performance of the task, as well as improvement on the task with adaptation, would most likely be impaired if the cortical information processing capacity of a subject or subject population were systemically altered, and thus, the methods described could be effective measures for use in clinical or clinical research applications. [ABSTRACT FROM AUTHOR]

Published

2008