Effects of Focal Inactivation of Dorsal or Ventral Layers of the Lateral Geniculate Nucleus on Cats' Ability to See and Fixate Small Targets

Tate, A. K.; Malpeli, Joseph G.

doi:10.1152/jn.1998.80.4.2206

Cited by 6 publications

(2 citation statements)

References 16 publications

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“…The preparation of the cat [1,2] and spectral method is described in Tanner et al [3]. For this experiment there were two types of trials, one in which the cat was visually stimulated (VS trial), and one where there was no visual stimulation (NVS).…”

Section: Methods and Data Analysismentioning

confidence: 99%

Spectrally resolved neurophotonics: the optical BOLD effect and vascular components in the mammalian brain

et al. 2006

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We developed a broad band spectral technique that is independent of the light transport modality to separate optical changes in scattering and absorption in the cat's brain due to the hemodynamic signal following visual stimulation. 1. Introduction We examine the visual cortex of the cat using a spectral technique that allows non-invasive measurements through the skull. Specifically, we determine spectral changes due to changes in concentrations of tissue chromophores and scattering during visual stimulation. This is the first study to employ a spectral technique to separate contributions from different tissue components with high temporal (in the ms time scale) and spatial resolution (in the millimeter range) for the determination of neuronal activity. We show that different spectral components associated with known tissue chromophores can be identified and that the time course of the changes in spectral components can also be obtained. Control measurements were done to validate that the observed effects result from the external visual stimulation. In particular, we performed control trials without visual stimulation, with other conditions remaining the same. Brain regions outside the cat's visual cortex were examined, during visual stimulation, to determine if the changes observed were localized to a specific region of the brain or were due to systemic changes in blood flow. The framework for the interpretation of the hemodynamic changes observed is based on the well-established BOLD effect (Blood Oxygenation Level Dependence response) from the fMRI literature. The BOLD effect is primarily due to neurovascular coupling between the part of the brain that is activated by a given task and the corresponding local increase in blood flow, following stimulation. This increase in flow causes a local decrease in the deoxy-hemoglobin (HHb) content which is visible both in the MRI experiments and in the optical counterpart. In addition to the changes in concentration of the deoxy-hemoglobin (HHb), the spectral method provides concomitant changes in concentration of other tissue chromophores such as oxy-hemoglobin (O2Hb) and water, thereby complementing the information obtained with the fMRI methodology. Furthermore, the spectral approach that we developed provided the changes in the scattering spectrum during brain activation. Our results confirm the general model of neurovascular coupling, and provide new information in regard to changes in the scattering spectrum and apparent changes in the local water concentration that require a new interpretation model. 2. Method and Data Analysis The preparation of the cat [1, 2] and spectral method is described in Tanner et al [3]. For this experiment there were two types of trials, one in which the cat was visually stimulated (VS trial), and one where there was no visual stimulation (NVS). The trials were done where the NVS trials were performed first (in blocks of 100) followed immediately by the VS trials The tip of each fiber was placed in contact with the acrylic which was ro...

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Section: Methods and Data Analysismentioning

confidence: 99%

Spectrally resolved neurophotonics: the optical BOLD effect and vascular components in the mammalian brain

et al. 2006

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“…A mixture of clear acrylic cement and antibiotics ϳ1 mm thick was then placed in lieu of the removed tissue to provide a permanent protective barrier. 19 Metal tubes ͑15 gauge, thin-wall hypodermic tubing, with an inner diameter of 1.52 mm and an outer diameter of 1.83 mm͒, 7 mm in height, were then embedded in this mixture above the region corresponding to the visual cortex, area 17/ 18, and the frontal lobes, area 4. Figure 2 shows schematically the location of the metal tubes.…”

Section: Preparation Of the Catmentioning

confidence: 99%

Spectrally resolved neurophotonics: a case report of hemodynamics and vascular components in the mammalian brain

et al. 2005

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Abstract. We developed a spectral technique that is independent of the light transport modality ͑diffusive or nondiffusive͒ to separate optical changes in scattering and absorption in the cat's brain due to the hemodynamic signal following visual stimulation. We observe changes in oxyhemoglobin and deoxyhemoglobin concentration signals during visual stimulation reminiscent of the functional magnetic resonance imaging ͑fMRI͒ blood oxygenation level dependence ͑BOLD͒ effect. Repeated measurements at different locations show that the observed changes are local rather than global. We also determine that there is an apparent large decrease in the water concentration and scattering coefficient during stimulation. We model the apparent change in water concentration on the separation of the optical signal from two tissue compartments. One opaque compartment is featureless ͑black͒, due to relatively large blood vessels. The other compartment is the rest of the tissue. When blood flow increases due to stimulation, the opaque compartment increases in volume, resulting in an overall decrease of tissue transmission. This increase in baseline absorption changes the apparent relative proportion of all tissue components. However, due to physiological effects, the deoxyhemoglobin is exchanged with oxyhemoglobin resulting in an overall increase in the oxyhemoglobin signal, which is the only component that shows an apparent increase during stimulation.

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Essential and Sustaining LGN Inputs to Cat Primary Visual Cortex

Weyand

2002

The Cat Primary Visual Cortex

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Effects of Focal Inactivation of Dorsal or Ventral Layers of the Lateral Geniculate Nucleus on Cats' Ability to See and Fixate Small Targets

Cited by 6 publications

References 16 publications

Spectrally resolved neurophotonics: the optical BOLD effect and vascular components in the mammalian brain

Spectrally resolved neurophotonics: the optical BOLD effect and vascular components in the mammalian brain

Spectrally resolved neurophotonics: a case report of hemodynamics and vascular components in the mammalian brain

Essential and Sustaining LGN Inputs to Cat Primary Visual Cortex

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