Apparatuses and methods for treating neurological disorders by electro-stimulation. The apparatus may include a neural input signal acquisition module having a front-end block configured to amplify the potential difference of its input signals (V.sub.1a, V.sub.2a) and to filter a stimulus artifact and may include a multi-stage fully-differential switched capacitor circuit (e.g., an integrated circuit) configured for discrete-time signal processing.

A breast saver is described that has the structure of a brassiere. The brassiere includes a first cup, a second cup, a first wing and a second wing. The first cup and the second cup include an electromagnetic shielding layer that is an elastic layer that retains the level of electromagnetic shielding in at least one direction of stretching. The first cup connects to the first wing and the second cup connects to the second wing. The wings of the breast saver can also include an electromagnetic shielding layer. The shielding provided by the electromagnetic shielding layer can vary in structure and material in order to provide a desired level of electromagnetic shielding while stretching in one or more directions.

A breast saver is described that has the structure of a brassiere. The brassiere includes a first cup, a second cup, a first wing and a second wing. The first cup and the second cup include an electromagnetic shielding layer that is an elastic layer that retains the level of electromagnetic shielding in at least one direction of stretching. The first cup connects to the first wing and the second cup connects to the second wing. The wings of the breast saver can also include an electromagnetic shielding layer. The shielding provided by the electromagnetic shielding layer can vary in structure and material in order to provide a desired level of electromagnetic shielding while stretching in one or more directions.

This disclosure relates to implantable neuro stimulation devices with a feedback loop to control an amount of energy delivered into a neural tissue based on a measured evoked neural response. Stimulation electrodes deliver stimulation energy to neural tissue. A microprocessor performs closed-loop control of the stimulation energy based on a feedback signal that is indicative of an evoked neural response. A supervisor is connected to the feedback signal and detects malfunction of the stimulator based on the feedback signal. The supervisor is also connected to the stimulator to provide a status signal to the stimulator and changes the status signal to indicate malfunction upon detecting malfunction based on the feedback signal. The microprocessor adjusts the control of the stimulation energy in response to the status signal from the supervisor indicating malfunction.

This disclosure relates to implantable neuro stimulation devices with a feedback loop to control an amount of energy delivered into a neural tissue based on a measured evoked neural response. Stimulation electrodes deliver stimulation energy to neural tissue. A microprocessor performs closed-loop control of the stimulation energy based on a feedback signal that is indicative of an evoked neural response. A supervisor is connected to the feedback signal and detects malfunction of the stimulator based on the feedback signal. The supervisor is also connected to the stimulator to provide a status signal to the stimulator and changes the status signal to indicate malfunction upon detecting malfunction based on the feedback signal. The microprocessor adjusts the control of the stimulation energy in response to the status signal from the supervisor indicating malfunction.

Exemplary embodiments of the present subject matter is directed towards a device used to reduce electromagnetic radiations comprising a electromagnetic resistance sheet including a first layer and a third layer positioned at front and rear portions of the electromagnetic resistance metallic sheet configured to convert received excess radio frequency radiations of electronic signals to electromagnetic field signals and ground the converted electromagnetic field; and cloud signals for avoiding the transmission of radiations into the human body and environment. The first layer and the third layer coated with plurality of chemical elements. The electromagnetic resistance sheet also includes a second layer positioned between the first layer and the third layer coated with plurality of metallic elements to provide anti corrosion of the electromagnetic resistance sheet in the transmission of radiations.

Exemplary embodiments of the present subject matter is directed towards a device used to reduce electromagnetic radiations comprising a electromagnetic resistance sheet including a first layer and a third layer positioned at front and rear portions of the electromagnetic resistance metallic sheet configured to convert received excess radio frequency radiations of electronic signals to electromagnetic field signals and ground the converted electromagnetic field; and cloud signals for avoiding the transmission of radiations into the human body and environment. The first layer and the third layer coated with plurality of chemical elements. The electromagnetic resistance sheet also includes a second layer positioned between the first layer and the third layer coated with plurality of metallic elements to provide anti corrosion of the electromagnetic resistance sheet in the transmission of radiations.

A tangible device such as a credit card shaped device that includes at least one waffler carved therein. A bottom stabilizing material in the shape of a film or sheet is placed within the waffler. A nano-scaled metal in powdered form that is ferromagnetic in nanoscale, such as gold, is then added above the bottom stabilizing film. A ferromagnetic powder in nanoscale is added to the nano-scaled metal and a top stabilizing film is placed thereon. Ceramic powder is then used to further stabilize the composition and finally all the components are sealed within the waffler. The nano-scaled metals can be affixed to the stabilizing films using atomic layer deposition. The present invention is used to neutralize the electromagnetic contamination emitted from a plurality of electronic devices by organizing the polarity of the spin of the element particles within their radiation.

A heating pad without electric field radiation is disclosed. The heating pad without electric field radiation includes a heating wire, a shielding layer, a cotton layer and flannel. The shielding layer is disposed on the heating wire, and the shielding layer is symmetrically provided with two groups. The cotton layer is disposed on the shield layer, the cotton layer is symmetrically provided with two groups. The flannel is disposed on the cotton layer, and the flannel is symmetrically provided with two groups. The present disclosure relates to the field of heating pads, and specifically to a heating pad without electric field radiation.

A heating pad without electric field radiation is disclosed. The heating pad without electric field radiation includes a heating wire, a shielding layer, a cotton layer and flannel. The shielding layer is disposed on the heating wire, and the shielding layer is symmetrically provided with two groups. The cotton layer is disposed on the shield layer, the cotton layer is symmetrically provided with two groups. The flannel is disposed on the cotton layer, and the flannel is symmetrically provided with two groups. The present disclosure relates to the field of heating pads, and specifically to a heating pad without electric field radiation.