A nerve mapping system includes an energy based dissection device, a plurality of beacons, and a processing device. The plurality of beacons are disposed in a tissue of a patient. Each beacon is adapted to transmit one or more first electrical signals within the body and receive one or more second energy signals. The processing device is adapted to determine first locations associated with the plurality of beacons, a second location associated with the energy based dissection device, and a third location associated with a nerve within the tissue, based on the one or more second signals, generate a mapping of the first locations, second location, and third location, and cause the first locations, second location, and third location to be displayed on a display device.

A nerve mapping system includes an energy based dissection device, a plurality of beacons, and a processing device. The plurality of beacons are disposed in a tissue of a patient. Each beacon is adapted to transmit one or more first electrical signals within the body and receive one or more second energy signals. The processing device is adapted to determine first locations associated with the plurality of beacons, a second location associated with the energy based dissection device, and a third location associated with a nerve within the tissue, based on the one or more second signals, generate a mapping of the first locations, second location, and third location, and cause the first locations, second location, and third location to be displayed on a display device.

This system for identifying information represented by biological signals is configured so as to detect biological signals (S501), analyze the detected biological signals and then output feature data (S502), determine the respective similarities between the feature data and a plurality of teaching data (S503), store the similarities per time in a time series (S504), and determine information represented by the biological signals on the basis of the plurality of similarities within a prescribed period among the stored similarities in the time series (S505).

Method and systems are provided for monitoring neuromuscular blockade in patients during surgical procedures. The system and method utilizes a stimulator to provide stimulation to a nerve of the patient, such as train-of-four (TOF). Following such stimulation, the system and method monitors for muscle twitch reaction and, based upon the monitored muscle twitches, the system and method creates a neuromuscular blocking trend curve. The neuromuscular blocking trend curve provides an estimated time of recovery for the patient and provides the estimated recovery time to a clinician. The estimated recovery time allows the clinician to modify treatment of the patient to accelerate recovery if required.

Method and systems are provided for monitoring neuromuscular blockade in patients during surgical procedures. The system and method utilizes a stimulator to provide stimulation to a nerve of the patient, such as train-of-four (TOF). Following such stimulation, the system and method monitors for muscle twitch reaction and, based upon the monitored muscle twitches, the system and method creates a neuromuscular blocking trend curve. The neuromuscular blocking trend curve provides an estimated time of recovery for the patient and provides the estimated recovery time to a clinician. The estimated recovery time allows the clinician to modify treatment of the patient to accelerate recovery if required.

A pedicle access system including a cannula, a stylet, and a removable T-handle. The pedicle access system may be used to percutaneously approach the pedicle, initiate pilot hole formation, and conduct a stimulation signal to the target site for the purposes of performing a pedicle integrity assessment during the pilot hole formation. To do this, the cannula and stylet are locked in combination and inserted through an operating corridor to the pedicle target site, using the T-handle to facilitate easy movement and positioning of the cannula/stylet combination. A stimulation signal may be applied during pilot hole formation to conduct the pedicle integrity assessment. In a significant aspect, the T-handle may be detached from the cannula/stylet combination to facilitate the use of various surgical tools as necessary.

A pedicle access system including a cannula, a stylet, and a removable T-handle. The pedicle access system may be used to percutaneously approach the pedicle, initiate pilot hole formation, and conduct a stimulation signal to the target site for the purposes of performing a pedicle integrity assessment during the pilot hole formation. To do this, the cannula and stylet are locked in combination and inserted through an operating corridor to the pedicle target site, using the T-handle to facilitate easy movement and positioning of the cannula/stylet combination. A stimulation signal may be applied during pilot hole formation to conduct the pedicle integrity assessment. In a significant aspect, the T-handle may be detached from the cannula/stylet combination to facilitate the use of various surgical tools as necessary.

Apparatus and methods for monitoring pregnancy or labour are disclosed. In one embodiment the apparatus includes an electromyography (EMG) sensor having two or more EMG electrodes to monitor fetal or maternal activity during pregnancy or labour and one or more position sensors to monitor the relative positioning of the two or more EMG electrodes during the fetal or maternal activity. In one embodiment, the apparatus includes a monitoring device to be placed on a body and having a plurality of sensors integrated into the monitoring device, the plurality of sensors including at least: a first sensor configured to detect a first type of signal from the body indicative of a first type of fetal or maternal activity during pregnancy or labour; and a second sensor configured to detect a second type of signal from the body, different from the first type of signal, also indicative of the first type of fetal or maternal activity during pregnancy or labour.

A portable polysomnography apparatus comprises a unitary flexible structured pillow that is embedded with one or more sensors for data collection. The one or more sensors can comprise a tilt sensor that is configured to generate respiratory effort signals based on tilting of the head of the subject on the pillow. The one or more sensors can further be configured to generate ballistocardiogram signals from movement of the head of the subject caused by beating of the heart of the subject. The polysomnography apparatus can be advantageously sized and shaped to cause the sleeping subject to properly orient her head with respect to the sensors for optimal data collection while the subject is asleep.

A portable polysomnography apparatus comprises a unitary flexible structured pillow that is embedded with one or more sensors for data collection. The one or more sensors can comprise a tilt sensor that is configured to generate respiratory effort signals based on tilting of the head of the subject on the pillow. The one or more sensors can further be configured to generate ballistocardiogram signals from movement of the head of the subject caused by beating of the heart of the subject. The polysomnography apparatus can be advantageously sized and shaped to cause the sleeping subject to properly orient her head with respect to the sensors for optimal data collection while the subject is asleep.