Intraoperative intrinsic optical imaging of human somatosensory cortex during neurosurgical operations.

Intrinsic optical imaging as developed by Grinvald et al. is a powerful technique for monitoring neural function in the central nervous system. The advent of this dye-free imaging has also enabled us to monitor human brain function during neurosurgical operations.

Functiogenesis of cardiac pacemaker activity.

Throughout our investigations on the ontogenesis of the electrophysiological events in early embryonic chick hearts, using optical techniques to record membrane potential probed with voltage-sensitive dyes, we have introduced a novel concept of "functiogenesis" corresponding to "morphogenesis". This article gives an account of the framework of "functiogenesis", focusing on the cardiac pacemaker function and the functional organization of the pacemaking area.

Monitoring Population Membrane Potential Signals During Development of the Vertebrate Nervous System.

The functional organization of the vertebrate central nervous system (CNS) during the early phase of development has long been unclear, because conventional electrophysiological means have several technical limitations. First, early embryonic neurons are small and fragile, and the application of microelectrodes is often difficult. Second, the simultaneous recording of electrical activity from multiple sites is limited, and as a consequence, response patterns of neural networks cannot be assessed.

Imaging of somatotopic representation of sensory cortex with intrinsic optical signals as guides for brain tumor surgery.

Object: Intrinsic optical signals in response to somatosensory stimuli were intraoperatively recorded during brain tumor surgery. In the present study, the authors report on the use of this technique as an intraoperative guide for the safe resection of tumors adjacent to or within the sensorimotor cortex.

Methods: In 14 patients with tumors adjacent to or within the sensorimotor cortex, intrinsic optical signals in response to somatosensory stimuli were recorded by illuminating the brain surface with Xe white light and imaging the reflected light passing through a bandpass filter (605 nm).

Optical imaging of intrinsic signals induced by peripheral nerve stimulation in the in vivo rat spinal cord.

We examined neural response patterns evoked by peripheral nerve stimulation in in vivo rat spinal cords using an intrinsic optical imaging technique to monitor neural activity. Adult rats were anesthetized by urethane, and laminectomy was performed between C5 and Th1 to expose the dorsal surface of the cervical spinal cord. The median, ulnar, and radial nerves were dissected, and bipolar electrodes were implanted in the forelimb.

Intraoperative intrinsic optical imaging of neuronal activity from subdivisions of the human primary somatosensory cortex.

We performed intrinsic optical imaging of neuronal activity induced by peripheral stimulation from the human primary somatosensory cortex during brain tumor surgery for 11 patients. After craniotomy and dura reflection, the cortical surface was illuminated with a xenon light through an operating microscope. The reflected light passed through a bandpass filter, and we acquired functional images using an intrinsic optical imaging system.

Optical Recording of the Pacemaking Activity of a Congenital Double-heart in an Early Chick Embryo: (embryonic double-heart/pacemaking activity/optical monitoring/potential-sensitive dye).

A congenital double-hearted chick embryo was found among 16,171 embryos, which was at the 11 somite stage of development. The pacemaking activity of its double heart was monitored simultaneously from 9 different regions by optical methods. The right and left half hearts were tubular, and in both, spontaneous rhythmical action potentials and beating were detected, and differences were detected in their rhythms.