Abstract: An anesthesia delivery and monitoring system for use during outpatient surgery performed under sedation level anesthesia that includes a ventilatory system, a system for supplying sedation anesthesia, a respiratory sensor adapted to detect a respiration parameter of such a patient, and a system for supplying a timed back-up breath to such a patient through the ventilatory system. The timed back-up breaths are supplied in response to the respiration parameter falling outside a preset threshold and at a positive pressure exceeding a base operating pressure of the respiratory system. The system for supplying sedation anesthesia is an intravenous supply system for anesthesia, a ventilatory system coupled to the patient, a needle and syringe, or any combination thereof. The respiratory system includes a PC-based physiologic monitor with user modified feedback control signal.

Abstract: A spacer is provided comprising a chamber having an interior surface and an exterior surface. The interior surface is configured to receive aerosolized medicament from an inhaler and has at least one sensor for measuring airflow in the chamber. The spacer includes an actuator disposed on the exterior surface configured to initiate measurement of airflow in the chamber. Methods of making and using a spacer are also provided.

Abstract: An inventory control system includes an inventory control hub and a medicament container in communication with the inventory control hub and configured to exchange medicament information with the inventory control hub, the medicament container including a body defining a container cavity; a plurality of medicament receptacles, each medicament receptacle configured to accommodate removable storage of an unused auto-injector within the medicament receptacle and prevent storage of a used auto-injector within the medicament receptacle; and a presence sensor for each medicament receptacle, each presence sensor configured to detect a presence or absence of the unused auto-injector from the corresponding medicament receptacle.

Abstract: An anesthesia delivery and monitoring system for use during outpatient surgery performed under sedation level anesthesia that includes a ventilatory system, a system for supplying sedation anesthesia, a respiratory sensor adapted to detect a respiration parameter of such a patient, and a system for supplying a timed back-up breath to such a patient through the ventilatory system. The timed back-up breaths are supplied in response to the respiration parameter falling outside a preset threshold and at a positive pressure exceeding a base operating pressure of the respiratory system. The system for supplying sedation anesthesia is an intravenous supply system for anesthesia, a ventilatory system coupled to the patient, a needle and syringe, or any combination thereof. The respiratory system includes a PC-based physiologic monitor with user modified feedback control signal.

Abstract: A medication delivery system includes a medical server configured to send and receive and process data, a medication device configured to administer a preselected medication, a sensor circuit configured to detect selected parameters relating to medication delivery and transmit information, a transmission hub configured to communicate with the medical server and the sensor circuit. The transmission hub is configured to receive a signal from the sensor circuit and exchange the information. An application is configured to facilitate exchange of information between the sensor circuit and the medical server. The application has a preselected set of protocols. The application monitors usage of the medication device and location of the medication device by connecting to the medication device via the transmission hub.

Abstract: A medication delivery system includes a medical server configured to send and receive and process data, a medication device configured to administer a preselected medication, a sensor circuit configured to detect selected parameters relating to medication delivery and transmit information, a transmission hub configured to communicate with the medical server and the sensor circuit. The transmission hub is configured to receive a signal from the sensor circuit and exchange the information. An application is configured to facilitate exchange of information between the sensor circuit and the medical server. The application has a preselected set of protocols. The application monitors usage of the medication device and location of the medication device by connecting to the medication device via the transmission hub.

Abstract: A medication delivery system includes a medical server configured to send and receive and process data, a medication device configured to administer a preselected medication, a sensor circuit configured to detect selected parameters relating to medication delivery and transmit information, a transmission hub configured to communicate with the medical server and the sensor circuit. The transmission hub is configured to receive a signal from the sensor circuit and exchange the information. An application is configured to facilitate exchange of information between the sensor circuit and the medical server. The application has a preselected set of protocols. The application monitors usage of the medication device and location of the medication device by connecting to the medication device via the transmission hub.

Abstract: A medication delivery system includes a medical server configured to send and receive and process data, a medication device configured to administer a preselected medication, a sensor circuit configured to detect selected parameters relating to medication delivery and transmit information, a transmission hub configured to communicate with the medical server and the sensor circuit. The transmission hub is configured to receive a signal from the sensor circuit and exchange the information. An application is configured to facilitate exchange of information between the sensor circuit and the medical server. The application has a preselected set of protocols. The application monitors usage of the medication device and location of the medication device by connecting to the medication device via the transmission hub.

Abstract: A method and apparatus for monitoring changes in the intra-thoracic pressure of a patient due to the patient's respiratory activity or volumetric changes in the extra-thoracic arterial circulatory system due to cardiac function based on the changes in pressure in the patient's extra-thoracic arterial circulatory system as measured by a plethysmography sensor, such as an photoplethysmograph. A frequency spectrum is generated for the plethysmograph signal and the frequencies of interest is isolated from the frequency spectrum by setting appropriate cutoff frequencies for the frequency spectrum. This isolated frequency is used to filter the plethysmograph signal to provide a signal indicative of the patient's respiratory activity or cardiac function.

Abstract: A method and apparatus for monitoring changes in the intra-thoracic pressure of a patient due to the patient's respiratory activity or volumetric changes in the extra-thoracic arterial circulatory system due to cardiac function based on the changes in pressure in the patient's extra-thoracic arterial circulatory system as measured by a plethysmography sensor, such as an photoplethysmograph. A frequency spectrum is generated for the plethysmograph signal and the frequencies of interest is isolated from the frequency spectrum by setting appropriate cutoff frequencies for the frequency spectrum. This isolated frequency is used to filter the plethysmograph signal to provide a signal indicative of the patient's respiratory activity or cardiac function.

Abstract: A noninvasive photoplethysmographic sensor system for mobile animals such as small rodents, namely rats and mice is useful such as in a laboratory research environment. The noninvasive photoplethysmographic sensor for mobile animals such as small rodents utilizes multiple FFT's in the processing of the phtotoplethysmograophic signal, where each FFT has a different time record of the signals such as a number of points, or a zero padded FFTs. The noninvasive photoplethysmographic sensor for mobile animals provides actigraphy measurements for the animal.

Abstract: An integrated blood pressure monitor and pulse oximeter system includes a blood flow occlusion member configured to selectively occlude blood flow through an appendage of the animal (e.g., the neck or tail); a sensor coupled to the blood flow occlusion member detecting a degree of operation thereof; Light sources coupled to the tail closer to the distal end of the tail than the tail blood flow occlusion member, and selectively directing light of two different wavelengths into the appendage; a light receiver coupled to the appendage and selectively receiving a signal associated with light directed into the appendage from the light sources; and a controller configured to selectively determine blood pressure parameters from the data and pulse oximeter parameters from the data.

Abstract: A noninvasive photoplethysmographic sensor platform for small animals provides a spring biased sensor clip, wherein at least one side of the sensor clip is provided with a saddle faced clip face member. The saddle shape of the clip face member may have a hinge end, toward the hinge of the clip, which is longer in the longitudinal direction of the clip and shorter in depth than the distal end. The shorter distal end side (measured longitudinally) of this saddle shape facilitates the ability to align the transmitted and received light with the bone, while the overall saddle shape of the facing provides a physical grip to capture enough tissue to prevent the clip from relocating over time while it is attached to the limb. The shorter hinge end side (depth-wise) also allows the clip to close when it is fully assembled. The edges of the saddle shaped clip are preferably rounded off to prevent the contusions of the tissue that may result from long-term contact.

Abstract: A method and apparatus for monitoring changes in the intra-thoracic pressure of a patient due to the patient's respiratory activity or volumetric changes in the extra-thoracic arterial circulatory system due to cardiac function based on the changes in pressure in the patient's extra-thoracic arterial circulatory system as measured by a plethysmography sensor, such as an photoplethysmograph. A frequency spectrum is generated for the plethysmograph signal and the frequencies of interest is isolated from the frequency spectrum by setting appropriate cutoff frequencies for the frequency spectrum. This isolated frequency is used to filter the plethysmograph signal to provide a signal indicative of the patient's respiratory activity or cardiac function.

Abstract: A blood oxygenation monitoring device may comprise an extracorporeal pulse simulation system including one at least partially transparent blood holding element with a photoplethysmographic sensor coupled to the element and adapted to measure particular gas content of the blood. The system includes a pulse simulation mechanism configured to simulate pulsatile behavior of the blood within the element relative to the photoplethysmographic sensors. The blood holding element may be a reservoir, wherein the pulse simulation mechanism includes a magnetic stirrer and stir bar within the reservoir. The blood holding member may be flexible tubing having blood flow there through, wherein the pulse simulation mechanism is a peristaltic pump coupled to the tubing. The monitoring device can rapidly and accurately form oxygen dissociation curves. The monitoring device can be utilized in conjunction with a heart lung bypass machine or other extra corporeal circuit devices or can be a calibration tool for sensors.

Abstract: A method and apparatus for monitoring changes in the intra-thoracic pressure of a patient due to the patient's respiratory activity or volumetric changes in the extra-thoracic arterial circulatory system due to cardiac function based on the changes in pressure in the patient's extra-thoracic arterial circulatory system as measured by a plethysmography sensor, such as an photoplethysmograph. A frequency spectrum is generated for the plethysmograph signal and the frequencies of interest is isolated from the frequency spectrum by setting appropriate cutoff frequencies for the frequency spectrum. This isolated frequency is used to filter the plethysmograph signal to provide a signal indicative of the patient's respiratory activity or cardiac function. For corrections for breathing frequency roll-off and deviations of the I:E ratio from 1:1.

Abstract: An efficient, effective, MRI compatible small bore MRI noninvasive photoplethysmographic sensor for animals such as small rodents, namely rats and mice. The photoplethysmographic sensor for animals comprising: a non-magnetic sensor coupling attachable to an animal; fiber optic cable coupled to the sensor coupling and configured to deliver a signal to and receive a signal from the animal tissue adjacent the sensor coupling; an opto-electical converter coupled to the fiber optic cable, the converter including a receiver coupled the fiber optic cable portion configured to receive a signal from the animal tissue and including an emitter coupled to the fiber optic portion configured to deliver a signal to the animal tissue; an electronic coupling extending from the opto-electric converter and configured to be coupled to the emitter and the receiver, wherein the electronic coupling is configured to extend outside of the MRI chamber; and a processor coupled to the electronic coupling.

Abstract: A portable modular kiosk based physiologic sensor system for clinical and research applications configured to simultaneously utilize multiple sensors with cross checking and cross calculation of physiologic parameters.

Abstract: A portable modular kiosk based physiologic sensor system for clinical and research applications configured to simultaneously utilize multiple sensors with cross checking and cross calculation of physiologic parameters and configured for continuous monitoring of blood oxygenation and respiratory parameters.

Abstract: A hypoxia, or other bioactive gas, chamber is provided for use in animal research conducted on non-anesthetized small animals with direct physiologic monitoring.