A feeding bottle includes a bottle enclosure defining a hollow bottle chamber, wherein the enclosure defines a feeding outlet at a first end and an attachment structure 26 at a second end. A bottom housing defines an instrument compartment extending between a closed exterior portion of the bottom housing and a separation surface within the bottom housing, wherein the bottom housing is configured for detachable connection to the attachment structure 26 of the bottle enclosure. A relief valve is positioned within the separation surface of the bottom housing. A pressure sensor is positioned adjacent the separation surface of the bottom housing and connected by a passageway to the instrument compartment in the bottom housing, wherein the pressure sensor is configured to detect changes of pressure in the bottle enclosure.

A high flow therapy system for delivering heated and humidified respiratory gas to an airway of a patient includes a respiratory gas flow pathway for delivering the respiratory gas to the airway of the patient by way of a non-sealing respiratory interface; wherein flow rate of the respiratory gas is controlled by a microprocessor, a mixing area for mixing a first gas and a second gas in the respiratory gas flow pathway, a humidification area downstream of the mixing area and configured for humidifying respiratory gas in the respiratory gas flow pathway, and a heated delivery conduit for minimizing condensation of humidified respiratory gas.

According to a first embodiment, a feeding bottle comprises a vessel, collar, and nipple. The nipple comprises a base portion, a teat portion, an areola portion allowing movement of the teat portion towards and away from the base portion. According to a second embodiment, a feeding bottle comprises a vessel, collar, nipple and handle portion removeably secured to the vessel by the collar. The invention includes a flexible region or regions to provide a more natural feeding by closely mimicking the human breast.

An infant feeding bottle assembly includes a container and a top assembly including a collar coupled to the container at a top portion of the container, a nipple, and a nipple protector. The collar further includes a holding portion. The nipple protector is coupled to the collar and is capable of transitioning between an open state and a closed state. In the closed state, the nipple protector covers and protects the nipple. In the open state, the nipple protector retracts into or rests on the holding portion and exposes the nipple.

A feeding bottle (100) including a reservoir (105) for receiving a liquid for feeding, a teat (115) for providing the liquid from the reservoir (105), a regulator (120) disposed between the reservoir (105) and the teat (115), the regulator (120) shaped to engage the teat (115), and a collar (110) configured to retain the teat (115) to the reservoir (105), wherein the collar (110) is adjustably movable relative to the reservoir (105), wherein movement of the collar (110) relative to the reservoir (105) moves the teat (115) relative to the regulator (120) which provides adjustable flow of liquid from the reservoir (105) through the regulator (120) to the teat (115).

A teat for a bottle has a nipple portion at which there is a recessed valve portion. The valve portion is domed outwardly.

Disclosed herein are systems and methods for providing feeding reinforcement in real-time or near real-time based on physiological sensor data acquired during feeding. In some examples, music reinforcement is rendered when one or more feeding features indicative of one or more feeding behaviors are detected using the physiological sensor data. When at least one feature is not detected, the music reinforcement is stopped. In this way, contingent reinforcement is provided in real-time or near real-time based on detection of the one or more feeding behaviors to encourage and improve independent feeding behavior.

A teat (10) for an infant feeding bottle (1), including a resilient wall (12) defining a central nipple (14a) and an areola (14b) that extend around a central axis (L), said teat being elastically transformable between a distended state in which the nipple defines a global maximum (38) and at least one depressed state that is accessible from the distended state by forcing the nipple at least partially into the areola along the central axis, and in which said wall (12) additionally defines an annular double fold (32) that defines an outer local maximum (34) and an inner local minimum (36), both extending circumferentially around the global maximum, wherein the wall defines a circumferential fold region (30) that, in said at least one depressed state, ranges from the local maximum to the local minimum of the double fold, and wherein said fold region has a rotationally asymmetric stiffness distribution.

An artificial nipple is formed of an elastomeric polymer by use of 3D printing after imaging of a mother's breast in an active state of lactation. The artificial nipple used as an attachment to a baby bottle or as the nipple component of a pacifier. Use of an artificial nipple formed in this manner mitigates a problem with nipple confusion, as may otherwise manifest in newborn offspring.

Customized nipples are provided herein that are designed to mimic a woman’s anatomic nipple to improve experiences such as breast feeding, soothing a baby, and/or superior aesthetics. The customized nipples are created in a noninvasive manner, for example, via a scan of the woman’s breast that is received by a computer. The scan may be processed with enhanced computing power to provide the optimal customized nipple for the woman. The customized nipples may be formed for baby/nipple/nursing products such as bottles, pacifiers, nipple shields, breast pump flanges, attachments for supplemental nursing systems, and prosthetic nipples.