A pressure solution of an infusion solution holder has a collar that is ergonomically fitted to the shape of the shoulders. The collar includes a pressure tank integrally with the holder and a tank containing the infusion solution. Since the tank containing the infusion solution is located on the patient's shoulders and vertically close to the supply point of the infusion solution, there has to be sufficient pressure in the tank in order for a successful infusion. Therefore, the collar's pressure tank is pressurized by the element, whereby the pressure in the pressure tank is pressing the solution tank and creates the necessary pressure at the time of infusion. The pressurization of the pressure tank is shown in the most cost-effective way by pumping with a manual pressure element, such as a ball pump. Pressurization can also be made, for example, by an electric pump.

A cannula protector for protection of a cannulation site on a body is described. The protector includes a shield for inhibiting access to the cannulation site; and a body mount operatively connected to the shield, the body mount configured to provide one or more relief zones so as to relieve the mounting force of the protector when mounted on the body. A protector for protection of a cannulation site on a body is also described, the protector including: a shield for inhibiting access to the cannulation site; wherein the shield is configured to conform to a contour of the body to inhibit access to the cannulation site. Further, a protector for protection of a cannulation site on a body is described, the protector including: a shield for inhibiting access to the cannulation site; and a body mount operatively connected to the shield, the body mount including a plurality of body engaging feet; wherein the body engaging feet are configured to move to conform to a contour of the body to inhibit access to the cannulation site.

The present disclosure is directed to a cap to be worn by an individual having a scalp intravenous tube so as to help in maintaining the body temperature of the individual. The cap includes a body, at least one opening and a fastener. The body has a plurality of panels. The at least one opening is formed between the plurality of panels of the body. The fastener is positioned on a portion of at least one of the plurality of panels of the body to connect the plurality of panels of the body so as to attach the body of the cap to a head of an individual.

Exoskeletal devices or sleeves that can be used with the delivery tube of an applicator device to help dispense fluids, typically flowable biocompatible materials such as hemostatic agents, adhesives, or sealants, onto specific sites in the human body for a medical reason are disclosed. The exoskeletal devices or sleeves are rigid, pre-shaped, and snappably or slidably affixed to the delivery tube. The exoskeletal devices or sleeves do not come into contact with the flowable biocompatible fluid being dispensed, and they can be placed at any position along the delivery tube to address different application situations. Once the exoskeletal device or sleeve is in place, it can optionally be locked onto the delivery tube to prevent further sliding under stresses when pushed against tissue. Multiple exoskeletal devices or sleeves can also be used to achieve more complicated shapes for hard-to-reach anatomical sites.

An intravenous (IV) site and medical tubing protection device which diminishes the inadvertent, non-purposeful dislodging of an IV catheter, as fluids are being delivered to a patient via a medicine dispensing unit. It employs a self-contained retractable spring spool unit consisting of medicinal tubing 13, a spring-loaded, retractable spool 8, an IV Luer 5, a lubricating ring port 9, a swiveling fluid junction 10, bolus valve 11, and a plastic shell container 7. Medicinal tubing 13 enters the plastic shell container 7 through a lubricating ring port 9 and winds around the retractable spool 8. The tubing attaches to a swiveling fluid junction 10, which permits a constant flow of fluid through the patient line, despite any extending or retracting of the tubing. A subsequent patient line attaches to the swiveling fluid junction 10 at its other end and then to an IV luer 5 that extends beyond the plastic shell 7. An IV catheter can then be attached to the luer 5.

The present invention pertains to a device for securing a medical implement to the body of a patient. The device preferably comprises a base having a locking device and an articulation strap connected to a cover. The cover further comprises a gear rack, where the gear rack is insertable into the locking device. The base further comprises a top surface with an adhesive film and release paper and a bottom surface attached to a patient attachment member. The base also has a cutout section. The base is preferably sloped at an angle between five and ten degrees. The cover preferably has at least two living hinges and the articulation strap has at least two living hinges. The locking device further comprises a sliding surface.

A medical tubing organizer includes a base defining a longitudinal direction, a lateral direction being defined as substantially orthogonal to the longitudinal direction, and a vertical direction being defined as substantially orthogonal to the longitudinal and lateral directions. A tube retainer is positioned on a top of the base and configured to receive a medical tube that extends along the lateral direction. The tube retainer is further configured to adjust between a free flow state and a retention state, wherein, in the free flow state, the tube retainer is configured to enable movement of the medical tube in the lateral direction and resist movement in the longitudinal direction, and in the retention state, the tube retainer is configured to resist movement in the lateral, longitudinal, and vertical directions. A connector is positioned on the base for selectively coupling the medical tubing organizer to a structure.

A retaining device is disclosed. The retaining device is made of suitable material formed in a frame having a central portion and two opposing arms spaced apart from the frame and in the plane thereof. The central portion being arranged so as to cause a conduit inserted through the cord slots between the central portion and the opposing arms to be urged substantially equally against the opposing arms. Each opposing arm provides a tapered gripping edge directed toward the central portion, wherein each gripping edges provides a plurality of serrations for further engaging the urged conduit.

An infusion and blood collection device allows clean blood collections into a collection tube via a previously installed angiocatheter without interrupting the administration of intravenous therapies after initial installation. The device optionally includes passive control of the blood collection flow rate to prevent contamination of the collected blood draw with the IV therapy fluid being simultaneously infused through the angiocatheter. A blood collection method uses an infusion and blood collection device to draw a clean blood sample from a patient and into a collection tube via a previously installed angiocatheter without interrupting the administration of intravenous therapies.

The invention relates to an apparatus, system and method to mitigate lines, tubes, and cords that are attached to a secure structure, such as a patient, from being displaced or pulled out from the insertion site of each line, tube, and cord on the patient when each line, tube and cord is pulled or yanked unexpectedly, as can routinely occur during patient movement, treatment, or therapy in a hospital, medical, or other environment.