Abstract: A multi-headed catheter for fluid delivery and a method of placing a multi-headed catheter for fluid delivery are provided. The multi-headed catheter includes a first tube extending along an axis, wherein the first tube has at least one exit hole provided at a distal end of the first tube to define a perfusion section of the first tube; and a second tube extending along the axis, wherein at least a portion of the second tube is disposed within the first tube, wherein the second tube has at least one exit hole provided at a distal end of the second tube to define a perfusion section of the second tube. The distal end of the second tube is configured to exit said first tube at an opening provided along a wall of the first tube. The perfusion sections of the first tube and the second tube can be independently placed to deliver fluid to distinct anatomical areas within a surgical wound site.

Abstract: A non-electrically driven enteral feeding pump including an expandable elastomeric bladder is provided. The enteral feeding pump includes a fluid delivery tube. The fluid delivery tube controls flow rate of fluid from the pump. The present invention further describes an enteral feeding pump assembly including the portable enteral feeding pump and a peristaltic pump. The peristaltic pump can be configured to be operatively coupled to the elastomeric bladder of the enteral feeding pump for transferring fluid from a reservoir external to the elastomeric bladder into a chamber of the elastomeric bladder.

Abstract: A catheter placing instrument is provided. The catheter placing instrument includes an elongated body that extends in a longitudinal direction from a proximal end to a distal end. The elongated body has a top surface configured to receive a catheter extending from the proximal end to the distal end. The elongated body includes a catheter insertion section and a grip section. The catheter insertion section includes a catheter locking clamp located at the distal end of the elongated body, and the grip section includes a catheter guide. The catheter placing instrument can be used to place or implant any tubular medical device within a patient's body. A method of placing a tubular medical device at a deep location within a patient's body is also provided.

Abstract: A multi-headed catheter for fluid delivery and a method of placing a multi-headed catheter for fluid delivery are provided. The multi-headed catheter includes a first tube extending along an axis, wherein the first tube has at least one exit hole provided at a distal end of the first tube to define a perfusion section of the first tube; and a second tube extending along the axis, wherein at least a portion of the second tube is disposed within the first tube, wherein the second tube has at least one exit hole provided at a distal end of the second tube to define a perfusion section of the second tube. The distal end of the second tube is configured to exit said first tube at an opening provided along a wall of the first tube. The perfusion sections of the first tube and the second tube can be independently placed to deliver fluid to distinct anatomical areas within a surgical wound site.

Abstract: A catheter placing instrument is provided. The catheter placing instrument includes an elongated body that extends in a longitudinal direction from a proximal end to a distal end. The elongated body has a top surface configured to receive a catheter extending from the proximal end to the distal end. The elongated body includes a catheter insertion section and a grip section. The catheter insertion section includes a catheter locking clamp located at the distal end of the elongated body, and the grip section includes a catheter guide. The catheter placing instrument can be used to place or implant any tubular medical device within a patient's body. A method of placing a tubular medical device at a deep location within a patient's body is also provided.

Abstract: A needle assembly for an ultrasound imaging system includes a needle having a proximal end and a distal end. The distal end is adapted to be inserted into a patient. The needle assembly also includes an optical sensor assembly secured to the distal end of the needle. The optical sensor assembly has a field of vision that includes the distal end of the needle and an environment surrounding the distal end of the needle as the needle is inserted into the patient towards a target site. In addition, the needle assembly includes a controller communicatively coupled to the optical sensor assembly. Thus, the controller is configured to receive and process one or more sensor signals from the optical sensor assembly in real-time.

Abstract: Described herein are suture passers that may be used for repair of the meniscus of the knee. These suture passers typically include an elongate body having a pair of arms. One or more of the arms may be radiused at the distal end region relative to the long axis of the device, to better fit between a target tissue and a body non-target tissue (e.g., the curvature of the femoral condyle). The arms may form a distal-facing opening that is configured to fit the target tissue. One arm may be movable in the axial direction (e.g., the direction of the long axis of the device), while the other arm may be bendable. A tissue penetrator may be housed within one of the arms to extend across the distal opening between the arms. Thus, a suture may be passed from a first side of the tissue to a second side.

Abstract: Described herein are suture passers that may be used for repair of the meniscus of the knee. These suture passers typically include an elongate body having a pair of arms. One or more of the arms may be radiused at the distal end region relative to the long axis of the device, to better fit between a target tissue and a body non-target tissue (e.g., the curvature of the femoral condyle). The arms may form a distal-facing opening that is configured to fit the target tissue. One arm may be movable in the axial direction (e.g., the direction of the long axis of the device), while the other arm may be bendable. A tissue penetrator may be housed within one of the arms to extend across the distal opening between the arms. Thus, a suture may be passed from a first side of the tissue to a second side.

Abstract: Described herein are suture passers that may be used for repair of the meniscus of the knee. These suture passers typically include an elongate body having a pair of arms. One or more of the arms may be radiused at the distal end region relative to the long axis of the device, to better fit between a target tissue and a body non-target tissue (e.g., the curvature of the femoral condyle). The arms may form a distal-facing opening that is configured to fit the target tissue. One arm may be movable in the axial direction (e.g., the direction of the long axis of the device), while the other arm may be bendable. A tissue penetrator may be housed within one of the aims to extend across the distal opening between the arms. Thus, a suture may be passed from a first side of the tissue to a second side.

Abstract: Described herein are suture passers that may be used for repair of the meniscus of the knee. These suture passers typically include an elongate body having a pair of arms. One or more of the arms may be radiused at the distal end region relative to the long axis of the device, to better fit between a target tissue and a body non-target tissue (e.g., the curvature of the femoral condyle). The arms may form a distal-facing opening that is configured to fit the target tissue. One arm may be movable in the axial direction (e.g., the direction of the long axis of the device), while the other arm may be bendable. A tissue penetrator may be housed within one of the arms to extend across the distal opening between the arms. Thus, a suture may be passed from a first side of the tissue to a second side.

Abstract: Described herein are suture passers that may be used for repair of the meniscus of the knee. These suture passers typically include an elongate body having a pair of arms. One or more of the arms may be radiused at the distal end region relative to the long axis of the device, to better fit between a target tissue and a body non-target tissue (e.g., the curvature of the femoral condyle). The arms may form a distal-facing opening that is configured to fit the target tissue. One arm may be movable in the axial direction (e.g., the direction of the long axis of the device), while the other arm may be bendable. A tissue penetrator may be housed within one of the arms to extend across the distal opening between the arms. Thus, a suture may be passed from a first side of the tissue to a second side.