Systems and methods of disinfection of catheter connections are provided. A transfer catheter connector can include a UV-transparent window at its distal end and a seal proximal to the window. A solution set connector can be inserted inside a portion of the transfer catheter connector to connect a solution set and transfer catheter. The solution set connector comprises a lumen covered by a leading membrane surface; and a sealing surface configured to sealingly engage the window surface. The connectors can be connected in a disinfection position configuration in which flow is not permitted between the catheters and the connectors are irradiated with UV light. After disinfection, the connectors are advanced to a flow position in which the piercing member pierces the membrane surface, enabling flow between the catheters. The system comprises clips that prevent advancement to the flow position without interference by the disinfection unit or by a user.

Techniques and devices for filtering dialysis fluids, such as dialysis effluent, are described. For example, a filter device may be configured to filter peritoneal dialysis (PD) effluent draining from a patient during a PD process. The filter devices may include filters configured to filter materials, such as human cells, microorganisms, and/or other components from PD effluent. For instance, a filter device may be configured to be installed in-line in a drain circuit of a PD system using conventional tubing. The captured materials may be analyzed or otherwise processed to determine health characteristics of a patient and/or to capture stem cells. Other embodiments are described.

Methods and apparatus provide therapeutic electromagnetic radiation (EMR) for inactivating infectious agents in, on or around a catheter residing in a patient's body cavity and/or for enhancing healthy cell growth. Transmitting non-ultraviolet therapeutic EMR substantially axially along an optical element in a lumen of the catheter body and/or the catheter body. Through delivery of the therapeutic EMR to particular infected areas and/or areas requiring tissue healing. The inactivation of the major sources of infection in, on, and around catheters and/or enhance healthy cell growth around catheters is accomplished by utilizing controlled relative intensity and/or treatment region specific dosing of the therapeutic EMR emitted radially from the optical element. Specific embodiments of urinary catheters, peritoneal dialysis catheters, dialysis accesses, and hemodialysis accesses are also disclosed.

A sterilizable connector may include a sterilization fluid reservoir to provide a sterilization fluid. The sterilizable connector may include a connector. The connector may include a first end to receive a first tube to connect to a medical device (e.g., directly or via one or more intervening components). The connector may include a second end to receive a second tube to connect to a patient (e.g., directly or via one or more intervening components). The connector may include a body to couple the first end to the second end to enable fluid transfer between the first tube and the second tube. The connector may include a body opening to couple to the sterilization fluid reservoir. The sterilizable connector may include a sterilization fluid injector to inject the sterilization fluid from the sterilization fluid reservoir to the connector.

A peritoneal dialysis device includes a disposable tubing set that includes a fill line with a patient access connector at one end and a dialysis fluid receiving end opposite the patient access connector end. The device also includes a fill-side pressure measuring sensor attached at the fill end and forming a disposable component of the tubing set and a patient-side pressure measuring sensor located at the fluid receiving end. The patient-side and fill-side pressure measuring sensors are adapted for measuring pressure in the fill line at the respective ends thereof. The device also includes a controller configured to regulate a rate of flow in the fill line responsively to a signal from the at least the patient-side pressure measuring sensor.

The present invention is a peritoneal undergarment for alleviating unpleasant irritation while receiving dialysis treatment. The current method of taping the transfer set is not effective during dialysis treatment due to the constant irritation while the patient's skin is pressed against the dialysis port. The present invention is a specially designed peritoneal undergarment that is effective at relieving pain while dialyzing. The current invention is ideal to combat irritation and can be manufactured using a variety of materials such as cotton which may be washed with household detergent.

A system for detecting and treating an anastomotic leak includes a microcatheter implanted at an anastomosis site; a source of a perfusion fluid coupled to the microcatheter and configured to dispense the perfusion fluid to the microcatheter; and an analyzer coupled to the microcatheter configured to receive an extracellular fluid from the microcatheter and to analyze the extracellular fluid to determine status of the anastomosis site.

Transfer sets with filters, including transfer sets with filters for peritoneal dialysis (PD) systems, and associated systems, devices, and methods are disclosed herein. In one embodiment, a transfer set includes a first connector configured to be coupled to a disposable set of a PD system, a second connector configured to be coupled to a catheter of the PD system, and a fluid channel extending between the first connector and the second connector. The transfer set further includes a filter positioned within the fluid channel and configured to filter contaminants from solution flowing within the fluid channel between the first connector and the second connector. In some embodiments, the transfer set further includes a one-way valve positioned between the filter and the second connector and configured to prevent fluid from flowing through the one-way valve in a direction toward the filter.

Pressure sensors, including optical pressure sensors for automated peritoneal dialysis (APD) systems, and associated systems, devices, and methods are disclosed herein. In one embodiment, an APD system includes a diaphragm positioned over an opening in a cavity of a disposable set. The diaphragm has an outer surface and an inner surface opposite the outer surface. The diaphragm is configured to deform in response to a force applied against the diaphragm due to pressure of fluid within the cavity. The APD system further includes a pressure sensor configured to measure a pressure of the fluid within cavity. The pressure sensor includes a light source and a photosensor. The light source is configured to irradiate the outer surface of the diaphragm with light, and the photosensor is configured to measure an amount of the light that is reflected off of the outer surface of the diaphragm and directed

A personalized chronic care system including (i) a sensor; (ii) a data receiving device separate from the sensor and configured to receive data directly or indirectly from the sensor; (iii) a data analytics device separate from the sensor and including at least one algorithm configured to analyze the sensor data and provide an analyzed data outcome; and (iv) at least one output device separate from the sensor and in communication with the data analytics device, the at least one output device configured to receive and communicate the analyzed data outcome to a health care provider.