Device for training and direct practice of breast self-palpation techniques for the early detection of breast cancer comprising a container flexible body refillable with viscous fluid, a support and transfer platform connected to the body, means to simulate the type of abnormal tissue detectable within the body; fluid distributor element directly on the user's skin coming from the chamber and transfer means arranged towards the distributor element.

Device for training and direct practice of breast self-palpation techniques for the early detection of breast cancer comprising a container flexible body refillable with viscous fluid, a support and transfer platform connected to the body, means to simulate the type of abnormal tissue detectable within the body; fluid distributor element directly on the user's skin coming from the chamber and transfer means arranged towards the distributor element.

A perfusive tissue phantom is disclosed. An example tissue phantom includes a chamber with fluid inlets disposed on a first side and fluid outlets disposed on a second side spaced apart from the first side. The tissue phantom also includes a hydrogel region connected to at least one of the fluid inlets and including a permeable hydrogel with structural characteristics that simulate a type of tissue. The tissue phantom also includes a microfluidic conduit coupled to at least one of the fluid inlets. The microfluidic conduit is a flexible, semi-permeable fiber that simulates a blood vessel. The structural characteristics of the permeable hydrogel may include a selected density, porosity, rigidity and dimension that approximate a target density, porosity, rigidity and dimension of interstitial space of the type of tissue.

A procedure simulator is provided, which includes a first storage tank configured to store a liquid imitating blood; a tissue model including a plurality of bifurcated flow paths being bifurcated downstream via a plurality of bifurcated portions; a pump configured to supply the liquid to the tissue model; a second storage tank configured to store the liquid to be flowed out from the plurality of bifurcated flow paths; a plurality of pipes configured to connect an outlet of a bifurcated flow path to the second storage tank; a plurality of switching valves configured to selectively causing the bifurcated flow path to communicate with a drain flow path from which the liquid is discharged below the tissue model; and a filter member between the switching valve and the outlet of the bifurcated flow path of the plurality of bifurcated flow paths.

A vein simulator system can be used by clinicians to improve their proficiency in placing catheters such as PIVCs or in otherwise accessing a vasculature. A vein simulator system can include a simulated portion of a body, such as a simulated human arm, that includes at least one simulated vein. The vein simulator system can also include a control system, one or more sensors and one or more feedback components. The control system can leverage the one or more sensors to generate feedback during a clinician's attempt to place a catheter and can output the feedback via the feedback components, either during or after the attempt.

A vein simulator system can be used by clinicians to improve their proficiency in placing catheters such as PIVCs or in otherwise accessing a vasculature. A vein simulator system can include a simulated portion of a body, such as a simulated human arm, that includes at least one simulated vein. The vein simulator system can also include a control system, one or more sensors and one or more feedback components. The control system can leverage the one or more sensors to generate feedback during a clinician's attempt to place a catheter and can output the feedback via the feedback components, either during or after the attempt.

An interactive infant simulation device used to demonstrate the proper sleep position of an infant. The infant simulation device can include an infant body portion and a transparent upper respiratory passageway at least partially contained within the infant body portion. The infant body portion can include one or two parts, and the two parts can be removeably coupled to one another. The infant simulation device can be moved from a first position to a second position, and a colored fluid contained within the upper respiratory passageway can be viewed moving between passages representing the trachea, esophagus, and pharynx of an infant. In one case (e.g., a stomach-down orientation), the fluid may be present in the tracheal passage, demonstrating the improper sleep position of an infant. In another case (e.g., a back-down orientation), the tracheal passage may be substantially free from fluid, demonstrating the proper sleep position of an infant.

An interactive infant simulation device used to demonstrate the proper sleep position of an infant. The infant simulation device can include an infant body portion and a transparent upper respiratory passageway at least partially contained within the infant body portion. The infant body portion can include one or two parts, and the two parts can be removeably coupled to one another. The infant simulation device can be moved from a first position to a second position, and a colored fluid contained within the upper respiratory passageway can be viewed moving between passages representing the trachea, esophagus, and pharynx of an infant. In one case (e.g., a stomach-down orientation), the fluid may be present in the tracheal passage, demonstrating the improper sleep position of an infant. In another case (e.g., a back-down orientation), the tracheal passage may be substantially free from fluid, demonstrating the proper sleep position of an infant.

A simulated tissue structure for surgical training is provided. The simulated tissue structure includes a first layer made of silicone and a second layer made of silicone interconnected by a third layer made of polyester fiber that is embedded in part in the first layer and in part in the second layer to create a mechanical linkage between the first layer and the second layer. Part of the third layer that is adjacent to the first layer and part of the third layer that is adjacent to the second layer includes fiber strands coated in silicone. An inclusion that mimics an anatomical structure is located between the first layer and the second layer. The third layer of polyester fibers provides a realistic dissection plane for the practice of the surgical excision of the inclusion.

A simulated tissue structure for surgical training is provided. The simulated tissue structure includes a first layer made of silicone and a second layer made of silicone interconnected by a third layer made of polyester fiber that is embedded in part in the first layer and in part in the second layer to create a mechanical linkage between the first layer and the second layer. Part of the third layer that is adjacent to the first layer and part of the third layer that is adjacent to the second layer includes fiber strands coated in silicone. An inclusion that mimics an anatomical structure is located between the first layer and the second layer. The third layer of polyester fibers provides a realistic dissection plane for the practice of the surgical excision of the inclusion.