Simulator systems for teaching patient care are provided. In some instances, the simulator system includes a master computer module positioned within a patient body and configured to communicate simulation commands to a pneumatic module also positioned within the patient body and spaced from the master computer module. A compressor module is configured to control a compressor to supply compressed air from the compressor to the pneumatic module. The pneumatic module includes a processor configured to execute the simulation commands received from the master computer module to control a physically simulated body part of the patient body with the supplied compressed air.

A surgical simulator for surgical training is provided. The simulator includes a frame defining an enclosure and a simulated tissue model located inside an enclosure. The simulated tissue model is adapted for practicing hysterectomies and includes at least a simulated uterus and a simulated vagina. The simulated tissue model is suspending inside the enclosure with two planar sheets of silicone such that the tissue model is located between the two sheets each of which form a fold and are in turn connected to the frame. The frame may be shaped like a cylinder and located inside a cavity of a larger laparoscopic trainer having a penetrable simulated abdominal wall. The tissue model is interchangeable and accessible laterally through an aperture provided in a support leg of the trainer.

The present disclosure is directed to a system and method for surgical training with low cost, reusable materials and a highly customizable virtual environment for skill-building. According to various embodiments, a surgical training tool is usable in conjunction with a support structure configured to at least partially constrain the tool movement. Meanwhile, the tool is tracked in real-time with off-tool detectors to generate a tool path driving a virtual rendering of the surgical training tool in an operative environment. The virtual rendering may be visually observable via a display device and may include a customizable and/or selectable operative environment with one or more structures that can be operated on by the virtual surgical training tool. By tracking the virtual tool interaction with the virtual structures, a task path may be established for documenting and/or objectively assessing the performance of one or more operative tasks.

Systems and methods are disclosed for an apparatus and method for practicing injection techniques through an injectable apparatus. The injectable apparatus may contain a camera that is configured to detect the intensity and color of light attenuated from a testing tool after it is injected into a simulated human or animal body parts. A training tool may be connected to a user display device to generate a display of the injection apparatus as well as the performance parameters of a trainee.

A surgical simulator for surgical training is provided. The simulator includes a frame defining an enclosure and a simulated tissue model located inside the frame. The simulated tissue model is adapted for practicing a number of surgical procedures including but not limited to transanal excisions and transvaginal hysterectomies. Portions of the frame comprises a material adhesively compatible with the material of portions of the simulated tissue model to secure and suspend the simulated tissue model within the frame. The simulated tissue model may also include simulated vasculature configured to loop through apertures in the frame to secure and suspend the simulated tissue model within the frame.

Systems and methods are disclosed for an apparatus and method for practicing injection techniques through an injectable apparatus. The injectable apparatus may contain a camera that is configured to detect the intensity and color of light attenuated from a testing tool after it is injected into a simulated human or animal body parts. A training tool may be connected to a user display device to generate a display of the injection apparatus as well as the performance parameters of a trainee.

Simulated tissue structures and methods of manufacturing are provided. The simulated tissue structures are particularly useful for placement inside abdominal simulators for practicing laparoscopic surgical techniques. One simulated tissue structure includes a combination of two materials that are attached together wherein one of the materials forms a hollow anatomical structure configured to contain the other material. The two materials are attached in an anatomically advantageous manner such that the inner surface of the outer material closely conforms to the outer surface of the inner material. Another simulated tissue structure includes a plurality of layers wherein at least one layer is applied by printing the layer with at least one stencil to impart one or more functional characteristic to the simulated tissue structure.

The invention relates to a resuscitation dummy for the practical training of resuscitation measures, comprising a dummy body, which models the human torso and in which a first fluid line system is arranged, which models the human blood circulation system in schematised form and comprises arterial and venous fluid line segments that can be associated with the human abdomen and groin area, which fluid line segments are fluidically connected to a pump.

The invention is characterised in that: the pump is a mechanical pump that can be manually actuated and that is arranged within the dummy body, which is formed from one or more parts, in the area of the human sternum, the dummy body being elastically deformable in said area; the dummy body has one opening each in the area of the human upper abdomen and in the area of the human right and/or left groin region, under each of which openings at least the arterial or venous fluid line segment partly runs and in each of which openings a body that can be physically examined sonographically and punctured is arranged; the first fluid line system and the pump are fluidically connected to a second fluid line system, along which at least one fluidic interface is arranged; and a dummy head modelling the human head is attached to the dummy body, the dummy head having a mouth-like opening, which is fluidically connected to a bag modelling the human lung.

Simulator systems for teaching patient care are provided. In some instances, the simulator system includes a master computer module positioned within a patient body and configured to communicate simulation commands to a pneumatic module also positioned within the patient body and spaced from the master computer module. A compressor module is configured to control a compressor to supply compressed air from the compressor to the pneumatic module. The pneumatic module includes a processor configured to execute the simulation commands received from the master computer module to control a physically simulated body part of the patient body with the supplied compressed air.

A simulation device and methods of using a simulation device comprising a plurality of artificial organs and a container, wherein the plurality of artificial organs comprises an artificial uterus; an artificial cervix; an artificial muscle; and an artificial abdominal wall, and wherein the container comprises a lid and an opening. The artificial abdominal wall comprises at least one of an artificial skin, an artificial subcuticula, an artificial fat, and an artificial fascia.