A surgical training model for teaching, practicing, and assessing motor and cognitive skills associated with laparoscopic surgery is provided. The surgical training model has at least a portion (e.g., limbs) that is manipulatable by a user in order to maneuver those portions in a desired manner in order to interact with other portions of the surgical training model. Force perception mechanisms can also be included to inform a user when an applied force on one or more portions of the surgical training model is over a pre-determined amount.

This application relates to a system, apparatus, and methods for renal dialysis training the patients, providers, and caretakers without harming or injuring an actual patient. The renal dialysis may be hemodialysis, peritoneal dialysis, or both. The system comprises at least one closed-loop apparatus with at least one of the following—artificial blood, cannulatable vascular system, heart, peritoneal membrane and cavity, vascular valves, artificial skin, and/or other artificial organs set inside a mannequin, humanoid, or any human-like machine. The artificial organ in the mannequin can be accessed through an opening in the chest, arm, abdominal cavity, thigh, groin, neck, and any combination thereof. The renal dialysis may be through catheter access, arterio-venous graft access, and peritoneal catheter access.

A system and method for converting medical images of a particular patient into high resolution, 3D dynamic and interactive images interacting with medical tools including medical devices by coupling a model of tissue dynamics and tool characteristics to the patient specific imagery for simulating a medical procedure in an accurate and dynamic manner. The method includes a tool to add and/or to adjust the dynamic image of tissues and ability to draw and add geometric shapes on the dynamic image of tissues. The system imports the 3D surgery plan (craniotomy, head position, approach etc.). The surgeon establishes multiple views, rotates and interacts with the navigation image to see behind pathology and vital structures. The surgeon can make structures such as tumors, vessels and tissue transparent to improve visualization and to be able to see behind the pathology. The System can warn on proximity of tools to specific anatomical structure.

The present invention relates to an automatic injection training device comprising an elongated housing having a distal end and an opposite proximal end and extending along a longitudinally axis (L); a tubular demo container axially and rotationally fixed relative to the elongated housing and having a tubular wall extending along the longitudinally axis (L); a reloadable plunger assembly comprising a plunger rod which is movable in the demo container between a first and a second position and a first energy accumulating element configured to move the plunger rod from the first to the second position; an actuation assembly configured to hold the plunger rod in the first position and to release the plunger rod from the first position. The invention is characterized in that the device further comprises a first signal generating element releasably connected to the plunger rod and a second signal generating element fixedly connected to the plunger rod, and wherein each signal generating element is configured to interact independently from each other for generating audible feedback signals.

A medical device operation training apparatus, used in performing training for operation of a medical device, includes: an affected-area simulated organ holding unit configured to hold a sheet-like affected-area simulated organ able to be incised or excised at least in part; and a path simulated organ holding unit configured to hold a path simulated organ for guiding the medical device to the affected-area simulated organ. With this apparatus, trainees can train for various manipulations with simple preparatory operations.

A resettable injection training device for simulating an injection is provided in an embodiment herein. The device may include an outer housing, a safety shield having a proximal end and a distal end, the distal end for engaging with a target surface during an injection simulation, the safety shield comprising a retracted position, an extended unlocked position and an extended locked position, a plunger; and a locking tab for interfacing with the safety shield for interfacing with the safety shield the extended locked position, wherein if the safety shield distal end disengages from the target surface during an injection simulation, the safety shield extends to the extended, locked position until the device is reset.

In an embodiment provided herein, an injection simulation device including a housing having a proximal end and a distal end is provided. The injection simulation device embodiment comprises a plunger having a proximal end, a distal end and being slidable relative to the housing, and a retractable injection simulation member at the distal end of the housing, at least one biasing member associated with the retractable injection simulation member and associated with the plunger, wherein a first force on a distal end of the injection simulation member causes movement of the injection simulation member from an extended position to a retracted position, to compress the first biasing member, and simulate the tactility of an injection to a user; and wherein a second force on the proximal end of the plunger asserts a third force on the first biasing member to facilitate resetting the injection simulation member to the extended position.

The present application discloses and claims a kidney phantom consisting of a silicone rubber model featuring the anatomical shape of a human kidney, the renal artery, the renal vein, and a total of 11 tumors and 2 cysts. Each tumor is represented by a solid mass, while cysts are empty three-dimensional shapes. In order to accommodate the needs of both novice and advanced surgeons, tumors were designed with increasing surgical difficulty. The kidney phantom disclosed in the present application can be combined with a commercially available ensemble of laparoscopic tools to provide localized and remote training to surgeons and medical staff practicing laparoscopic and robotic partial nephrectomy.

Various training devices and methods for simulating intranasal drug delivery are described. In one exemplary embodiment, a training device can include an outer sleeve, a locking sleeve coupled to the outer sleeve, a core sleeve coupled to the locking sleeve, and a plunger operatively coupled to the core sleeve. The plunger can be configured to selectively translate the core sleeve from an initial position to a first actuated position that indicates the release of a first simulated dose of a drug, and from the first actuated position to a second actuated position that indicates the release of a second simulated dose of the drug, in which the device does not contain the drug. The plunger can also be configured to rotate relative to the outer sleeve to reset the core sleeve to the initial position such that the core sleeve can be translated back to the first and second actuated positions.

A mucosal tissue model which, by being provided with a simulated blood vessel and/or a pseudo abdominal cavity layer, reproduces hemorrhages and/or perforations that become problems in actual resections and dissections better than conventional organ models.