Aspects of the present disclosure are directed toward a device for training emergency eye surgery such as lateral canthotomy and cantholysis training. The device includes a simulated eye, a base configured to receive the simulated eye, a simulated skin, an eye displacer, and a simulated tendon. The simulated skin is configured to attach to the base and at least partially cover the simulated eye, the simulated skin depicting an area immediately surrounding a human eye, and including an eye opening configured to expose at least a portion of the simulated eye through said eye opening when the simulated skin is attached to the base. The eye displacer is configured to displace the simulated eye from a first position to second position, the first position corresponding to an ocular injury and the second position indicating a properly performed ocular surgery.

Aspects of the present disclosure are directed toward a device for training emergency eye surgery such as lateral canthotomy and cantholysis training. The device includes a simulated eye, a base configured to receive the simulated eye, a simulated skin, an eye displacer, and a simulated tendon. The simulated skin is configured to attach to the base and at least partially cover the simulated eye, the simulated skin depicting an area immediately surrounding a human eye, and including an eye opening configured to expose at least a portion of the simulated eye through said eye opening when the simulated skin is attached to the base. The eye displacer is configured to displace the simulated eye from a first position to second position, the first position corresponding to an ocular injury and the second position indicating a properly performed ocular surgery.

A patient simulator system includes a fetal patient simulator including a simulated torso and a simulated head attached to the simulated torso and being moveable in relation to the simulated torso between a neutral position and a raised position. An actuator is configured to raise the simulated head from the neutral position to the raised position. The actuator may be disposed within the simulated head of the fetal patient simulator. The patient simulator system may further include a maternal patient simulator in which the fetal patient simulator is adapted to be disposed to simulate a birthing scenario. The actuator may raise the simulated head from the neutral position to the raised position during the birthing scenario to simulate the rise of a natural fetus's head during birth. The actuator may comprise an inflatable bag or other member positioned outside of the fetal patient simulator and within the maternal patient simulator.

A patient simulator system includes a fetal patient simulator including a simulated torso and a simulated head attached to the simulated torso and being moveable in relation to the simulated torso between a neutral position and a raised position. An actuator is configured to raise the simulated head from the neutral position to the raised position. The actuator may be disposed within the simulated head of the fetal patient simulator. The patient simulator system may further include a maternal patient simulator in which the fetal patient simulator is adapted to be disposed to simulate a birthing scenario. The actuator may raise the simulated head from the neutral position to the raised position during the birthing scenario to simulate the rise of a natural fetus's head during birth. The actuator may comprise an inflatable bag or other member positioned outside of the fetal patient simulator and within the maternal patient simulator.

A manikin (1) comprising jointed body parts that are configurable to (1) closely mimic natural movement of corresponding body parts of a real baby and/or (2) closely mimic a range of poses or postures of a real baby. The baby manikin (1) includes a neck joint (11) (articulated ball and socket joint), a waist joint (12) (articulated ball and socket joint), a hip joint (13) (double ball and socket joint), two knee joints (14) (pin joints), two ankle joints (15) (articulated ball and socket joints), two shoulder joints (16) (double ball and socket joints), two elbow joints (17) (pin joints), and two wrist joints (18) (articulated ball and socket joints).

A manikin (1) comprising jointed body parts that are configurable to (1) closely mimic natural movement of corresponding body parts of a real baby and/or (2) closely mimic a range of poses or postures of a real baby. The baby manikin (1) includes a neck joint (11) (articulated ball and socket joint), a waist joint (12) (articulated ball and socket joint), a hip joint (13) (double ball and socket joint), two knee joints (14) (pin joints), two ankle joints (15) (articulated ball and socket joints), two shoulder joints (16) (double ball and socket joints), two elbow joints (17) (pin joints), and two wrist joints (18) (articulated ball and socket joints).

A test apparatus or system for testing impact induced brain trauma a method of making and a method using the same are provided. The system includes a head model, which includes a skull component, a brain component, and a fluid component. The skull component has a wall defining an interior chamber. The brain component includes a gel material and is disposed within the interior chamber. The fluid component is disposed inside the interior chamber. The system may also include a fluid tank fluidly coupled with the skull component and configured to provide the fluid component into the interior chamber. The head model may further include a layer of porous media disposed between the brain component and the interior wall surface of the skull component. The system may include at least one impact element for providing an impact on the head model. The impact is translational or rotational or both.

A test apparatus or system for testing impact induced brain trauma a method of making and a method using the same are provided. The system includes a head model, which includes a skull component, a brain component, and a fluid component. The skull component has a wall defining an interior chamber. The brain component includes a gel material and is disposed within the interior chamber. The fluid component is disposed inside the interior chamber. The system may also include a fluid tank fluidly coupled with the skull component and configured to provide the fluid component into the interior chamber. The head model may further include a layer of porous media disposed between the brain component and the interior wall surface of the skull component. The system may include at least one impact element for providing an impact on the head model. The impact is translational or rotational or both.

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.

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.