A nasal impression assembly for use in prosthodontics and otolaryngology, wherein the assembly includes detachable components specifically designed for recording precise nasal impressions. The detachable components may include plurality of nasal cones, a pair of injection syringes, and an extra nasal mesh splint, assembled on a horizontal bar. Further a method is provided for measuring/imprinting the impression, by using the assembly, wherein an impression material is brought in contact with extra-nasal and/or intra-nasal structure to imprint its size and/or shape.

To provide an artificial tissue model that can be more advantageously used in surgical technique training compared to previous artificial tissues, as well as a method of fabricating the same. An artificial organ model for surgical technique training comprising two or more fibrous layers 2, 3 layered and bonded to each other so as to be peelable by a surgical technique performed by a surgical technique trainee; the layered and bonded two or more fibrous layers 2, 3 as a whole being saturated with an electroconductive liquid or gel; and two adjacent fibrous layers out of the two or more fibrous layers being formed from different materials or substances or in different colors so as to be recognizable as different membranes by the surgical technique trainee.

The present invention is related to a biochip and production method thereof. The biochip comprises a carrier, a cell or tissue culture area deposited on the carrier, and a sensor area deposited on the carrier adjacent and fluidly communicating with the cell or tissue culture area. A containing space is contained in the cell or tissue culture area comprising a simulated vascular channel, a cell or a tissue and a culture medium. At least one sensor fixation area is contained at the sensor area for placing a sensor element. The present invention can be a model for stimulating cancer of specific patient to realtimely reflecting the cancer formation, transferring status and treatment strategies. The biochip could also carry testing drugs to observe how the drugs functioning to the cells/tissue as to provide a more accurate instruction of the drugs. The present invention can perform multiple test just within on chip which can save cost and also provide a more accurate test model for the patient.

Systems and methods for calculating external bone loss for alignment of pre-diseased joints comprising: generating a three-dimensional (“3D”) computer model of an operative area from at least two two-dimensional (“2D”) radiographic images, wherein at least a first radiographic image is captured at a first position, and wherein at least a second radiographic image is captured at a second position, and wherein the first position is different than the second position; identifying an area of bone loss on the 3D computer model; and applying a surface adjustment algorithm to calculate an external missing bone surface fitting the area of bone loss.

In an embodiment, a method for the manufacture of an injection molded article in an injection mold comprises at least one flow length of at least 50 cm, the flow length being defined as the shortest distance between a point of injection in the mold and an inner mold wall, the method comprising injection molding a polycarbonate composition comprising an aromatic polycarbonate, from 0.01 wt. % to 0.30 wt. % based on the weight of the polycarbonate composition of an epoxy additive having at least two epoxy groups per molecule, and from 0.01 wt. % to 0.30 wt. % based on the weight of the polycarbonate composition of a phenolic diphosphite derived from pentaerythritol.

A simulated tissue structure and a method for making the same is provided. The simulated tissue structure is made to have a longitudinal strength that is sufficient to withstand manipulations and movements when used with a simulated surgical training model while still being severable by conventional and electro-surgical tools. The simulated tissue structure has a first and second inner layer that is encompassed by an outer layer. Portions of the first inner layer are connectable with other simulated organs to simulate conditions for training laparoscopic procedures.

An anthropomorphic test device includes a spine assembly substantially extending along a spine axis; a clavicle assembly substantially extending radially from the spine assembly; an arm assembly spaced radially from the spine assembly; and a shoulder assembly connected to the clavicle assembly and disposed adjacent to the arm assembly and defining a proximal portion that is disposed proximal to the spine assembly and a distal portion that is disposed distal to the spine assembly. The shoulder assembly includes a seat belt portion disposed between the proximal portion and the distal portion and having an elasticity that differs from the elasticity of the distal portion.

[Problem to be Solved by the Invention] To provide an artificial tissue model that can be more advantageously used in surgical technique training compared to previous artificial tissues, as well as a method of fabricating the same. [Solution] An artificial organ model for surgical technique training comprising two or more fibrous layers 2, 3 layered and bonded to each other so as to be peelable by a surgical technique performed by a surgical technique trainee; the layered and bonded two or more fibrous layers 2, 3 as a whole being saturated with an electroconductive liquid or gel; and two adjacent fibrous layers out of the two or more fibrous layers being formed from different materials or substances or in different colors so as to be recognizable as different membranes by the surgical technique trainee.

The invention relates to a mounting press for automatically mounting metallographic samples in mounting material, comprising: a pressing unit with the press cylinder, a feeding device for feeding mounting material, e.g. plastic granules, a sample loading table with a plurality of loading stations, on each of which the operator can place a sample to be mounted, a control device, a grinder and/or polisher, comprising: a device housing, at least one processing station for processing the underside of the sample, wherein the processing station comprises a grinding plate with a grinding disc for grinding the underside of the sample or a polishing plate for polishing the underside of the sample, a sample feeder with a sample removal position for providing the samples for a grinding and/or polishing process, a sample deposit position for depositing the samples after the grinding and/or polishing process, a grinding-/polishing head with a sample gripper for gripping a sample, wherein the grinding/polishing head with the sample gripper moves to the sample removal position and the sample gripper grips a sample, wherein the grinding-/polishing head with the sample gripper conveys the sample to the at least one processing station and the underside of the sample is ground or polished in the processing station, and wherein the grinding-/polishing head with the sample gripper moves the sample to the sample deposit position after the grinding or polishing process and possibly further processing steps and deposits the sample there, as well as an automated production line for mounting a plurality of samples and for processing the thus mounted samples by grinding and/or polishing samples in a program-controlled overall system comprising an automated mounting press and an automated grinder and polisher.

The present disclosure relates to an ultrasound phantom for a focused ultrasound wave. More specifically, the present invention provides an ultrasound phantom which mimics a body so as to correspond to a speed of sound in the body, in which agarose, sucrose, polydiacetylene vesicle, and distilled water are mixed, and a specific part onto which an ultrasound wave is irradiated by a focused ultrasound transducer is gradually discolored in accordance with a temperature.