A biomimetic composite material includes a bioactive cement material, an autologous dentin matrix, and an inorganic nano-reinforcement material. A dental implant includes a body including a biomimetic composite material, wherein the biomimetic composite material includes a bioactive cement material, an autologous dentin matrix, and an inorganic nano-reinforcement material.

A nest with flexural self-alignment features for receiving and aligning a model. The model is provided is a pair of V grooves that engage a pair of alignment pins of the nest. One of the alignment pins is movable and is connected to a near-infinite-life spring loaded flexure.

An oral appliance (OA) made as add-on optional feature in a denture of a user with or without implants to facilitate adjustable mandibular advancement assisting in partially or fully reducing snoring and thus ameliorating obstructive sleep apnea (OSA). The mandibular advancement is realized by deployment of pins in the denture set, and a set of straps that may have optional features such as recess, reinforcement, and the OA may be made of bio-compatible materials using several manufacturing approaches including 3D printing, molding, or milling. An optional additional process comprises of economical production of a similar or alternatively simpler, lighter secondary unit that may be offered to a patient ordering a primary denture, at a discounted price that may serve the purpose of cosmetic function as well as anti-snoring function.

A dental guidance assembly that includes: (a) a rigid body comprising at least one tooth-shaped recess and a coupling structure; and (b) at least two dental bur guides that are each: structured to securely and removably couple to a coupling structure, and having an elongated slot having the following measurements: a length of 4 to 40 millimeters, a width of 1 to 4 millimeters, and a depth of 2 to 10 millimeters. The elongated slot extends along a portion of a circumference of a treated tooth, wherein the elongated slots of the at least two dental bur guides have complementary structures, such that, together, the elongated slots are configured to facilitate a limitation of the motion of a dental bur to: an entirety of the circumference of a treated tooth, and a depth suitable to form a shoulder on the treated tooth, for receiving a dental restoration.

A device (1) for spinning a 3D printed workpiece (100). The device has a rotor (2) for spinning about a spinning axis (A) and a receptacle (8) for holding the workpiece (100). The receptacle (8) is pivotally attached to the rotor (2) for swiveling about a swivel axis (B) that is transverse to the spinning axis (A). The pivotal attachment enables swiveling of the receptacle (8) between a first angular orientation relative to the spinning axis (A) and a different second angular orientation relative to the spinning axis (A). The device (1) further has a balancing weight (9) that is movably arranged relative to the receptacle (8). The balancing weight (9) is lockable at different distances relative to the receptacle (8).

Various implant analogs and dental modeling techniques are disclosed herein. The implant analogs are versatile and can be used in traditional modeling techniques or in rapid-prototyping techniques for producing dental models.

The present invention relates to a method for designing a dental restoration, comprising the steps of determining (S101) a target data set based on a natural tooth which reflects the optical properties and/or the geometry of the natural tooth; generating (S102) a digital tooth model with an internal architecture; rendering (S103) the digital tooth model based on the internal architecture to generate an actual data set representing the optical properties and/or the geometry of the digital tooth model; calculating (S104) a deviation between the target data set and the actual data set; and iteratively altering (S105) the digital tooth model to obtain a smaller deviation between the detected target data set and the actual data set of the re-rendered digital tooth model.

The present invention relates to a method of producing a dental restoration, comprising the steps of: generating (S101) a digital tooth model having a first spatial region in which a first restoration material is disposed and a second spatial region in which a second restoration material is disposed; rendering (S102) the digital tooth model to generate an actual data set representing optical properties of the digital tooth model; determining (S103) a deviation between a target data set and the actual data set; altering (S104) at least one of the first spatial region and the second spatial region to obtain a smaller deviation between the detected target data set and the actual data set of the re-rendered digital tooth model; and producing (S105) the dental restoration based on the digital tooth model having the smaller deviation.

The present invention relates to a method for fabricating a dental restoration, comprising the steps of rendering (S101) a first digital tooth model with a first material combination for generating a first actual data set representing the optical properties of the first digital tooth model; determining (S102) a first deviation between a target data set and the first actual data set; rendering (S103) a second digital tooth model based on a second combination of materials to generate a second actual data set representing the optical properties of the second digital tooth model; determining (S104) a second deviation between the target data set and the second actual data set; and fabricating (S105) the dental restoration based on the first digital tooth model when the first deviation is less than the second deviation and fabricating the dental restoration based on the second digital tooth model when the second deviation is less than the first deviation.

The present invention relates to a method for comparing three-dimensional dental structures, comprising the steps of acquiring (S101) a target data set representing the shape and optical properties of a natural tooth; rendering (S102) a digital tooth model (200) to generate an actual data set representing the shape and optical properties of the digital tooth model; determining (S104) a first comparison value from the actual data set; determining (S105) a second comparison value from the target data set; and determining (S106) a deviation based on the first and second comparison values.