Made of a durable and auto-claveable material including a handle portion of the intra-oral tongue/cheek retractor with a mirror device with an offset in the handle, with a handle flat surface on the mirror side, and with a retention end of handle; at least one mirror or mirrored surface; and a manner for securing/holding or having a mirror or mirrored surface to the handle flat surface on the mirror side where the device can free-up hands of a professional and/or an assistant; can remove any extra “hardware” in a mouth of a patient; provides better visual feedback from the mouth of the patient to the professional; is useable for dental procedures and oral surgery; and is sterilizable in conventional dental or surgical machines.

Made of a durable and auto-claveable material including a handle portion of the intra-oral tongue/cheek retractor with a mirror device with an offset in the handle, with a handle flat surface on the mirror side, and with a retention end of handle; at least one mirror or mirrored surface; and a manner for securing/holding or having a mirror or mirrored surface to the handle flat surface on the mirror side where the device can free-up hands of a professional and/or an assistant; can remove any extra “hardware” in a mouth of a patient; provides better visual feedback from the mouth of the patient to the professional; is useable for dental procedures and oral surgery; and is sterilizable in conventional dental or surgical machines.

The present invention generally relates to a dental intraoral scanner system. In detail, the present invention includes: a scan unit sequentially imaging an intraoral structure in a scan mode; a control unit generating a three-dimensional modeling image for each scan mode by using the imaged intraoral structure; and a display unit displaying the three-dimensional modeling image, wherein the control unit switches the scan unit from a present scan mode to a following scan mode according to a user's command that is input through the scanning unit, or automatically switches from the present scan mode to the following scan mode when a three-dimensional modeling image of the present scan mode is completed.

Disclosed is a dental treatment instrument including a bridge unit configured to be gripped by a user; a plurality of tip units configured to be replaceable with respect to the bridge unit; and a coupling unit configured to selectively couple the tip unit with the bridge unit. The coupling unit is configured to couple the tip unit with the bridge unit by inserting and thereby rotating a portion of the tip unit relative to the bridge unit. Through this configuration, various types of dental tips may be easily replaced based on a selection of a user.

Disclosed is a dental treatment instrument including a bridge unit configured to be gripped by a user; a plurality of tip units configured to be replaceable with respect to the bridge unit; and a coupling unit configured to selectively couple the tip unit with the bridge unit. The coupling unit is configured to couple the tip unit with the bridge unit by inserting and thereby rotating a portion of the tip unit relative to the bridge unit. Through this configuration, various types of dental tips may be easily replaced based on a selection of a user.

A finger engagement assembly for supporting a handheld dental tool on a user's hand. The finger engagement assembly includes a mounting member with a cylindrical shaped body extending along a grip axis and having an aperture extending there through. The mounting member has an inner surface that interfaces with a dental tool and an outer surface that interfaces with a finger engagement. The finger engagement includes a rotational coupling extending about the mounting member and is operable to rotate relative to the mounting member about the grip axis. A post extends from the rotational coupling in a first direction and supports a crossbar. The crossbar extends across the backs of a user's index and middle finger and is functional to retain a handheld dental tool, such as a dental mirror, to a user's hand, while allowing the dental tool to rotate relative to the finger engagement.

A finger engagement assembly for supporting a handheld dental tool on a user's hand. The finger engagement assembly includes a mounting member with a cylindrical shaped body extending along a grip axis and having an aperture extending there through. The mounting member has an inner surface that interfaces with a dental tool and an outer surface that interfaces with a finger engagement. The finger engagement includes a rotational coupling extending about the mounting member and is operable to rotate relative to the mounting member about the grip axis. A post extends from the rotational coupling in a first direction and supports a crossbar. The crossbar extends across the backs of a user's index and middle finger and is functional to retain a handheld dental tool, such as a dental mirror, to a user's hand, while allowing the dental tool to rotate relative to the finger engagement.

A cavity illumination system according to the present disclosure may include one or more illumination elements composed of a transparent or semi-transparent, biocompatible sterilizable polymer and one or more illumination sources. The sterilizable polymer operates as a waveguide. An illumination element may incorporate micro structured optical components such as for example gratings, prisms and or diffusers to operate as precision optics for customized delivery of the light energy. The micro structured optical components may also be used to polarize and/or filter the light energy entering or exiting the illumination element.

A cavity illumination system according to the present disclosure may include one or more illumination elements composed of a transparent or semi-transparent, biocompatible sterilizable polymer and one or more illumination sources. The sterilizable polymer operates as a waveguide. An illumination element may incorporate micro structured optical components such as for example gratings, prisms and or diffusers to operate as precision optics for customized delivery of the light energy. The micro structured optical components may also be used to polarize and/or filter the light energy entering or exiting the illumination element.

A dental imager includes an elongated handle with a rotatable head coupled to a distal end thereof and having a central platform with a plurality of arcuate scanning arms pivotally coupled thereto by a hinge. The arcuate scanning arms are of a shape and size for general deployment around a tooth and each include at least one scanner and a roller guide that comfortably rolls along the surface of the tooth or gums to bias the scanners a desired distance from the surface of the tooth, conducive for imaging thereof. In this respect, such a dental imager may be used in a process to scan and record the contours of an intraoral surface, the data of which may be used to create a digital three-dimensional surface impression printable by a 3D printer or the like.