| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 41 | Bone-adaptive surface structure | US12857203 | 2010-08-16 | US08647117B2 | 2014-02-11 | Stefan Ihde |
| The invention concerns bone-adaptive surface structures for lateral jaw implants. Micromechanical and/or macromechanical surface structures having various body forms are incorporated into selected segments of the surface of the base and of the bar that connects the threaded piece with the base to accelerate the healing process after the implant is inserted into the jaw bone and to make a critical improvement in holding the implant firmly in place without rotation. | ||||||
| 42 | Method for preparing an implant site and laterally inserting a dental implant | US13401080 | 2012-02-21 | US08430669B2 | 2013-04-30 | Carl E. Misch |
| A method of positioning a dental implant in a jaw bone using a piezoelectric cutting tool is provided. Ultrasonic vibration is generated with the piezoelectric cutting tool. The piezoelectric cutting tool is translated in a lateral direction to form a first cut into the jaw bone and to form a second cut into the jaw bone. The second cut intersects the first cut to define a multi-slotted aperture in the jaw bone for receiving at least one dental implant. The dental implant is inserted in the multi-slotted aperture from the lateral direction. | ||||||
| 43 | Bionic dental implant | US12595270 | 2008-04-03 | US08333591B2 | 2012-12-18 | Daguo Zhao |
| A bionic dental implant includes a main root (1), a basal platform (2) and a platform bolt (3). The main root (1) includes a fixing root part (11), a neck part (12) located on the upper end of the fixing root part (11), and a mounting channel (13) located inside the main root (1). An aperture (21) is provided inside the basal platform (2). The platform bolt (3) communicates with the aperture (21) to make the basal platform (2) to be fixed on the main root (1). The main root (1) also includes at least one subsidiary root (4). The main root (1) has the same number of inclined holes (14) as the subsidiary root. The inclined holes (14) form a sharp angle with respect to the mounting channel (13) and communicates with it. The upper ends of the subsidiary roots (4) are fixed inside the inclined holes (14) of the main root. | ||||||
| 44 | Dental implant systems and methods | US12694911 | 2010-01-27 | US08287278B2 | 2012-10-16 | James C. Grant |
| A dental implant system includes a base member that is adapted to be embedded within a patient's jawbone at a treatment site. The base member has a generally flat top side defining an outer periphery, a bottom side, a central opening, and at least one screw hole positioned between the central opening and the outer periphery. The system also includes an implant screw that is adapted to pass through the central opening of the base member and into the patient's jawbone. The system further includes a securing screw that is smaller in size than the implant screw and has a head and a threaded end. The threaded end of the securing screw passes through the screw hole of the base member and into the patient's jawbone. | ||||||
| 45 | Implant, in particular jaw implant, with different material properties | US12226505 | 2007-04-19 | US08277220B2 | 2012-10-02 | Frank-Peter Spahn |
| The invention relates to an implant (1), particularly a jaw implant, which comprises several structural zones (5, 6, 12) made of a material which is non-resorbable, particularly from bones, for the implantation on bones or at least in the vicinity of bones. In an advantageous further embodiment of the implant, two or more of said structural zones (5, 6, 12) have respectively different material properties, in particular different physical properties such as different deformation and/or strength properties. The invention also relates to a method for determining load-dependent deformations in different bone regions, according to which X-ray images of the bone regions are taken with and without mechanical load for comparison. By comparing the X-ray images taken of the individual bone regions under or without load, the resulting deformation can be determined due to the applied load. | ||||||
| 46 | LATERAL IMPLANT SYSTEM AND APPARATUS FOR REDUCTION AND RECONSTRUCTION | US13017370 | 2011-01-31 | US20110166572A1 | 2011-07-07 | Stefan Ihde |
| A bone fixation apparatus and method includes basal implants dimensioned to be installed in bone through lateral insertion into a T-shaped slot. The implants serve as anchors for mounting plates to be placed on either side of a fracture. The mounting plates or anchors may be a mount to which a stabilizing fixation rod, plate, prosthesis, dental prosthesis or other mesiostructure is attached. | ||||||
| 47 | Screw implant apparatus and method | US11788985 | 2007-04-23 | US07909605B2 | 2011-03-22 | Stefan Ihde |
| An enossal screw implant is inserted cortically into the jawbone as an implant base and a mount for the superstructure of a tooth replacement or a substructure. A break point is provided in the abutment head above a bending zone. Key surfaces are above and below the break point. Solutions to ease adjustment of the inserted implant to the natural tooth position and which can reduce the danger of loosening of the inserted implant in the jawbone are coated on the implant. | ||||||
| 48 | BONE-ADAPTIVE SURFACE STRUCTURE | US12857203 | 2010-08-16 | US20100316971A1 | 2010-12-16 | Stefan Ihde |
| The invention concerns bone-adaptive surface structures for lateral jaw implants. Micromechanical and/or macromechanical surface structures having various body forms are incorporated into selected segments of the surface of the base and of the bar that connects the threaded piece with the base to accelerate the healing process after the implant is inserted into the jaw bone and to make a critical improvement in holding the implant firmly in place without rotation. | ||||||
| 49 | LATERALLY INSERTED DENTAL IMPLANT ASSEMBLY AND METHOD FOR SECURING A DENTAL PROSTHESIS | US12468522 | 2009-05-19 | US20100297584A1 | 2010-11-25 | Carl E. Misch |
| A dental implant assembly kit and method for insertion into a bone, the assembly serving to support a dental prosthesis or other dental structure. The assembly includes a base plate having a bone-facing surface and a pillar-supporting surface that defines an off-center region; a ledge depending from the bone-facing surface of the basal plate; and a pillar extending from the off-center region of the pillar-supporting surface of the basal plate. | ||||||
| 50 | Custom-fit implant surgery guide and associated milling cutter, method for their production, and their use | US11579533 | 2005-05-03 | US07824181B2 | 2010-11-02 | Laurent Sers |
| The invention relates to a custom-fit implantable surgical guide (1) and an associated milling tool (4), which is positioned in straddling on the alveolar ridge (7) of a maxillary or mandible arch (2) and comprises at least one drilling barrel (11) for axially guiding said milling tool (4), wherein said barrel (11) is laterally open and at least one part of the internal surface thereof (17) and at least one part of the external surface of the milling tool (4) interact and axially maintain the entire milling tool (4) with respect to the barrel (11). Said invention makes it possible to carry out high precision osteotomies for lateral insertion dental implants. | ||||||
| 51 | Bone-adaptive surface structure | US10714200 | 2003-11-14 | US07775796B2 | 2010-08-17 | Stefan Ihde |
| The invention concerns bone-adaptive surface structures for lateral jaw implants. Micromechanical and/or macromechanical surface structures having various body forms are incorporated into selected segments of the surface of the base and of the bar that connects the threaded piece with the base to accelerate the healing process after the implant is inserted into the jaw bone and to make a critical improvement in holding the implant firmly in place without rotation. | ||||||
| 52 | DENTAL IMPLANT SYSTEMS AND METHODS | US12694911 | 2010-01-27 | US20100159419A1 | 2010-06-24 | James C. Grant |
| A dental implant system comprises a base member that is adapted to be embedded within a patient's jawbone at a treatment site. The base member has a generally flat top side defining an outer periphery, a bottom side, a central opening, and at least one screw hole positioned between the central opening and the outer periphery. The system also includes an implant screw that is adapted to pass through the central opening of the base member and into the patient's jawbone. The system further includes a securing screw that is smaller in size than the implant screw and has a head and a threaded end. The threaded end of the securing screw passes through the screw hole of the base member and into the patient's jawbone. | ||||||
| 53 | BIONIC DENTAL IMPLANT | US12595270 | 2008-04-03 | US20100055646A1 | 2010-03-04 | Daguo Zhao |
| Abstract A bionic dental implant. The bionic dental implant includes a main root (1), a basal platform (2) and a platform bolt (3). The said main root (1) includes a fixing root part (11), a neck part (12) located on the upper end of the fixing root part (11), and a mounting channel (13) located inside the main root (1). An aperture (21) is provided inside the basal platform (2). The platform bolt (3) communicates with the aperture (21) to make the basal platform (2) to be fixed on the main root (1). The said main root (1) also includes at least one subsidiary root (4). The main root (1) has the same number of inclined holes (14) as the subsidiary root the said inclined holes (14) form a sharp angle with respect to the mounting channel (13) and communicates with it. The upper ends of the said subsidiary roots (4) are fixed inside the inclined holes (14) of the main root. | ||||||
| 54 | ARTIFICIAL TEETHRIDGE AND FANG | US12524361 | 2008-01-28 | US20100035207A1 | 2010-02-11 | Lieh-Tang Chen |
| A structure of the artificial teethridge and fang includes an artificial teethridge which has an arched top and an arched bottom, wherein the top and the bottom of the artificial teethridge are curved toward the same direction. The thickness of the artificial teethridge is relatively thicker at central part and gradually becomes thinner toward two lateral sides. A fang is installed on the top and the fang has a narrower fang top and a wider fang bottom, whereby the artificial teethridge and the fang form a mechanical conduction structure. The bottom surface of the artificial teethridge has a complementary structure which can be tightly matched and fixed on each point of the top surface of the alveolar bone without any gap, whereby the bottom of the artificial teethridge further includes a fastening fixture. | ||||||
| 55 | Lateral implant system and apparatus for reduction and reconstruction | US11506614 | 2006-08-18 | US20070055254A1 | 2007-03-08 | Stefan Ihde |
| A bone fixation apparatus and method includes basal implants dimensioned to be installed in bone through lateral insertion into a T-shaped slot. The implants serve as anchors for mounting plates to be placed on either side of a fracture. The mounting plates or anchors may be a mount to which a stabilizing fixation rod, plate, prosthesis, dental prosthesis or other mesiostructure is attached. | ||||||
| 56 | Dental implants with improved loading properties | US11328815 | 2006-01-09 | US20060154205A1 | 2006-07-13 | John Reggie |
| A dental prosthetic includes an elongate threaded implant adapted to be secured within the trabecular region of a maxilla or mandible. An abutment having a first region adapted to receive a crown and a second region adapted for coupling to the elongate threaded implant is secured to the elongate threaded implant. The abutment and elongate threaded implant extend generally along a common longitudinal axis. A compliant brace is adapted for placement between the first region of the abutment and the elongate threaded implant. The compliant brace includes first, second, and third elongate extensions capable of engaging the cortical region of the maxilla or mandible, thereby minimizing micromotion and allowing for osseointegration despite immediate installation of a crown and immediate mechanical loading. The dental prosthetic may also include an adaptor for coupling the elongate threaded implant and the abutment. Methods for implanting dental prosthetics are also described. | ||||||
| 57 | Dental implants with improved loading properties | US11035312 | 2005-01-12 | US20060154204A1 | 2006-07-13 | John Reggie |
| A dental prosthetic comprising an elongate threaded implant adapted to be secured within the trabecular region of a maxilla or mandible. An abutment is secured to the elongate threaded implant and adapted to receive a crown. The abutment and elongate threaded implant extend generally along a common longitudinal axis. A generally flat surface is secured to a region where the abutment meets the implant and extends generally perpendicular to the axis of the abutment and implant. The generally flat surface is shaped to engage the cortical region of the maxilla or mandible, and thereby minimize micromotion and allow for osseointegration despite immediate installation of a crown and immediate mechanical loading. Methods for implanting dental prosthetics are also described. | ||||||
| 58 | Method and apparatus for dental implants | US10395373 | 2003-03-24 | US07056117B2 | 2006-06-06 | Earl Wayne Simmons, Jr. |
| A dental apparatus and method of dental reconstruction are provided in which a base (24) is set (112) into or on a jawbone, and one or more stabilizers (26) couple the base (24) to the jawbone. A dental fixture (86) is coupled (114) to the base (24). Also provided are one-piece dental implants (120 and 132). | ||||||
| 59 | Dental implant and method of insertion | US10163034 | 2002-06-05 | US06991463B2 | 2006-01-31 | Stefan Ihde |
| A one-piece dental implant for endosteal and combined endosteal/subperiosteal osseointegration includes a force-transferring foot part for insertion into a jaw, the foot part including a frame in a closed geometric form having an interior open area and at least one bar connected with the frame and extending into the interior open area of the geometric form, said geometric form including at least a partial ring shape; a post that projects out of the jaw, said post connected with the foot part through the bar; and wherein a profile of the bar has a first height at a first transition region where it connects with the closed frame and a second height, which is greater than the first height, at a second transition region where it connects with the post, the height of the bar tapering from the second height to the first height.A method of inserting the disclosed one-piece dental implant for endosteal and combined endosteal/subperiosteal osseointegration into an alveolar bone with a vestibular side and a palatal side includes the steps of providing a one-piece dental implant having a force-transferring foot part for insertion into the alveolar bone and a post that projects out of the alveolar bone; inserting the dental implant into the vestibular side of the alveolar bone; securely engaging the dental implant in the palatal side of the alveolar bone, leaving a part of the dental implant protruding from the vestibular side of the alveolar bone; bending and adapting the protruding part of the dental implant to the vestibular side of the alveolar bone; and trimming extraneous parts of the dental implant. | ||||||
| 60 | Expandable polymer dental implant and method of use | US11033190 | 2005-01-11 | US20050260541A1 | 2005-11-24 | Dennis McDevitt |
| Systems and methods for a dental implant system suitable for an endosteal implant into a jawbone are provided. The systems and methods make use of an expandable polymer sheath insertable into a jawbone, an implant insertable into the sheath and causing expansion of the sheath upon insertion, and an abutment adapted to be coupled to the implant and permitting the attachment of a dental prosthesis. | ||||||
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