CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
This document discusses image guided surgery, which uses computer technology and 3D imaging like CT and MRI scans to guide surgical interventions. Key aspects covered include:
- Image guidance allows surgeons to view a patient's anatomy during surgery to locate structures hidden from direct vision.
- Registration aligns the 3D imaging with the patient's actual anatomy using tracking devices and fiducial markers.
- Volume rendering and surface rendering techniques are used to visualize 3D models of the patient's anatomy overlaid during surgery.
- Accuracy depends on factors like registration error and tracking device precision. Image guidance is useful for locating small structures in complex areas like the skull base.
triple scan protocol (Dr. Gross) - a new and effective protocol for 3D planni...Michael Gross
triple scan protocol (Dr. Gross) - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases
Cortex guide - complete service for advanced 3D planning and guided surgery of dental implants
The document discusses the advantages of dental CT imaging over traditional dental radiographs. Dental CT provides accurate multi-planar views of the jaw anatomy, allowing for precise measurement of bone dimensions and identification of vital structures. It indicates dental CT is particularly useful for dental implant planning and assessment of complex dental conditions like tumors, cysts, fractures and trauma. The technique of dental CT involves thin slice imaging of the jaw to generate panoramic and cross-sectional views for detailed evaluation.
This document describes the technique of dental CT imaging. It discusses how dental CT has become an established method for imaging jaw anatomy prior to dental implant placement. The key aspects of the dental CT technique include acquiring high-resolution axial scans of the jaw and generating curved and orthoradial multiplanar reconstructions. The document outlines the specific scanner protocols used in dental CT, including using a small focal spot, thin slices, and dose reduction strategies. It also describes how the data is reconstructed to generate panoramic and orthogonal views of the jaw anatomy and how the images are presented.
CBCT stands for cone beam computed tomography. It is a 3D imaging technique that uses a cone-shaped X-ray beam to capture volumetric images of the teeth, jaws, and surrounding structures. CBCT provides more detailed views than conventional 2D X-rays and exposes patients to less radiation than traditional medical CT scans. It has various applications in dentistry, including implant planning, endodontics, surgery, and orthodontics by allowing visualization of hard tissues and their relationship to anatomical structures.
Hey Guys, this presentation is all that a BDS graduate needs to know. A very basic yet important facts about CBCT.
Stay Safe
Regards
Battisi - Dr. Jasmine Singh
CBCT provides 3D images of the jaws and teeth using low-dose x-rays and computer reconstruction. It allows visualization of bone quality, morphology, and proximity to anatomical structures for applications in dental implant planning, oral surgery, endodontics, orthodontics, and more. CBCT is particularly useful when traditional 2D imaging is limited by anatomical superimposition or inability to assess 3D bone characteristics. Some key uses of CBCT include implant planning, assessment of impacted teeth, maxillofacial trauma, airway imaging, and evaluation of periodontal defects.
CBCT provides high resolution 3D imaging of the maxillofacial region using a low radiation cone-shaped x-ray beam. It acquires full volume data in a single 10 second scan, allowing visualization of hard and some soft tissues from multiple angles. CBCT has numerous applications in dentistry due to its improved accuracy over 2D imaging such as panoramic x-rays. It is useful for implant planning, maxillofacial surgery, orthodontics, temporomandibular joint assessment, trauma cases, and oral pathology diagnosis.
This document discusses image guided surgery, which uses computer technology and 3D imaging like CT and MRI scans to guide surgical interventions. Key aspects covered include:
- Image guidance allows surgeons to view a patient's anatomy during surgery to locate structures hidden from direct vision.
- Registration aligns the 3D imaging with the patient's actual anatomy using tracking devices and fiducial markers.
- Volume rendering and surface rendering techniques are used to visualize 3D models of the patient's anatomy overlaid during surgery.
- Accuracy depends on factors like registration error and tracking device precision. Image guidance is useful for locating small structures in complex areas like the skull base.
triple scan protocol (Dr. Gross) - a new and effective protocol for 3D planni...Michael Gross
triple scan protocol (Dr. Gross) - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases
Cortex guide - complete service for advanced 3D planning and guided surgery of dental implants
The document discusses the advantages of dental CT imaging over traditional dental radiographs. Dental CT provides accurate multi-planar views of the jaw anatomy, allowing for precise measurement of bone dimensions and identification of vital structures. It indicates dental CT is particularly useful for dental implant planning and assessment of complex dental conditions like tumors, cysts, fractures and trauma. The technique of dental CT involves thin slice imaging of the jaw to generate panoramic and cross-sectional views for detailed evaluation.
This document describes the technique of dental CT imaging. It discusses how dental CT has become an established method for imaging jaw anatomy prior to dental implant placement. The key aspects of the dental CT technique include acquiring high-resolution axial scans of the jaw and generating curved and orthoradial multiplanar reconstructions. The document outlines the specific scanner protocols used in dental CT, including using a small focal spot, thin slices, and dose reduction strategies. It also describes how the data is reconstructed to generate panoramic and orthogonal views of the jaw anatomy and how the images are presented.
CBCT stands for cone beam computed tomography. It is a 3D imaging technique that uses a cone-shaped X-ray beam to capture volumetric images of the teeth, jaws, and surrounding structures. CBCT provides more detailed views than conventional 2D X-rays and exposes patients to less radiation than traditional medical CT scans. It has various applications in dentistry, including implant planning, endodontics, surgery, and orthodontics by allowing visualization of hard tissues and their relationship to anatomical structures.
Hey Guys, this presentation is all that a BDS graduate needs to know. A very basic yet important facts about CBCT.
Stay Safe
Regards
Battisi - Dr. Jasmine Singh
CBCT provides 3D images of the jaws and teeth using low-dose x-rays and computer reconstruction. It allows visualization of bone quality, morphology, and proximity to anatomical structures for applications in dental implant planning, oral surgery, endodontics, orthodontics, and more. CBCT is particularly useful when traditional 2D imaging is limited by anatomical superimposition or inability to assess 3D bone characteristics. Some key uses of CBCT include implant planning, assessment of impacted teeth, maxillofacial trauma, airway imaging, and evaluation of periodontal defects.
CBCT provides high resolution 3D imaging of the maxillofacial region using a low radiation cone-shaped x-ray beam. It acquires full volume data in a single 10 second scan, allowing visualization of hard and some soft tissues from multiple angles. CBCT has numerous applications in dentistry due to its improved accuracy over 2D imaging such as panoramic x-rays. It is useful for implant planning, maxillofacial surgery, orthodontics, temporomandibular joint assessment, trauma cases, and oral pathology diagnosis.
This document discusses cone-beam computed tomography (CBCT) and its applications in dental practice. CBCT provides sub-millimeter resolution images of the maxillofacial skeleton in a fraction of the time and radiation dose of conventional CT. It allows reconstruction of 3D volumetric data into multiplanar reformatted images. Specific applications discussed include implant planning, pathology assessment, temporomandibular joint imaging, and orthodontics. Advanced display modes like curved planar reformation and volume rendering provide familiar views useful for clinical evaluation and measurement.
This document provides information on cone beam computed tomography (CBCT) imaging in dentistry. It discusses the principles of CBCT, including X-ray generation and detection, image reconstruction, and clinical considerations for protocols. CBCT uses a cone-shaped X-ray beam and area detector to create a 3D volume of the region of interest with less radiation than medical CT. It has various applications in dentistry for implant planning, orthodontic assessment, and pathology diagnosis. Potential artifacts are also described.
This article reviews the clinical applications of cone beam computed tomography (CBCT) in dentistry as described in 129 peer-reviewed publications from 1998 to 2010. The literature review found that CBCT has been used for oral and maxillofacial surgery, endodontics, implant dentistry, orthodontics, temporomandibular joint disorders, periodontics, and forensic dentistry. Specifically, CBCT provides advantages over 2D imaging such as a lack of superimposition, accurate measurements, and 3D visualization which has made it useful for applications like dental trauma assessment, implant planning, endodontic diagnosis, and orthognathic surgery planning.
CBCT provides high quality 3D images that allow for more accurate implant planning compared to traditional 2D radiography. It allows visualization of anatomical structures in multiple planes, and accurate measurements. While it provides more information, inexperienced clinicians may misinterpret data. CBCT is recommended for implant planning in aesthetic zones, complex cases, and when vital anatomy needs to be assessed. Virtual planning with CBCT can be used to determine grafting needs, tumor resection plans, and angled implant positions to avoid lifting sinus floors.
This document provides an overview of cone beam computed tomography (CBCT) including its history, components, principles, and applications in dentistry. Some key points:
- CBCT was first introduced in the 1990s and provides 3D imaging with lower radiation dose than medical CT. It works by generating a cone-shaped X-ray beam and using a detector to record attenuation data, which is then reconstructed into 3D images.
- Components include an X-ray generator, image sensor, and software for image reconstruction. Images are stored in DICOM format.
- Advantages include rapid scan time, interactive display modes, and ability to view structures in multiple planes. Disadvantages include potential artifacts and inability to view
CBCT imaging provides 3D imaging of the dental and maxillofacial complex, allowing for improved diagnosis and treatment planning. It involves rotating an x-ray source and detector to capture projection images from different angles, which are then reconstructed into a 3D volume using back projection algorithms. Key components include the x-ray generator, detector, and workstation for image reconstruction and display. CBCT has various applications in orthodontics for assessing dental anomalies, impacted teeth, arch discrepancies, and facilitating treatment. Guidelines recommend its use be justified based on the individual clinical situation and that radiation dose be minimized.
(1) Cone Beam Computed Tomography (CBCT) provides 3D imaging that can be used for evaluating dental anatomy, complex root morphologies, and assessing endodontic treatment complications. (2) The American Association of Endodontists (AAE) and American Association of Oral and Maxillofacial Radiology (AAOMR) have listed potential uses of CBCT in selected cases including differential diagnosis, presurgical case planning, and evaluation of dental trauma or resorptive lesions. (3) CBCT can provide improved visualization over traditional 2D imaging for tasks like locating fractures, separated instruments, root perforations, and resorptive defects.
A 24-year-old female presented with facial asymmetry and dental malocclusion. An i-CAT CBCT scan was performed to evaluate the dentition, jaws, and condyles. The scan revealed impacted teeth 28, 36, 38, and 46. Asymmetry was observed between the right and left hemimandibles, with measurements confirming the right side was larger. Features of the condyles were suggestive of condylar hypoplasia on the left side. The i-CAT CBCT provided 3D imaging to revolutionize diagnosis and treatment planning with ultra-low radiation dose.
CBCT has become an important tool in clinical orthodontics for providing 3D information. It was developed due to increasing demand for 3D data from conventional CT scans. This article discusses CBCT technology and its various uses in orthodontics such as detection of facial asymmetry, assessment of mandibular shape and growth, localization of impacted teeth, evaluation of root resorption and airway changes. CBCT allows more accurate diagnosis and treatment planning compared to 2D radiographs and has largely replaced conventional records in digital orthodontic records.
CBCT provides high resolution 3D imaging of the maxillofacial region with lower radiation dose compared to medical CT. It has become an important tool in dentistry since its introduction in the late 1990s. CBCT works by taking X-ray images of the head from different angles and using complex algorithms to reconstruct 3D volumetric images. While it offers advantages over 2D imaging, CBCT is also subject to various artifacts from beam hardening, metal objects, and patient movement. Proper use and understanding of these limitations is important for accurate interpretation of CBCT scans.
Three-dimensional (3D) computer-assisted surgical simulation and navigation can improve the accuracy of orthognathic surgery planning and execution over traditional 2D techniques. The document reviews literature on 3D modeling techniques including cone beam CT imaging, virtual surgical planning, and methods for transferring virtual plans to surgery using splints, guides or navigation. Key benefits of 3D methods include more accurate simulation of bone movements, simplified intraoperative positioning, elimination of human errors, and improved aesthetic outcomes.
Cone beam computed tomography.DR. ANUBHUTI Dental Institute RIMS Anubhuti Singh
Cone beam computed tomography
Carm CT
Cone beam volume CT
Flat panel CT
Extra-oral imaging system specifically designed for three dimensional imaging of the oral and maxillofacial structures
ALARA Principle
Principal of cbct- Field of view
voxel
This document discusses dental cone beam CT (CBCT). It provides information on how CBCT works, its advantages over panoramic imaging and conventional CT, examples of its applications in dental imaging, and some shortcomings. CBCT provides volumetric data using a cone-shaped x-ray beam and flat panel detector, giving superior images to panoramic x-rays at a lower radiation dose than conventional CT. It is well-suited for uses like implant planning, tumor detection, and airway visualization.
Cone beam computed tomography (CBCT) uses a cone-shaped x-ray beam projected through the area of interest and a 2D detector to acquire multiple 2D radiographic images at different angles. These images are then used to reconstruct 3D volumetric images. CBCT has applications in dentistry for implant planning, endodontics, orthodontics and TMJ imaging due to its ability to provide high contrast images of bony structures at a lower radiation dose compared to medical CT. Some limitations include artifacts from metallic restorations, lower soft tissue contrast and isotropic resolution compared to medical CT.
CBCT imaging allows dentists to visualize anatomy in 3 dimensions. It has many applications including implant planning, assessing impacted teeth, orthodontic evaluation, and examining maxillofacial trauma and lesions. CBCT provides important information such as bone quantity and quality, location of vital structures, and relationship of pathologies to surrounding tissues. It also allows for accurate pre-surgical planning through tools like radiographic tracing and implant simulation. CBCT has advantages over medical CT such as smaller size, lower radiation dose, and software tailored for dentistry.
The Carestream 8100 3D. High resolution, low radiation
By utilizing cone beam CT technology, the CS 8100 3D produces a significantly lower radiation dose than the average CT system—making it a safe choice for patients. In addition, the unit’s four selectable fields of view and fast scanning mode confine radiation to the area of interest and reduce length of exposure for further safety. At the same time, the system delivers ultra-high resolution images up to 75μm to ensure you have all the details you need to make an accurate and confident diagnosis—particularly for endodontic procedures.
Dental CT imaging is a technique developed in 1987 to image the complex jaw bone structures. It involves acquiring high resolution axial CT scans of the jaw and using reconstruction software to generate panoramic and cross-sectional views for examination of jaw anatomy and implant planning. Dental CT provides detailed images of teeth, bone quality, anatomy, and any pathologies present to aid in dental procedures and implant placement. Reformatted views allow evaluation of bone cortices and precise measurements for implant planning and simulation.
This document summarizes the potential applications of cone beam computed tomography (CBCT) in forensic science based on a review of clinical and scientific literature. CBCT can be used for age and sex estimation, frontal sinus analysis for identification, and 3D facial reconstruction. Studies show CBCT allows for more accurate age estimation compared to 2D radiographs. Measurements of bones like the mastoid and mandible from CBCT scans can determine sex with over 80% accuracy. Comparison of frontal sinus patterns through CBCT provides reliable evidence for identification. While CBCT has advantages like portability and accuracy, limitations include artifacts from metals and limited soft tissue contrast. Further research is still needed to improve 3D reconstruction techniques from CBCT data for forensic
The document summarizes the history and technology of computed tomography (CT). It describes how CT was invented in the 1970s by Godfrey Hounsfield and sparked a revolution in medical imaging. It provides insights into the evolution of CT technology over time, from early sequential CT scanners to current spiral CT systems. CT has advanced to become an indispensable medical imaging tool that provides detailed cross-sectional views of the body.
Head pathologies and protocols /certified fixed orthodontic courses by Indian...Indian dental academy
The Indian Dental Academy is the Leader in continuing dental education , training dentists in all aspects of dentistry and offering a wide range of dental certified courses in different formats.
Indian dental academy provides dental crown & Bridge,rotary endodontics,fixed orthodontics,
Dental implants courses.for details pls visit www.indiandentalacademy.com ,or call
00919248678078
This document discusses cone-beam computed tomography (CBCT) and its applications in dental practice. CBCT provides sub-millimeter resolution images of the maxillofacial skeleton in a fraction of the time and radiation dose of conventional CT. It allows reconstruction of 3D volumetric data into multiplanar reformatted images. Specific applications discussed include implant planning, pathology assessment, temporomandibular joint imaging, and orthodontics. Advanced display modes like curved planar reformation and volume rendering provide familiar views useful for clinical evaluation and measurement.
This document provides information on cone beam computed tomography (CBCT) imaging in dentistry. It discusses the principles of CBCT, including X-ray generation and detection, image reconstruction, and clinical considerations for protocols. CBCT uses a cone-shaped X-ray beam and area detector to create a 3D volume of the region of interest with less radiation than medical CT. It has various applications in dentistry for implant planning, orthodontic assessment, and pathology diagnosis. Potential artifacts are also described.
This article reviews the clinical applications of cone beam computed tomography (CBCT) in dentistry as described in 129 peer-reviewed publications from 1998 to 2010. The literature review found that CBCT has been used for oral and maxillofacial surgery, endodontics, implant dentistry, orthodontics, temporomandibular joint disorders, periodontics, and forensic dentistry. Specifically, CBCT provides advantages over 2D imaging such as a lack of superimposition, accurate measurements, and 3D visualization which has made it useful for applications like dental trauma assessment, implant planning, endodontic diagnosis, and orthognathic surgery planning.
CBCT provides high quality 3D images that allow for more accurate implant planning compared to traditional 2D radiography. It allows visualization of anatomical structures in multiple planes, and accurate measurements. While it provides more information, inexperienced clinicians may misinterpret data. CBCT is recommended for implant planning in aesthetic zones, complex cases, and when vital anatomy needs to be assessed. Virtual planning with CBCT can be used to determine grafting needs, tumor resection plans, and angled implant positions to avoid lifting sinus floors.
This document provides an overview of cone beam computed tomography (CBCT) including its history, components, principles, and applications in dentistry. Some key points:
- CBCT was first introduced in the 1990s and provides 3D imaging with lower radiation dose than medical CT. It works by generating a cone-shaped X-ray beam and using a detector to record attenuation data, which is then reconstructed into 3D images.
- Components include an X-ray generator, image sensor, and software for image reconstruction. Images are stored in DICOM format.
- Advantages include rapid scan time, interactive display modes, and ability to view structures in multiple planes. Disadvantages include potential artifacts and inability to view
CBCT imaging provides 3D imaging of the dental and maxillofacial complex, allowing for improved diagnosis and treatment planning. It involves rotating an x-ray source and detector to capture projection images from different angles, which are then reconstructed into a 3D volume using back projection algorithms. Key components include the x-ray generator, detector, and workstation for image reconstruction and display. CBCT has various applications in orthodontics for assessing dental anomalies, impacted teeth, arch discrepancies, and facilitating treatment. Guidelines recommend its use be justified based on the individual clinical situation and that radiation dose be minimized.
(1) Cone Beam Computed Tomography (CBCT) provides 3D imaging that can be used for evaluating dental anatomy, complex root morphologies, and assessing endodontic treatment complications. (2) The American Association of Endodontists (AAE) and American Association of Oral and Maxillofacial Radiology (AAOMR) have listed potential uses of CBCT in selected cases including differential diagnosis, presurgical case planning, and evaluation of dental trauma or resorptive lesions. (3) CBCT can provide improved visualization over traditional 2D imaging for tasks like locating fractures, separated instruments, root perforations, and resorptive defects.
A 24-year-old female presented with facial asymmetry and dental malocclusion. An i-CAT CBCT scan was performed to evaluate the dentition, jaws, and condyles. The scan revealed impacted teeth 28, 36, 38, and 46. Asymmetry was observed between the right and left hemimandibles, with measurements confirming the right side was larger. Features of the condyles were suggestive of condylar hypoplasia on the left side. The i-CAT CBCT provided 3D imaging to revolutionize diagnosis and treatment planning with ultra-low radiation dose.
CBCT has become an important tool in clinical orthodontics for providing 3D information. It was developed due to increasing demand for 3D data from conventional CT scans. This article discusses CBCT technology and its various uses in orthodontics such as detection of facial asymmetry, assessment of mandibular shape and growth, localization of impacted teeth, evaluation of root resorption and airway changes. CBCT allows more accurate diagnosis and treatment planning compared to 2D radiographs and has largely replaced conventional records in digital orthodontic records.
CBCT provides high resolution 3D imaging of the maxillofacial region with lower radiation dose compared to medical CT. It has become an important tool in dentistry since its introduction in the late 1990s. CBCT works by taking X-ray images of the head from different angles and using complex algorithms to reconstruct 3D volumetric images. While it offers advantages over 2D imaging, CBCT is also subject to various artifacts from beam hardening, metal objects, and patient movement. Proper use and understanding of these limitations is important for accurate interpretation of CBCT scans.
Three-dimensional (3D) computer-assisted surgical simulation and navigation can improve the accuracy of orthognathic surgery planning and execution over traditional 2D techniques. The document reviews literature on 3D modeling techniques including cone beam CT imaging, virtual surgical planning, and methods for transferring virtual plans to surgery using splints, guides or navigation. Key benefits of 3D methods include more accurate simulation of bone movements, simplified intraoperative positioning, elimination of human errors, and improved aesthetic outcomes.
Cone beam computed tomography.DR. ANUBHUTI Dental Institute RIMS Anubhuti Singh
Cone beam computed tomography
Carm CT
Cone beam volume CT
Flat panel CT
Extra-oral imaging system specifically designed for three dimensional imaging of the oral and maxillofacial structures
ALARA Principle
Principal of cbct- Field of view
voxel
This document discusses dental cone beam CT (CBCT). It provides information on how CBCT works, its advantages over panoramic imaging and conventional CT, examples of its applications in dental imaging, and some shortcomings. CBCT provides volumetric data using a cone-shaped x-ray beam and flat panel detector, giving superior images to panoramic x-rays at a lower radiation dose than conventional CT. It is well-suited for uses like implant planning, tumor detection, and airway visualization.
Cone beam computed tomography (CBCT) uses a cone-shaped x-ray beam projected through the area of interest and a 2D detector to acquire multiple 2D radiographic images at different angles. These images are then used to reconstruct 3D volumetric images. CBCT has applications in dentistry for implant planning, endodontics, orthodontics and TMJ imaging due to its ability to provide high contrast images of bony structures at a lower radiation dose compared to medical CT. Some limitations include artifacts from metallic restorations, lower soft tissue contrast and isotropic resolution compared to medical CT.
CBCT imaging allows dentists to visualize anatomy in 3 dimensions. It has many applications including implant planning, assessing impacted teeth, orthodontic evaluation, and examining maxillofacial trauma and lesions. CBCT provides important information such as bone quantity and quality, location of vital structures, and relationship of pathologies to surrounding tissues. It also allows for accurate pre-surgical planning through tools like radiographic tracing and implant simulation. CBCT has advantages over medical CT such as smaller size, lower radiation dose, and software tailored for dentistry.
The Carestream 8100 3D. High resolution, low radiation
By utilizing cone beam CT technology, the CS 8100 3D produces a significantly lower radiation dose than the average CT system—making it a safe choice for patients. In addition, the unit’s four selectable fields of view and fast scanning mode confine radiation to the area of interest and reduce length of exposure for further safety. At the same time, the system delivers ultra-high resolution images up to 75μm to ensure you have all the details you need to make an accurate and confident diagnosis—particularly for endodontic procedures.
Dental CT imaging is a technique developed in 1987 to image the complex jaw bone structures. It involves acquiring high resolution axial CT scans of the jaw and using reconstruction software to generate panoramic and cross-sectional views for examination of jaw anatomy and implant planning. Dental CT provides detailed images of teeth, bone quality, anatomy, and any pathologies present to aid in dental procedures and implant placement. Reformatted views allow evaluation of bone cortices and precise measurements for implant planning and simulation.
This document summarizes the potential applications of cone beam computed tomography (CBCT) in forensic science based on a review of clinical and scientific literature. CBCT can be used for age and sex estimation, frontal sinus analysis for identification, and 3D facial reconstruction. Studies show CBCT allows for more accurate age estimation compared to 2D radiographs. Measurements of bones like the mastoid and mandible from CBCT scans can determine sex with over 80% accuracy. Comparison of frontal sinus patterns through CBCT provides reliable evidence for identification. While CBCT has advantages like portability and accuracy, limitations include artifacts from metals and limited soft tissue contrast. Further research is still needed to improve 3D reconstruction techniques from CBCT data for forensic
The document summarizes the history and technology of computed tomography (CT). It describes how CT was invented in the 1970s by Godfrey Hounsfield and sparked a revolution in medical imaging. It provides insights into the evolution of CT technology over time, from early sequential CT scanners to current spiral CT systems. CT has advanced to become an indispensable medical imaging tool that provides detailed cross-sectional views of the body.
Head pathologies and protocols /certified fixed orthodontic courses by Indian...Indian dental academy
The Indian Dental Academy is the Leader in continuing dental education , training dentists in all aspects of dentistry and offering a wide range of dental certified courses in different formats.
Indian dental academy provides dental crown & Bridge,rotary endodontics,fixed orthodontics,
Dental implants courses.for details pls visit www.indiandentalacademy.com ,or call
00919248678078
CT scans also termed as computer tomography, is an imaging test that involves taking the circular images of the body and then produces what a picture on the computer that looks like a slice through the body.
2 d vs. 3d external beam planning in cervical cancer by nelson mandelaKesho Conference
This document compares 2D and 3D treatment planning for cervical cancer patients. It found that using only bony landmarks in 2D planning led to inadequate coverage of the clinical target volume (CTV) in 29 out of 30 patients, with a median CTV coverage of only 95.35%. 3D planning based on computed tomography contouring of the CTV and organs at risk provided much better CTV coverage of 99.55% on average. The study recommends using 3D CT-based planning over conventional 2D planning to improve treatment accuracy for cervical cancer patients.
3-D DIAGNOSIS & TREATMENT PLANNING IN ORTHODONTICS / fixed orthodontics cours...Indian dental academy
The Indian Dental Academy is the Leader in continuing dental education , training dentists in all aspects of dentistry and
offering a wide range of dental certified courses in different formats.for more details please visit
www.indiandentalacademy.com
The Indian Dental Academy is the Leader in continuing dental education , training dentists in all aspects of dentistry and
offering a wide range of dental certified courses in different formats.for more details please visit
www.indiandentalacademy.com
MSCT 640 CHỤP CẮT LỚP ĐỘNG MẠCH VÀNH tại MEDIC HOÀ HẢO VIỆT NAM
Similar to CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
The Indian Dental Academy is the Leader in continuing dental education , training dentists in all aspects of dentistry and
offering a wide range of dental certified courses in different formats.for more details please visit
www.indiandentalacademy.com
The Indian Dental Academy is the Leader in continuing dental education , training dentists in all aspects of dentistry and
offering a wide range of dental certified courses in different formats.for more details please visit
www.indiandentalacademy.com
This document discusses the various uses of computers in orthodontics. It begins with an introduction to computers and their advantages over manual work. It then describes several applications of computers in orthodontic practice, including administrative, clinical, and miscellaneous uses. Specific technologies discussed include computed tomography, digital radiography, 3D imaging, digital study models, computerized tooth width analysis, cephalometric analysis software, and programs for treatment planning and visualization like Invisalign. Overall, the document provides an overview of how computers are transforming various areas of orthodontic practice and care.
Technological advances in dental implant surgeryPeriowiki.com
This document discusses recent technological advances in dental implant surgery, including computer-aided design/computer-aided manufacturing (CAD/CAM) technology and computer-guided implant surgery techniques. It describes computerized tomography (CT) imaging and how CT data can be used for virtual surgical planning and fabrication of surgical guides. The document compares computer-guided implant surgery (CGIS), which uses static surgical guides, to computer-navigated implant surgery (CNIS), which allows for intraoperative modification of the surgical plan. Both techniques aim to increase the accuracy and predictability of dental implant placement.
Fast Track en Cierre de Orejuela. Herramientas para facilitar el procedimient...Fundacion EPIC
This document discusses tools and techniques for facilitating left atrial appendage closure (LAAO) procedures. It provides data on success rates from clinical studies and registries of various LAAO devices. It also outlines a global strategy for LAAO, including recommendations for the pre-procedure, procedure, and post-procedure phases. Examples of specific tools and techniques discussed are imaging planning with CT and TEE, use of ICE and microTEE during the procedure, sedation versus general anesthesia, and techniques for early hospital discharge post-procedure. Two case examples of LAAO procedures are also presented.
This presentation has videos and more surgical aspects of recent advances in Implant dentistry.This is different from other presentations in this platform since it is stuffed with most recent articles and informations
KERARING intrastromal corneal ring segments are the most complete and versatile corneal remodelling system in the World. The precision implantable devices correct corneal surface irregularities and reduce refractive errors associated with keratoconus and other corneal ectatic disorders.
Imaging Sciences International is a global leader in 3D dental imaging technology. Their flagship product is the i-CAT Cone Beam 3D dental imaging system, which provides high definition 3D images using low radiation doses. The i-CAT system allows for improved diagnosis, treatment planning, and surgical outcomes for procedures like implants, orthodontics, and airway analysis compared to traditional 2D imaging.
This document discusses 3D printed medical implants for craniofacial defects. It describes the process of medical reverse engineering using scanning, computer aided design (CAD) to design implants, and computer aided manufacturing (CAM) to 3D print the implants. Examples are given of a 3D printed titanium implant to reconstruct a girl's skull after a car accident, and a 3D printed titanium implant with hydroxyapatite coating to reconstruct an elderly woman's mandible that had extensive bone destruction from osteomyelitis. The advantages of 3D printed patient-specific implants are optimal reconstruction and functional and aesthetic outcomes in a single surgery.
Digital impressions in prosthodontics are emerging as an alternative to traditional elastomeric impressions. Various digital impression systems like CEREC, E4D, iTero, and Lava COS use intraoral scanners with blue or red lasers to optically capture 3D images of the teeth and produce digital models. This eliminates the need for physical impressions and allows for viewing of the occlusion digitally. The digital files can be used to directly mill restorations chairside or be sent to a lab for fabrication. Benefits include accuracy, reduced errors and cross-contamination control compared to conventional impressions. However, the equipment has high costs and requires trained personnel. Overall, digital impressions are expected to become more common
This case report describes a treatment using a surgery-first approach for a Class III malocclusion patient. 3D virtual surgical planning and customized self-ligating brackets were used. Excellent facial and occlusal outcomes were achieved in only 5 months, demonstrating the benefits of combining 3D digital technology, self-ligating brackets, and a surgery-first approach to significantly reduce treatment time. Mandibular setback surgery was performed, followed by placement of the initial archwire during surgery and use of Class III elastics to correct the bite.
DIFOTI (digitally imaged fiber-optic transillumination) is a caries detection method that uses a light probe and digital camera to capture illuminated images of tooth surfaces. A study compared DIFOTI to film and digital radiography for detecting approximal caries lesions using 112 tooth surfaces. Observers examined images from all three methods twice, finding DIFOTI recorded lesion depth more accurately than radiography. Within limitations, DIFOTI showed superior diagnostic accuracy over film and digital radiography for detecting caries.
This document discusses recent advances in implantology. It summarizes improvements in diagnostic imaging technologies like CBCT that provide high-resolution 3D imaging of implant sites. It also discusses advances in implant design, including mini implants less than 3mm in diameter, narrow diameter implants, transitional implants, and one-piece implants that integrate the implant body and abutment. Studies show high survival rates of over 90% for these newer implant designs.
Faster and more confident diagnosis:
• True anatomical details
• Distortion free images, 1:1 anatomical accuracy • Eliminate doubts from 2D exams
Predictability in surgery, improved treatment quality Increased productivity and autonomy
• In-office 3D exams– limit patient visits Improved communication
• Show patients images that are easier to understand Increased treatment plan acceptance.
The advantages at a glance
• Affordable three-in-one solution– 3D, 2D panoramic and optional cephalometric imaging
• Highest resolution (76 μm), low dose 3D images
• Flexible 3D programs– from local exams to full-arch exams
• Compatible with guided surgery systems
Fueling Start-Up Medical Companies through 3D ModelingTriCmarketing
Karl West discusses how 3D printing has helped fuel the start-up of two medical device companies - Centerline Biomedical and Custom Orthopedic Solutions. 3D printing allowed for the creation of prototypes, patient-specific models for surgical planning and training, and customized tools that helped the companies demonstrate their technologies and progress to investors. The models were crucial for visualizing and refining complex anatomical devices and surgical plans in a time-efficient manner. Without 3D printing, the start-up process would have taken significantly longer and incurred greater costs.
This presentation describes indications of intrastromal corneal rings implantation in keratoconus cases and how they are beneficial even in advanced cases.
The document discusses intraoral scanners, their validity and reliability during the pandemic. It notes that intraoral scanners capture precise 3D details of dental impressions digitally, avoiding messy traditional materials. This provides a more convenient experience for patients and clinicians. Studies have found digital impressions to be more accurate than conventional impressions and provide benefits like reduced appointment time and lab costs. Maintaining disinfection of intraoral scanners is important, with tips requiring high-level disinfection between patients according to CDC guidelines. Digital workflows also reduce cross-contamination risks compared to physical impression handling and transportation.
This document discusses the rehabilitation of the atrophic posterior maxilla using pterygoid implants. It provides background on the challenges of posterior maxillary rehabilitation and outlines treatment options like sinus lifts, short implants and tilted implants. It then focuses on the anatomy of the pterygoid region and classifications for pterygoid implants. The document details the surgical protocol for placing pterygoid implants using guides, angled abutments, impressions and final prosthesis placement. It concludes that pterygoid implants provide an alternative to maxillary reconstruction and avoid cantilevers while allowing for immediate loading.
Diagnosis of Vertical Root Fracture Using Digital Radiography, Helical Comput...iosrjce
IOSR Journal of Dental and Medical Sciences is one of the speciality Journal in Dental Science and Medical Science published by International Organization of Scientific Research (IOSR). The Journal publishes papers of the highest scientific merit and widest possible scope work in all areas related to medical and dental science. The Journal welcome review articles, leading medical and clinical research articles, technical notes, case reports and others.
This document discusses 3D diagnostics in orofacial medicine using cone-beam computed tomography (CBCT). It begins by providing background on the development of 3D diagnostics and its limitations in dentistry due to high radiation exposure from traditional CT. The advent of CBCT enabled wider use of 3D diagnostics in dentistry by using a cone-shaped beam and lower radiation doses. CBCT provides high-resolution 3D images, allows for improved surgical planning, and greater understanding of procedures for patients. The document then describes the technical principles and components of CBCT scanning.
Similar to CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants (20)
CrystalGuide guided surgery protocol for Bicon and Quantum implants with use of bone harvesting drills as hand reamers, with ratchet or motor driven. Also standard protocol for other implant systems. CrystalGuide premium CoCr laser sintered surgical guides
more info in facebook
http://www.facebook.com/groups/212785608852432/
CrystalGuide guided surgery protocol for Bicon and Quantum implants with use of bone harvesting drills as hand reamers, with ratchet or motor driven. Also standard protocol for other implant systems. CrystalGuide premium CoCr laser sintered surgical guides
more info in facebook
http://www.facebook.com/groups/212785608852432/
Crystal guide clinical case presentation dr hennenMichael Gross
The document describes the process of digitally planning and guiding the placement of dental implants using 3D imaging and modeling software and customized guides. Key steps included aligning a 3D implant placement model, designing a 5-axis guide, precision casting the guide, and using the guide during surgery along with drill guides to accurately place implants for teeth 31, 42 based on the pre-operative plan. Post-operative x-rays confirmed correct placement of the implants.
CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
Klinische Fallpraesentation CrystalGuide Dr. Danny DomingueMichael Gross
CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
CrystalGuide clinical case Dr. Danny DomingueMichael Gross
This document describes a case report on CrystalGuide, which are laser sintered metal surgical guides for dental implant placement. Key details include:
- CrystalGuide surgical guides are CAD/CAM fabricated from laser sintered CoCr metal for rigidity and stable fit. They are designed with an open structure for optimal sight and cooling during surgery.
- Planning software is provided free of charge and CrystalGuide guides are compatible with all standard guided surgery kits. They can be used for bone-supported reduction guides and drill guides as well as implant placement guides.
- The guides have a flat fee of EUR 280 regardless of the number of implants placed and are distributed through Hess Medizintechnik GmbH in Germany
El documento contiene una lista de medidas y especificaciones para implantes dentales SMARTPLANT del Dr. Gross. Describe las dimensiones de varios implantes SMARTPLANT de 3.5 a 7.5 mm de diámetro y de 6 a 16 mm de longitud. También proporciona información sobre el material y proceso de fabricación de titanio de los implantes, y detalles sobre su diseño y uso como base para cementar abutments individuales de zirconia.
The document contains records from Dr. Gross listing various sizes of SMARTPLANT implants and related components. It describes SMARTPLANT as a biogeneric custom hybrid implant made of titanium and zirconia that can be used to immediately fabricate custom zirconia abutments. Details are provided on dimensions, intended uses, and the DMLS fabrication technique for the titanium implants which have a rough surface investigated to be positive.
The document discusses the benefits of exercise for mental health. Regular physical activity can help reduce anxiety and depression and improve mood and cognitive functioning. Exercise has also been shown to increase gray matter volume in the brain and reduce risks for conditions like Alzheimer's and dementia.
Triple scan Protokoll nach Dr. Gross ein neues und effektives Protokoll für ...Michael Gross
Triple scan Protokoll nach Dr. Gross
ein neues und effektives Protokoll für computer-assistierte 3D-Implantatplanung und guided surgery für transmukosale Implantatinsertion in teilbezahnter Indikation
Cortex guide - kompletter Service für 3D-Implantatplanung neuester Technologie und Herstellung von hochpräzisen surgical guides zu günstigen Preisen
triple scan segun Dr. Gross - un protocolo novedoso y eficiente de planificac...Michael Gross
triple scan segun Dr. Gross - un protocolo novedoso y eficiente de planificacion de implantes en 3D y fabricacion de guias quirurgicas para casos parcialmente edentulosos
Cortex guide - servicio completo de planificacion 3D de implantologia avanzada para cirugia guiada sin colgajo
Knee anatomy and clinical tests 2024.pdfvimalpl1234
This includes all relevant anatomy and clinical tests compiled from standard textbooks, Campbell,netter etc..It is comprehensive and best suited for orthopaedicians and orthopaedic residents.
Ozempic: Preoperative Management of Patients on GLP-1 Receptor Agonists Saeid Safari
Preoperative Management of Patients on GLP-1 Receptor Agonists like Ozempic and Semiglutide
ASA GUIDELINE
NYSORA Guideline
2 Case Reports of Gastric Ultrasound
NVBDCP.pptx Nation vector borne disease control programSapna Thakur
NVBDCP was launched in 2003-2004 . Vector-Borne Disease: Disease that results from an infection transmitted to humans and other animals by blood-feeding arthropods, such as mosquitoes, ticks, and fleas. Examples of vector-borne diseases include Dengue fever, West Nile Virus, Lyme disease, and malaria.
These lecture slides, by Dr Sidra Arshad, offer a quick overview of the physiological basis of a normal electrocardiogram.
Learning objectives:
1. Define an electrocardiogram (ECG) and electrocardiography
2. Describe how dipoles generated by the heart produce the waveforms of the ECG
3. Describe the components of a normal electrocardiogram of a typical bipolar lead (limb II)
4. Differentiate between intervals and segments
5. Enlist some common indications for obtaining an ECG
6. Describe the flow of current around the heart during the cardiac cycle
7. Discuss the placement and polarity of the leads of electrocardiograph
8. Describe the normal electrocardiograms recorded from the limb leads and explain the physiological basis of the different records that are obtained
9. Define mean electrical vector (axis) of the heart and give the normal range
10. Define the mean QRS vector
11. Describe the axes of leads (hexagonal reference system)
12. Comprehend the vectorial analysis of the normal ECG
13. Determine the mean electrical axis of the ventricular QRS and appreciate the mean axis deviation
14. Explain the concepts of current of injury, J point, and their significance
Study Resources:
1. Chapter 11, Guyton and Hall Textbook of Medical Physiology, 14th edition
2. Chapter 9, Human Physiology - From Cells to Systems, Lauralee Sherwood, 9th edition
3. Chapter 29, Ganong’s Review of Medical Physiology, 26th edition
4. Electrocardiogram, StatPearls - https://www.ncbi.nlm.nih.gov/books/NBK549803/
5. ECG in Medical Practice by ABM Abdullah, 4th edition
6. Chapter 3, Cardiology Explained, https://www.ncbi.nlm.nih.gov/books/NBK2214/
7. ECG Basics, http://www.nataliescasebook.com/tag/e-c-g-basics
Rasamanikya is a excellent preparation in the field of Rasashastra, it is used in various Kushtha Roga, Shwasa, Vicharchika, Bhagandara, Vatarakta, and Phiranga Roga. In this article Preparation& Comparative analytical profile for both Formulationon i.e Rasamanikya prepared by Kushmanda swarasa & Churnodhaka Shodita Haratala. The study aims to provide insights into the comparative efficacy and analytical aspects of these formulations for enhanced therapeutic outcomes.
Title: Sense of Taste
Presenter: Dr. Faiza, Assistant Professor of Physiology
Qualifications:
MBBS (Best Graduate, AIMC Lahore)
FCPS Physiology
ICMT, CHPE, DHPE (STMU)
MPH (GC University, Faisalabad)
MBA (Virtual University of Pakistan)
Learning Objectives:
Describe the structure and function of taste buds.
Describe the relationship between the taste threshold and taste index of common substances.
Explain the chemical basis and signal transduction of taste perception for each type of primary taste sensation.
Recognize different abnormalities of taste perception and their causes.
Key Topics:
Significance of Taste Sensation:
Differentiation between pleasant and harmful food
Influence on behavior
Selection of food based on metabolic needs
Receptors of Taste:
Taste buds on the tongue
Influence of sense of smell, texture of food, and pain stimulation (e.g., by pepper)
Primary and Secondary Taste Sensations:
Primary taste sensations: Sweet, Sour, Salty, Bitter, Umami
Chemical basis and signal transduction mechanisms for each taste
Taste Threshold and Index:
Taste threshold values for Sweet (sucrose), Salty (NaCl), Sour (HCl), and Bitter (Quinine)
Taste index relationship: Inversely proportional to taste threshold
Taste Blindness:
Inability to taste certain substances, particularly thiourea compounds
Example: Phenylthiocarbamide
Structure and Function of Taste Buds:
Composition: Epithelial cells, Sustentacular/Supporting cells, Taste cells, Basal cells
Features: Taste pores, Taste hairs/microvilli, and Taste nerve fibers
Location of Taste Buds:
Found in papillae of the tongue (Fungiform, Circumvallate, Foliate)
Also present on the palate, tonsillar pillars, epiglottis, and proximal esophagus
Mechanism of Taste Stimulation:
Interaction of taste substances with receptors on microvilli
Signal transduction pathways for Umami, Sweet, Bitter, Sour, and Salty tastes
Taste Sensitivity and Adaptation:
Decrease in sensitivity with age
Rapid adaptation of taste sensation
Role of Saliva in Taste:
Dissolution of tastants to reach receptors
Washing away the stimulus
Taste Preferences and Aversions:
Mechanisms behind taste preference and aversion
Influence of receptors and neural pathways
Impact of Sensory Nerve Damage:
Degeneration of taste buds if the sensory nerve fiber is cut
Abnormalities of Taste Detection:
Conditions: Ageusia, Hypogeusia, Dysgeusia (parageusia)
Causes: Nerve damage, neurological disorders, infections, poor oral hygiene, adverse drug effects, deficiencies, aging, tobacco use, altered neurotransmitter levels
Neurotransmitters and Taste Threshold:
Effects of serotonin (5-HT) and norepinephrine (NE) on taste sensitivity
Supertasters:
25% of the population with heightened sensitivity to taste, especially bitterness
Increased number of fungiform papillae
Basavarajeeyam is a Sreshta Sangraha grantha (Compiled book ), written by Neelkanta kotturu Basavaraja Virachita. It contains 25 Prakaranas, First 24 Chapters related to Rogas& 25th to Rasadravyas.
CrystalGuide flat fee surgical guide and triple scan - a new and effective protocol for 3D planning and guided surgery of partially edentulous cases CrystalGuide - complete service for advanced 3D planning and guided surgery of dental implants
1. CrystalGuide – the flat feesurgical guide No matterhowmany implants per arch – flat fee of $350 forpremiumservice Dr. Michael Gross Implantologist and internationallecturer Scientificconsultantfor dental implantindustry
2. Lectureprogram Classicprotocol : dual scantechnique Guided surgery and immediateloading Simplifiedinstrumentationforexpandedindication Triple scantechnique and case scenarios Clinicalsupport and education
3. Lectureprogram Classicprotocol : dual scantechnique Guided surgery and immediateloading Simplifiedinstrumentationforexpandedindication Triple scantechnique and case scenarios Clinicalsupport and education
4. 3D Scan of patient bone wearing radiographic denture with x-ray markers 3D scan of radiographic denture alone and alignment on 3D scan of patient bone 3D planning with visualization of radiographic denture
5. Precise 3D planning of position and angulation of implants and guide pins 3D relation between planned implant positions and radiographic denture File transfer over internet of planning data Fabrication of surgical guide converting radiographic denture
21. Lectureprogram Classicprotocol : dual scantechnique Guided surgery and immediateloading Simplifiedinstrumentationforexpandedindication Triple scantechnique and case scenarios Clinicalsupport and education
22. Guided surgery and immediateloading Dual scanprotocolwasdevelopedforedentulous cases withimmediateloading Promotedforteeth-in-a-daywithprefabricatedrestoration Thisrequiresimplantplacementoversurgical guide and thereforetitaniumsleeves in surgical guide Thisrequiresdevelopment of guided surgery kit withmanycomponents – costs – Ifnotallplanned implants haverequiredprimarystability, prefabricatedrestorationisuseless
23. Lectureprogram Classicprotocol : dual scantechnique Guided surgery and immediateloading Simplifiedinstrumentationforexpandedindication Triple scantechnique and case scenarios Clinicalsupport and education
24. Simplifiedinstrumentationforexpandedindication Reducedinstrumentationforcompatibility Eliminatingtheneed of implantspecificsurgical guide kit – universal guidance of 2mm and 3 mm drillwithdepth stop Eliminatingtheneed of titaniumsleeves – use of titaniumdrill guide handle 2mm and 3mm whichisintroduced in surgical guide Thisexpandsindicationbecausecollision of titaniumsleeveswithcloseorinclinated implants iseliminated In extremelynarrowsituations use of 2mm guide sleevesfor use with 2mm drills
26. Lectureprogram Classicprotocol : dual scantechnique Guided surgery and immediateloading Simplifiedinstrumentationforexpandedindication Triple scantechnique and case scenarios Clinicalsupport and education
27. Triple scantechnique Most of implant cases are partiallyedentulous Radiographicpartialdenturefor dual scan has disadvantages Fixationon residual teethpoorifnot extended overthem Visibility of residual teethcompromisedifcoveringthem Gingival contour of neighboringteeth and edentulousareas can only be estimated as underside of denture
28. Triple scantechnique Solutionforpartialedentulous cases CT or CBCT scan of patientwithoutanyappliance in open occlusion Opticalscan of master cast (can be modified and imported at any time after CT or CBCT) Optical scan of master cast with diagnostic wax-up (can be modified and imported at any time after CT or CBCT) Alignment of both optical scans with 3D model of bone
29. Triple scantechnique Solution for partial edentulous cases Implants can be backward-planned on cast with diagnostic wax-up with visualization of available bone, excellent details of teeth and soft tissue Relation of implant and soft tissue depth can be verified with visualization of master cast without wax-up, excellent details of teeth and soft tissue Relation of implant to crestal bone can be verified with visualization of bone without cast Fabrication of tooth-supported surgical guide over master cast without wax-up
58. 2 mm guide multipleextraction case withtooth-supported guide over 3 teeth as strategicsupport
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71. Lectureprogram Classicprotocol : dual scantechnique Guided surgery and immediateloading Simplifiedinstrumentationforexpandedindication Triple scantechnique and case scenarios Clinicalsupport and education
72. Clinicalsupport CrystalGuide– flat fee complete servicefor 3D planning and fabrication of surgicalguides withfastturnaround time (3 days) Providesurgicalinstruments at low-cost Online helpwith skype and teamviewer Simple data transfer overdropbox No physicalshippingneeded Free premiumplanningand viewingsoftware
73. Clinicalsupport CrystalGuide- Complete servicefor 3D planning and fabrication of surgicalguides at flat fee of $350 Turn-around time for guide fabrication3 businessdaysafter final approval of planning Secure online paymentoverPayPal
74. Clinicalsupport CrystalGuide- Complete servicefor 3D planning and fabrication of surgical guides Youalready are using a guided surgery kit foryourimplantbrand – weindividualizeyour software and adapttoit You are new to guided surgery – weprovide universal guided surgerytoolsforguiding up to 3mm drills, final sitepreparationwithyourimplant kit
75. Contact: Dr. Michael Gross CrystalGuide www.crystalguide.us dds.michael.gross@gmail.com