Regeneration is the process of renewal and restoration that allows organisms to recover from damage. In the context of periodontal regeneration, it refers to reproducing the lost periodontal complex including cementum, periodontal ligament, and alveolar bone. This document discusses various techniques used to achieve periodontal regeneration, including root biomodification using chemicals like citric acid and tetracycline to expose collagen and promote new attachment, use of barrier membranes to prevent epithelial downgrowth and allow selective repopulation of cells, and biodegradable membranes made of collagen or polylactic acid. While regeneration is the goal, often the outcome is repair through replacement of tissues by scar or bone fill.
This document provides an overview of periodontal wound healing and regeneration following periodontal surgery. It defines regeneration as the reproduction of lost or injured periodontal tissues, including cementum, periodontal ligament, and alveolar bone. Successful regeneration is assessed through probing, radiographs, direct measurements, and histology. The document discusses factors that influence regeneration outcomes, such as the surgical technique and local wound environment. Regenerative therapies aim to fully restore the lost periodontal structure and function.
This document discusses several controversies in periodontics. It addresses debates around the classification of periodontal diseases, factors involved in periodontal pathogenesis like invasiveness of bacteria and the role of the periodontal epithelium. It also examines controversies in diagnosing periodontal diseases and determining an accurate prognosis. Additionally, it looks at debates around treatments like gingival curettage, tooth mobility and splinting, one stage full-mouth disinfection versus quadrant SRP, and whether results are comparable between non-surgical and surgical periodontal therapy. The document acknowledges that while knowledge has improved, some controversies remain due to limitations in present diagnostic methods and incomplete understanding of periodontal pathology.
The future of dentistry and periodontics lies in regeneration. The goals of periodontal therapy lies in not only the arrest of periodontal disease progression but also regeneration of the lost periodontal structures. This presentation provides a review of the current understanding of the regeneration of the periodontium and the procedures involved to restore the periodontal tissues around the teeth.
Surgical v/s Non surgical periodontal therapy Achi Joshi
Both surgical and nonsurgical therapy produced improvement in the periodontal health.
Treatment approach was based on the comfort level of the practitioner.
In the late 60’s and continuing into the 70’s and 80’s, many series of longitudinal studies were conducted, aimed to document the immediate and most importantly long term clinical results following several types of periodontal therapy.
This document discusses different types of periodontal flaps used in periodontal surgery. It defines a periodontal flap as a section of gingiva and/or mucosa surgically separated from underlying tissues to provide visibility and access to the bone and root surfaces. It then classifies periodontal flaps based on bone exposure, placement after surgery, and management of the papilla. Specific flap techniques discussed include the modified Widman flap, undisplaced flap, apically displaced flap, and palatal flap. The objectives, incisions, and procedures for each flap type are described in detail.
The future of dentistry and periodontics lies in regeneration. The goals of periodontal therapy lies in not only the arrest of periodontal disease progression but also regeneration of the lost periodontal structures. This presentation provides a review of the current understanding of the regeneration of the periodontium and the procedures involved to restore the periodontal tissues around the teeth.
Scaling and root planing (SRP) is a non-surgical treatment for periodontitis that aims to remove dental plaque and calculus from tooth surfaces. It involves scaling to remove deposits and root planing to smooth root surfaces. The goals are to eliminate periodontitis by removing irritants and restoring a healthy environment for tissue healing. The long-term effectiveness depends on factors like patient compliance, disease severity, and anatomical challenges. Overhanging restorations can interfere with cleaning and disturb the ecological balance, allowing disease-causing bacteria to proliferate.
This document provides an overview of periodontal wound healing and regeneration following periodontal surgery. It defines regeneration as the reproduction of lost or injured periodontal tissues, including cementum, periodontal ligament, and alveolar bone. Successful regeneration is assessed through probing, radiographs, direct measurements, and histology. The document discusses factors that influence regeneration outcomes, such as the surgical technique and local wound environment. Regenerative therapies aim to fully restore the lost periodontal structure and function.
This document discusses several controversies in periodontics. It addresses debates around the classification of periodontal diseases, factors involved in periodontal pathogenesis like invasiveness of bacteria and the role of the periodontal epithelium. It also examines controversies in diagnosing periodontal diseases and determining an accurate prognosis. Additionally, it looks at debates around treatments like gingival curettage, tooth mobility and splinting, one stage full-mouth disinfection versus quadrant SRP, and whether results are comparable between non-surgical and surgical periodontal therapy. The document acknowledges that while knowledge has improved, some controversies remain due to limitations in present diagnostic methods and incomplete understanding of periodontal pathology.
The future of dentistry and periodontics lies in regeneration. The goals of periodontal therapy lies in not only the arrest of periodontal disease progression but also regeneration of the lost periodontal structures. This presentation provides a review of the current understanding of the regeneration of the periodontium and the procedures involved to restore the periodontal tissues around the teeth.
Surgical v/s Non surgical periodontal therapy Achi Joshi
Both surgical and nonsurgical therapy produced improvement in the periodontal health.
Treatment approach was based on the comfort level of the practitioner.
In the late 60’s and continuing into the 70’s and 80’s, many series of longitudinal studies were conducted, aimed to document the immediate and most importantly long term clinical results following several types of periodontal therapy.
This document discusses different types of periodontal flaps used in periodontal surgery. It defines a periodontal flap as a section of gingiva and/or mucosa surgically separated from underlying tissues to provide visibility and access to the bone and root surfaces. It then classifies periodontal flaps based on bone exposure, placement after surgery, and management of the papilla. Specific flap techniques discussed include the modified Widman flap, undisplaced flap, apically displaced flap, and palatal flap. The objectives, incisions, and procedures for each flap type are described in detail.
The future of dentistry and periodontics lies in regeneration. The goals of periodontal therapy lies in not only the arrest of periodontal disease progression but also regeneration of the lost periodontal structures. This presentation provides a review of the current understanding of the regeneration of the periodontium and the procedures involved to restore the periodontal tissues around the teeth.
Scaling and root planing (SRP) is a non-surgical treatment for periodontitis that aims to remove dental plaque and calculus from tooth surfaces. It involves scaling to remove deposits and root planing to smooth root surfaces. The goals are to eliminate periodontitis by removing irritants and restoring a healthy environment for tissue healing. The long-term effectiveness depends on factors like patient compliance, disease severity, and anatomical challenges. Overhanging restorations can interfere with cleaning and disturb the ecological balance, allowing disease-causing bacteria to proliferate.
Coronal advanced flap in combination with a connective tissue graft. Is the t...MD Abdul Haleem
Coronal advanced flap in combination with a connective tissue graft. Is the thickness of the flap a predictor for root coverage? - A prospective clinical study.
Department of Periodontology and Oral Implantology.
"A Journal Club Presentation"
This document discusses concepts related to periodontal pocket elimination. It defines a periodontal pocket and describes how plaque can lead to pocket formation in a vicious cycle. Non-surgical therapy like scaling and root planing can reduce pocket depth by resolving inflammation. Surgical pocket therapies aim to eliminate the pocket and restore periodontal tissues, resulting in new attachment, reattachment, or epithelial adaptation. Techniques discussed include gingivectomy, curettage, the excisional new attachment procedure, and laser-assisted procedures to access the root surface and eliminate pockets. The goal is to restore periodontal health and function.
Periodontitits is a multifactorial disease which leads to progressive loss of periodontal tissues including the alveolar bone. Since autogenous bone grafting has been considered as the gold standard referring to the lowest incidence of graft rejection, this ppt gives an insight about the autogenous bone grafts that can be used in periodontal defects.
1. The document discusses the importance of soft tissue integration around dental implants for long term success. Proper soft tissue seals protects the bone and prevents bacterial access.
2. Anatomy and healing of natural tooth soft tissue differs from implants, which can lead to less resistance to inflammation and slower healing for implants. Factors like gingival biotype, keratinized tissue, abutment design and mucosal thickness influence soft tissue integration.
3. Surgical and non-surgical methods are used to manage soft tissue and address factors like thin mucosa. Proper case assessment and treatment of biologic width is important for integration and preventing bone loss.
This document provides an overview of periodontal dressings. It discusses the history of dressings from the early 20th century use of eugenol-containing dressings to the development of non-eugenol dressings. The ideal properties and types of dressings are described, including eugenol, non-eugenol, and those containing neither zinc oxide nor eugenol. Modifications to dressings through the addition of substances like chlorhexidine to improve antimicrobial activity are also summarized. The document concludes by stating that while dressings provide wound protection, mouthwashes are now preferred for their antimicrobial effects during healing.
This document discusses crown lengthening procedures and biological width. It defines biological width as the natural distance between the base of the gingival sulcus and alveolar bone, which is typically 2mm. Crown lengthening surgically exposes more tooth structure above the bone to avoid violating the biological width and prevent inflammation. The document outlines different types of crown lengthening procedures based on the available soft and hard tissue dimensions, as well as factors to consider like gingival biotype and restoration design. Maintaining at least 3mm of tooth structure above bone is recommended to allow for proper restorative margins and healing.
This document provides information on various ridge augmentation techniques. It begins with an introduction describing how tooth loss leads to bone resorption and impaired function. It then discusses the history of using autogenous bone grafts for ridge augmentation. The objectives of ridge augmentation are also outlined. Key techniques discussed include ridge preservation, ridge splitting, use of autogenous bone blocks, and distraction osteogenesis. Advantages and disadvantages of different graft sources and incision designs are compared. The document emphasizes the importance of adequate bone volume for successful implant placement and summarizes various methods to augment bone.
This document discusses the anatomy, measurement, and clinical significance of the attached gingiva. It notes that the attached gingiva extends from the base of the gingival sulcus to the mucogingival junction. The normal width is 3-4.5mm in the maxillary anterior region but narrower in other areas. Inadequate width can facilitate subgingival plaque formation. Methods to measure width and increase width through surgery are described. The importance of keratinized, attached tissue for resisting mechanical irritation and stabilizing the gingival margin is emphasized.
This document discusses dental implants and the importance of soft tissue and bone health for implant success. It covers topics like osseointegration between implants and bone, gingival shrinkage during healing, the peri-implant soft tissue seal, the need for keratinized gingiva, and maintaining the biological width of peri-implant soft tissues. Patient factors like age, smoking, and diseases as well as local bone quality can influence implant success. Proper implant placement and surgical technique are important to support the overlying soft tissues long-term.
Periodontal flaps can be classified based on bone exposure, flap placement, and papilla management. A full thickness flap reflects all soft tissue including periosteum to expose bone, while a partial thickness flap reflects only epithelium and connective tissue, leaving bone covered. Flaps can be placed in their original position (non-displaced) or moved to a new position (displaced). Conventional flaps split the papilla while papilla preservation flaps incorporate the entire papilla into one flap. Proper flap design and suturing are important to achieve desired outcomes and promote healing.
The document discusses various techniques for preserving interdental papilla during periodontal procedures. It begins by defining the papilla and classifying types of papilla loss. Factors contributing to loss are described. Non-surgical and surgical preservation techniques are then covered in detail, including the papilla preservation flap, modified papilla preservation flap, simplified papilla preservation flap, entire papilla preservation flap, semilunar coronally repositioned flap, and whale's tail technique. Healing and references are lastly summarized.
Wound healing is a complex process involving regeneration and repair. It consists of three overlapping phases - inflammatory, proliferative, and remodeling. In the inflammatory phase, coagulation and platelet aggregation form a fibrin clot and recruit inflammatory cells. The proliferative phase involves re-epithelialization through keratinocyte migration and proliferation. Fibroblasts are activated and form granulation tissue through angiogenesis and collagen deposition. Myofibroblasts aid wound contraction in the final remodeling phase. Growth factors influence each phase of wound healing after periodontal and oral procedures.
This document discusses dental splints, including their definition, rationale, requirements, classifications, indications, and contraindications. It notes that splints are used to immobilize and stabilize mobile or loose teeth. They help reduce tooth mobility, distribute forces evenly, preserve arch integrity, and provide psychological benefits. Splints are classified based on duration, materials used, and location. They are indicated when tooth mobility impairs function or comfort, while contraindications include poor oral hygiene or insufficient firm teeth for stabilization. The document reviews different splint designs and their advantages of stabilizing teeth, but also notes disadvantages like hindering oral hygiene.
This document provides an overview of periimplantitis, including its definition, classification systems, epidemiology, etiology, pathogenesis, diagnosis, and treatment. Periimplantitis is defined as an inflammatory process involving both soft and hard tissues around a dental implant, resulting in loss of supporting bone. It is distinguished from peri-implant mucositis, which only involves inflammation of soft tissues. The document discusses various classification systems for periimplantitis and reviews potential etiologic factors such as plaque, biomechanical overload, genetic factors, and iatrogenic causes. Diagnosis involves clinical parameters like bleeding, probing depth, and radiographic bone loss. Treatment aims to eliminate infection and may include nonsurgical and surgical
This document discusses soft tissue grafting procedures used in periodontal plastic surgery. It provides an overview of common grafting techniques like free gingival grafts and connective tissue grafts used to treat mucogingival defects. Details are given on the indications, surgical protocols, advantages/disadvantages of each technique. Post-operative healing times and expectations are reviewed. The goal is to understand how and when these procedures can be used to correct mucogingival defects and improve periodontal health and aesthetics.
This document provides an overview of occlusion and occlusal therapy. It discusses the forces involved in jaw movement, the biologic basis of normal occlusion and occlusion-related dysfunction. It covers clinical examination techniques used to evaluate occlusion and various occlusal therapies including occlusal appliances, occlusal adjustment, splint therapy and orthodontic treatment. The goal of occlusal therapy is to establish stable functional relationships that are favorable for oral health by reducing excessive occlusal forces and correcting occlusal disharmonies.
The document discusses various chairside diagnostic aids that can be used in periodontal examination. It outlines the limitations of traditional diagnostic methods like clinical and radiographic evaluation. It then describes several advanced diagnostic aids like thermal probes, subtraction radiography. The rationale for developing chairside diagnostic kits is provided which allow immediate reports without specialized equipment. Examples of microbiological, genetic and biochemical chairside test kits are explained in detail, covering their methodology and biomarkers analyzed. Newer diagnostic tests still under development are also mentioned.
This document provides an overview of guided tissue regeneration (GTR). It defines key terms like regeneration, new attachment, and repair. It discusses the biological rationale for GTR, which is to use a barrier membrane to allow periodontal ligament cells to repopulate the root surface and form new attachment. The document outlines the objectives, indications, ideal properties, and functions of barrier membranes. It also discusses various barrier materials, the procedural guidelines for GTR, and factors that can affect clinical outcomes.
This document discusses periodontal regeneration and the various factors involved. It begins by defining key terminology related to grafting and regeneration. It then discusses the biology and objectives of periodontal regeneration, including the ideal outcome of new attachment formation and factors that can influence outcomes. The document outlines various techniques for periodontal regeneration including non-graft associated approaches involving removal of epithelium and surgical techniques, as well as graft-associated approaches using various graft materials. Requirements for predictable regeneration and assessment methods are also summarized.
The document describes a novel surgical technique called nonincised papillae surgical approach (NIPSA) for treating periodontal defects. NIPSA involves making a single horizontal incision in the mucosa away from the marginal tissues to access the defect, leaving the marginal tissues intact. This preserves the integrity of the interdental soft tissues and blood supply. The technique is modified to incorporate connective tissue grafts to treat advanced periodontal defects associated with buccal bone loss. Four case studies demonstrate positive outcomes with reduced pocket depth and clinical attachment gain using NIPSA with connective tissue grafts. The grafts are thought to improve wound stability, prevent soft tissue collapse, and delay epithelial downgrowth to create optimal conditions
Coronal advanced flap in combination with a connective tissue graft. Is the t...MD Abdul Haleem
Coronal advanced flap in combination with a connective tissue graft. Is the thickness of the flap a predictor for root coverage? - A prospective clinical study.
Department of Periodontology and Oral Implantology.
"A Journal Club Presentation"
This document discusses concepts related to periodontal pocket elimination. It defines a periodontal pocket and describes how plaque can lead to pocket formation in a vicious cycle. Non-surgical therapy like scaling and root planing can reduce pocket depth by resolving inflammation. Surgical pocket therapies aim to eliminate the pocket and restore periodontal tissues, resulting in new attachment, reattachment, or epithelial adaptation. Techniques discussed include gingivectomy, curettage, the excisional new attachment procedure, and laser-assisted procedures to access the root surface and eliminate pockets. The goal is to restore periodontal health and function.
Periodontitits is a multifactorial disease which leads to progressive loss of periodontal tissues including the alveolar bone. Since autogenous bone grafting has been considered as the gold standard referring to the lowest incidence of graft rejection, this ppt gives an insight about the autogenous bone grafts that can be used in periodontal defects.
1. The document discusses the importance of soft tissue integration around dental implants for long term success. Proper soft tissue seals protects the bone and prevents bacterial access.
2. Anatomy and healing of natural tooth soft tissue differs from implants, which can lead to less resistance to inflammation and slower healing for implants. Factors like gingival biotype, keratinized tissue, abutment design and mucosal thickness influence soft tissue integration.
3. Surgical and non-surgical methods are used to manage soft tissue and address factors like thin mucosa. Proper case assessment and treatment of biologic width is important for integration and preventing bone loss.
This document provides an overview of periodontal dressings. It discusses the history of dressings from the early 20th century use of eugenol-containing dressings to the development of non-eugenol dressings. The ideal properties and types of dressings are described, including eugenol, non-eugenol, and those containing neither zinc oxide nor eugenol. Modifications to dressings through the addition of substances like chlorhexidine to improve antimicrobial activity are also summarized. The document concludes by stating that while dressings provide wound protection, mouthwashes are now preferred for their antimicrobial effects during healing.
This document discusses crown lengthening procedures and biological width. It defines biological width as the natural distance between the base of the gingival sulcus and alveolar bone, which is typically 2mm. Crown lengthening surgically exposes more tooth structure above the bone to avoid violating the biological width and prevent inflammation. The document outlines different types of crown lengthening procedures based on the available soft and hard tissue dimensions, as well as factors to consider like gingival biotype and restoration design. Maintaining at least 3mm of tooth structure above bone is recommended to allow for proper restorative margins and healing.
This document provides information on various ridge augmentation techniques. It begins with an introduction describing how tooth loss leads to bone resorption and impaired function. It then discusses the history of using autogenous bone grafts for ridge augmentation. The objectives of ridge augmentation are also outlined. Key techniques discussed include ridge preservation, ridge splitting, use of autogenous bone blocks, and distraction osteogenesis. Advantages and disadvantages of different graft sources and incision designs are compared. The document emphasizes the importance of adequate bone volume for successful implant placement and summarizes various methods to augment bone.
This document discusses the anatomy, measurement, and clinical significance of the attached gingiva. It notes that the attached gingiva extends from the base of the gingival sulcus to the mucogingival junction. The normal width is 3-4.5mm in the maxillary anterior region but narrower in other areas. Inadequate width can facilitate subgingival plaque formation. Methods to measure width and increase width through surgery are described. The importance of keratinized, attached tissue for resisting mechanical irritation and stabilizing the gingival margin is emphasized.
This document discusses dental implants and the importance of soft tissue and bone health for implant success. It covers topics like osseointegration between implants and bone, gingival shrinkage during healing, the peri-implant soft tissue seal, the need for keratinized gingiva, and maintaining the biological width of peri-implant soft tissues. Patient factors like age, smoking, and diseases as well as local bone quality can influence implant success. Proper implant placement and surgical technique are important to support the overlying soft tissues long-term.
Periodontal flaps can be classified based on bone exposure, flap placement, and papilla management. A full thickness flap reflects all soft tissue including periosteum to expose bone, while a partial thickness flap reflects only epithelium and connective tissue, leaving bone covered. Flaps can be placed in their original position (non-displaced) or moved to a new position (displaced). Conventional flaps split the papilla while papilla preservation flaps incorporate the entire papilla into one flap. Proper flap design and suturing are important to achieve desired outcomes and promote healing.
The document discusses various techniques for preserving interdental papilla during periodontal procedures. It begins by defining the papilla and classifying types of papilla loss. Factors contributing to loss are described. Non-surgical and surgical preservation techniques are then covered in detail, including the papilla preservation flap, modified papilla preservation flap, simplified papilla preservation flap, entire papilla preservation flap, semilunar coronally repositioned flap, and whale's tail technique. Healing and references are lastly summarized.
Wound healing is a complex process involving regeneration and repair. It consists of three overlapping phases - inflammatory, proliferative, and remodeling. In the inflammatory phase, coagulation and platelet aggregation form a fibrin clot and recruit inflammatory cells. The proliferative phase involves re-epithelialization through keratinocyte migration and proliferation. Fibroblasts are activated and form granulation tissue through angiogenesis and collagen deposition. Myofibroblasts aid wound contraction in the final remodeling phase. Growth factors influence each phase of wound healing after periodontal and oral procedures.
This document discusses dental splints, including their definition, rationale, requirements, classifications, indications, and contraindications. It notes that splints are used to immobilize and stabilize mobile or loose teeth. They help reduce tooth mobility, distribute forces evenly, preserve arch integrity, and provide psychological benefits. Splints are classified based on duration, materials used, and location. They are indicated when tooth mobility impairs function or comfort, while contraindications include poor oral hygiene or insufficient firm teeth for stabilization. The document reviews different splint designs and their advantages of stabilizing teeth, but also notes disadvantages like hindering oral hygiene.
This document provides an overview of periimplantitis, including its definition, classification systems, epidemiology, etiology, pathogenesis, diagnosis, and treatment. Periimplantitis is defined as an inflammatory process involving both soft and hard tissues around a dental implant, resulting in loss of supporting bone. It is distinguished from peri-implant mucositis, which only involves inflammation of soft tissues. The document discusses various classification systems for periimplantitis and reviews potential etiologic factors such as plaque, biomechanical overload, genetic factors, and iatrogenic causes. Diagnosis involves clinical parameters like bleeding, probing depth, and radiographic bone loss. Treatment aims to eliminate infection and may include nonsurgical and surgical
This document discusses soft tissue grafting procedures used in periodontal plastic surgery. It provides an overview of common grafting techniques like free gingival grafts and connective tissue grafts used to treat mucogingival defects. Details are given on the indications, surgical protocols, advantages/disadvantages of each technique. Post-operative healing times and expectations are reviewed. The goal is to understand how and when these procedures can be used to correct mucogingival defects and improve periodontal health and aesthetics.
This document provides an overview of occlusion and occlusal therapy. It discusses the forces involved in jaw movement, the biologic basis of normal occlusion and occlusion-related dysfunction. It covers clinical examination techniques used to evaluate occlusion and various occlusal therapies including occlusal appliances, occlusal adjustment, splint therapy and orthodontic treatment. The goal of occlusal therapy is to establish stable functional relationships that are favorable for oral health by reducing excessive occlusal forces and correcting occlusal disharmonies.
The document discusses various chairside diagnostic aids that can be used in periodontal examination. It outlines the limitations of traditional diagnostic methods like clinical and radiographic evaluation. It then describes several advanced diagnostic aids like thermal probes, subtraction radiography. The rationale for developing chairside diagnostic kits is provided which allow immediate reports without specialized equipment. Examples of microbiological, genetic and biochemical chairside test kits are explained in detail, covering their methodology and biomarkers analyzed. Newer diagnostic tests still under development are also mentioned.
This document provides an overview of guided tissue regeneration (GTR). It defines key terms like regeneration, new attachment, and repair. It discusses the biological rationale for GTR, which is to use a barrier membrane to allow periodontal ligament cells to repopulate the root surface and form new attachment. The document outlines the objectives, indications, ideal properties, and functions of barrier membranes. It also discusses various barrier materials, the procedural guidelines for GTR, and factors that can affect clinical outcomes.
This document discusses periodontal regeneration and the various factors involved. It begins by defining key terminology related to grafting and regeneration. It then discusses the biology and objectives of periodontal regeneration, including the ideal outcome of new attachment formation and factors that can influence outcomes. The document outlines various techniques for periodontal regeneration including non-graft associated approaches involving removal of epithelium and surgical techniques, as well as graft-associated approaches using various graft materials. Requirements for predictable regeneration and assessment methods are also summarized.
The document describes a novel surgical technique called nonincised papillae surgical approach (NIPSA) for treating periodontal defects. NIPSA involves making a single horizontal incision in the mucosa away from the marginal tissues to access the defect, leaving the marginal tissues intact. This preserves the integrity of the interdental soft tissues and blood supply. The technique is modified to incorporate connective tissue grafts to treat advanced periodontal defects associated with buccal bone loss. Four case studies demonstrate positive outcomes with reduced pocket depth and clinical attachment gain using NIPSA with connective tissue grafts. The grafts are thought to improve wound stability, prevent soft tissue collapse, and delay epithelial downgrowth to create optimal conditions
This document provides an overview of regenerative periodontal surgery techniques. It discusses the historical concepts of periodontal regeneration including bone grafts, guided tissue regeneration (GTR), and the emerging field of tissue engineering. Key cellular mediators and signaling molecules that can promote periodontal regeneration are described, including platelet-derived growth factor, bone morphogenetic proteins, insulin-like growth factor, and enamel matrix derivative. The document also reviews the different cell types involved in periodontal regeneration, including dental pulp stem cells, periodontal ligament stem cells, dental follicle progenitor cells, and dental epithelial stem cells. The criteria for achieving true periodontal regeneration and methods to guide cell differentiation and maturation are also summarized.
The document discusses various methods for evaluating periodontal regeneration after therapy, including clinical, radiographic, surgical re-entry, and histologic methods. It also covers principles of bone regeneration including osteogenesis, osteoconduction and osteoinduction. Non-bone graft associated procedures and bone grafting techniques and materials used in periodontal regeneration are described in detail.
Simultaneous vertical guided bone regeneration and guided tissue regeneration...threea3a
This clinical case report describes using recombinant human platelet-derived growth factor (rhPDGF-BB) along with autogenous bone and barrier membranes to reconstruct severe alveolar bone defects in the posterior maxilla through simultaneous vertical ridge augmentation and sinus floor elevation. Over 9 months of healing, complete vertical bone regeneration and new attachment to a previously denuded root surface were observed. Three implants were successfully placed and a fixed restoration was provided, demonstrating the potential for rhPDGF-BB to enhance regeneration when combined with standard bone grafting techniques and membranes. However, further controlled studies are needed to fully evaluate the benefits of using rhPDGF-BB for complex reconstruction procedures.
It is sometimes difficult in clinical and experimental situations to determine whether regeneration or new attachment has occurred and the extent to which it has occurred.
Although there are various evidences of reconstruction, the proof of principle for the type of healing is determined by histological studies.
Gingival Curettage / /certified fixed orthodontic courses by Indian dental ac...Indian dental academy
Welcome to 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 has a unique training program & curriculum that provides students with exceptional clinical skills and enabling them to return to their office with high level confidence and start treating patients
State of the art comprehensive training-Faculty of world wide repute &Very affordable.
This document summarizes root surface treatments for periodontal regeneration. It discusses that the root surface must provide a substrate for connective tissue cell migration and attachment. Mechanical root planing alone is not sufficient, as it can leave behind a smear layer and bacteria. Chemical root treatments help decontaminate and demineralize the root to expose collagen and provide a better substrate. Citric acid, tetracycline, EDTA, and enamel matrix derivatives are discussed as common chemical treatments used to modify the root surface. The document also discusses using growth factors like PDGF, FGF, and IGF to further aid periodontal regeneration by stimulating cell migration and new attachment.
Reconstructive periodontal therapy
Some of the slides may appear Blank/White/Black, those are the Videos that I added in the presentation.
Kindly Ignore those slides.
GINGIVAL SURGICAL TECHNIQUES IN PERIODONTOLOGYSupriya Bhat
This document provides an overview of different gingival surgical techniques including gingival curettage, gingivectomy, and gingivoplasty. It discusses the history, rationale, indications, contraindications, procedures, healing processes, and clinical appearances for each technique. Gingival curettage involves scraping the gingival pocket wall to remove diseased soft tissue, while gingivectomy is the excision of gingiva to eliminate supra bony pockets. Different techniques for performing these surgeries include using curettes, electrosurgery, lasers, or chemosurgery. Proper application of these techniques aims to reduce inflammation and promote new tissue attachment and bone regeneration.
This literature review discusses techniques for repairing large and complete maxillary sinus membrane perforations during sinus lift procedures. It describes the anatomy of the maxillary sinus and discusses causes of membrane perforation. For large perforations over 1.5cm, suturing and other techniques may not be feasible. The author presents a case report where a slow resorbing collagen membrane was used to fully cover the sinus, including areas with no membrane, after cyst removal resulted in a complete perforation. At 12 months, the graft was well-incorporated with minimal resorption. The membrane's structure and stabilization with tacks helped maintain the blood supply needed for graft incorporation.
Guided tissue regeneration (GTR) aims to regenerate lost periodontal tissues by using barrier membranes to selectively prevent the migration of epithelial and gingival connective tissue cells to the root surface, allowing periodontal ligament cells to repopulate the area. The document discusses the history and development of GTR, the biological basis and concept behind using barrier membranes, characteristics of ideal GTR membranes, indications and contraindications for GTR, and outcomes from studies applying GTR in treating periodontal defects.
An undergraduate student accidentally perforated the coronal third of a patient's tooth during root canal treatment, resulting in marginal tissue recession. The patient was referred for periodontal and restorative treatment. The perforation site was restored with glass ionomer cement. A subepithelial connective tissue graft was used to achieve total root coverage. Five months later, porcelain veneers were placed to restore esthetics. The multidisciplinary approach successfully restored both soft tissue and dental esthetics following an iatrogenic error.
24th oct Pulp Therapy In Young Permanent Teeth.pptxismasajjad1
The document discusses various pulp therapy techniques for young permanent teeth including indirect pulp capping, direct pulp capping, Cvek pulpotomy, apexogenesis, apexification, and regenerative endodontics. Important factors to consider include assessing for signs of reversible pulpitis. Indirect pulp capping involves sealing a deep lesion near the pulp with a protective material while direct pulp capping places a material directly over an exposure site after controlling bleeding. Pulpotomy removes inflamed pulp from the crown while leaving healthy tissue in the root canals. Apexogenesis treats immature teeth to allow continued root development while apexification induces a barrier in nonvital open apices. Regenerative endodontics aims
The document discusses various surgical procedures in periodontics and dentistry. It covers indications for surgery such as deep pockets or furcation involvement. It describes resective, regenerative, and new attachment procedures. Regenerative procedures use grafts, EMD, PDGF or PRP with membranes to guide tissue regeneration. Post-operative instructions and complications are addressed. Healing by first, second or third intention is summarized.
Root Amputation and Perio Esthetic SurgeryDr AJINS CB
This case report describes the successful treatment of a patient with gingival recession and root exposure on the upper right first premolar. Treatment involved non-surgical therapy followed by endodontic treatment, resection of the exposed buccal root, and perio-plastic surgery using a lateral pedicle flap and bone graft to cover the partially visible palatal root. At 1-year post-op, there was no further recession and the tooth was successfully salvaged, demonstrating that advanced perio-plastic procedures can restore esthetics and treat furcation involvement even in premolars.
it describes the bony anatomy including the femoral head , acetabulum, labrum . also discusses the capsule , ligaments . muscle that act on the hip joint and the range of motion are outlined. factors affecting hip joint stability and weight transmission through the joint are summarized.
How to Manage Your Lost Opportunities in Odoo 17 CRMCeline George
Odoo 17 CRM allows us to track why we lose sales opportunities with "Lost Reasons." This helps analyze our sales process and identify areas for improvement. Here's how to configure lost reasons in Odoo 17 CRM
Main Java[All of the Base Concepts}.docxadhitya5119
This is part 1 of my Java Learning Journey. This Contains Custom methods, classes, constructors, packages, multithreading , try- catch block, finally block and more.
A Strategic Approach: GenAI in EducationPeter Windle
Artificial Intelligence (AI) technologies such as Generative AI, Image Generators and Large Language Models have had a dramatic impact on teaching, learning and assessment over the past 18 months. The most immediate threat AI posed was to Academic Integrity with Higher Education Institutes (HEIs) focusing their efforts on combating the use of GenAI in assessment. Guidelines were developed for staff and students, policies put in place too. Innovative educators have forged paths in the use of Generative AI for teaching, learning and assessments leading to pockets of transformation springing up across HEIs, often with little or no top-down guidance, support or direction.
This Gasta posits a strategic approach to integrating AI into HEIs to prepare staff, students and the curriculum for an evolving world and workplace. We will highlight the advantages of working with these technologies beyond the realm of teaching, learning and assessment by considering prompt engineering skills, industry impact, curriculum changes, and the need for staff upskilling. In contrast, not engaging strategically with Generative AI poses risks, including falling behind peers, missed opportunities and failing to ensure our graduates remain employable. The rapid evolution of AI technologies necessitates a proactive and strategic approach if we are to remain relevant.
MATATAG CURRICULUM: ASSESSING THE READINESS OF ELEM. PUBLIC SCHOOL TEACHERS I...NelTorrente
In this research, it concludes that while the readiness of teachers in Caloocan City to implement the MATATAG Curriculum is generally positive, targeted efforts in professional development, resource distribution, support networks, and comprehensive preparation can address the existing gaps and ensure successful curriculum implementation.
This presentation was provided by Steph Pollock of The American Psychological Association’s Journals Program, and Damita Snow, of The American Society of Civil Engineers (ASCE), for the initial session of NISO's 2024 Training Series "DEIA in the Scholarly Landscape." Session One: 'Setting Expectations: a DEIA Primer,' was held June 6, 2024.
How to Add Chatter in the odoo 17 ERP ModuleCeline George
In Odoo, the chatter is like a chat tool that helps you work together on records. You can leave notes and track things, making it easier to talk with your team and partners. Inside chatter, all communication history, activity, and changes will be displayed.
2. 2
Regeneration is the process of
renewal, restoration and
growth that makes cells and
organisms resilient to natural
fluctuations or events that cause
disturbance
or damage
Regeneration can either be complete or incomplete
3. INTRODUCTION
3
The Periodontium
consists of cells and
tissue complex organized
into basic components of
cementum, periodontal
ligament and alveolar
bone.
The challenge of
regeneration is to
reconstitute this complex
onto the root surface.
6. Healing patterns in the periodontal
tissues
Lindhe 6th6
Healing by first intention Involves the wound edges being
brought together using sutures.
Healing by second intention Occurs in surgical wounds that are
left to heal without approximating the edges.
Healing by third intention wound heal by contraction of wound
edges and In some cases presence of a foreign body or
infection may be suspected.
Partial‐thickness healing Occurs when a partial‐thickness
wound is closed primarily by epithelialization
7. Sources of Regenerating cells
7
A. Gingival Epithelium
B. Connective Tissue
C. Bone Marrow
D. Periodontal Ligament
9. Possible Outcomes Of Periodontal
Therapy
9
Oral epithelium
Bone cells
Periodontal ligament cells
Connective tissue
Karring Et Al 1980
Nyman 1980
Karring 1985
10. TYPES OF HEALING AFTER
PERIODONTAL THERAPY
Carranza 10th ed
10
Regeneration
Repair
New Attachment
Reattachment
Epithelial Adaptation
Bone fill
Sharpey’s Fibers
Bone
PDL
Tooth
11. Regeneration
Carranza 10th ed11
Regeneration is defined as a reproduction or
reconstruction of a lost or injured part in such a way
that the architecture and function of the lost or injured
tissues are completely restored
(American Academy of Periodontology 1992)
Regeneration occurs through growth from the same type of
tissue that has been destroyed or from its precursor.
12. 12
Regeneration of the periodontium is a continuous
physiologic process
It is manifested by :-
(1) Mitotic activity in the epithelium of the gingiva and
the connective tissue of the periodontal ligament
(2) The formation of new bone, and
(3) The continuous deposition of cementum.
13. 13
Repair
Involves replacement of one tissues with another
tissue, such as fibrous connective tissue, which may
not function as the same as the tissue replaced.
This process, called “healing by scar”.
Arrests bone destruction but does not result in gain of
gingival attachment or bone height.
14. 14
New attachment is the embedding of new periodontal
ligament fibers into new cementum and the attachment
of the gingival epithelium to a tooth surface previously
denuded by disease.
Reattachment refers to repair in areas of the root not
previously exposed to the pocket, such as after surgical
detachment of the tissues or following traumatic tears
in the cementum, tooth fractures, or the treatment of
periapical lesions.
15. 15
Epithelial adaptation differs from new attachment in
that it is the close apposition of the gingival epithelium
to the tooth surface, with no gain in height of gingival
fiber attachment.
Bone fill is defined as the clinical restoration of bone
tissue in a treated periodontal defect
16. Carranza 10th ed,16
PERIODONTAL RECONSTRUCTION
Refer to the process of regeneration of cells and fibers
and remodeling of the lost periodontal structures that
results in
(1) Gain of attachment level
(2) Formation of new periodontal ligament fibers
(3) A level of alveolar bone significantly coronal to that
present before treatment.
17. Methods to Evaluate Regeneration
17
Clinical methods for evaluation of therapy are
Periodontal probing – Pocket depth, CAL, Gingival
margin location and width.
Re-entry procedures
Radiographic evaluation
Histological evaluation
Pretreatment and post treatment are compared to
determine the effect of the therapy.
18. Criteria for regeneration
Bartold PM, McCulloch CA, Narayanan AS and Pitaru S. Tissue engineering: a new paradigm for
periodontal regeneration based on molecular and cell biology. Periodontology 2000 2000; 24:253-269.18
Functional epithelial seal not more than 2
mm in length.
New connective tissue fibres must be
inserted into the previously exposed root.
New acellular extrinsic fiber cementum
must be reformed.
Alveolar bone height must be restored to
within 2 mm of the CEJ.
19. OBJECTIVES OF REGENERATIVE
THERAPY
19
Regeneration of new cementum, PDL, and bone as
determined by histologic analysis.
Bone fill of the osseous defect.
Clinical attachment gain.
Pocket elimination.
Establishment of healthy maintainable environment
20. REQUIREMENTS FOR
PREDICTABLE REGENERATION
20
(1) Thorough Root Planing
(2) Root Biomodification
(3) Space Provision
(4) Preparation Of The Osseous Defects For New
Attachment
(5) Wound Stability
(6) Revascularization
(7) Undisturbed Healing
(8) Flap Management
22. Generations in Periodontal
regeneration- Egusa et al., 2012
Egusa H, Sonoyama W, Nishimura M, Atsuta I, Akiyama K. Stem cells in dentistry–Part II:
Clinical applications. Journal of prosthodontic research. 2012;56(4):229-48.22
24. Non–Graft-Associated
Reconstructive Procedures
Carranza 12th
24
Removal of junctional and pocket
epithelium
- Curettage
- Chemical agents
- Biomodification of root surface
- Surgical Techniques
Preventing or Impeding the
epithelial migration
Clot stabilization, wound
protection and space creation
Orthodontic therapy
LASER
25. Removal of junctional & Pocket
epithelium
25
‘Curettage’ - Removal of granulation tissue from
lateral wall of pocket.
Unreliable, Regeneration does occur.
Chemicals - NaS, Phenol, Camphor, Antiformin,
Naocl.
Effect not limited to epithelium.
Depth of penetration is not controlled.
Historical interest.
27. Biomodification of root surface
Lindhe 6th
27
Rationale
To improve blood clot
adhesion
To expose collagen
fibrils
Methods
Mechanical
Chemical
Combination of the two.
extrinsic collagen fibers
Cementum
28. Citric acid
Carranza 12th
28
• pH 1.0, 2 mins (2-5 mins), ‘Rubbing’ technique
Register & Burdick, 1976
• Removes smear layer
• Demineralisation of root surface on root planed teeth (4μm)
• Eliminate endotoxins and bacteria from the diseased tooth
surface.
29. 29
Exposes collagen (2-15μm) & collagen splicing
Exposed and wide dentinal tubules (8.88μm depth)
Accelerated healing and new cementum formation
occur.
Prevention of epithelial migration by fibrin linkage (1-3
days) Polson 1984
Pulpal / epithelial injury
30. Tetracycline
Shewale et al. Root Surface Biomodification: Current Status and a Literature Review on Available
Agents for Periodontal Regeneration ; BJMMR, 2016; 13(2): 1-14,.30
pH 1.6, 100mg/ml for 2 to 3 mins
Terranova et al., 1986
Increases fibronectin binding which stimulates
fibroblast attachment and growth.
Smear layer removal, exposure of dentin tubules /
collagen fibers.
Endothelial cell growth factor binding to dentin,
stimulating periodontal ligament cell proliferation /
migration.
31. 31
Adsorbs to enamel and dentin. acts as antimicrobial
local delivery system. Substantivity (50mg/ml - 14
days)
Collagenolytic enzyme inhibition preventing bone
resorption.
Prevent epithelial migration
Recommended for use with biologic mediators
32. EDTA
32
Higher pH 7.0 to 7.2, 18 to 24% , 2-3mins
No root resorption and ankylosis
Chelation
Surface demineralisation
33. Root Conditioning by Lasers
33
Lasers are capable of sterilizing the diseased root
surface and thus ultimately promoting cell
reattachment.
Commercially available laser systems
ER: YAG (Erbium: Yttrium, aluminum and garnet)
ND: YAG (Neodymium: Yttrium; aluminum and
garnet)
Carbon dioxide laser
34. CURRENT STATUS
34
Angelo Mariotti in a systematic review in 2003
concluded that chemical modifiers provides no
additional benefit and clinical significance to
regeneration in patients with chronic periodontitis.
Systematic review by Karam et al., 2015 - (Citric
acid, lasers)
Use of root surface modifiers to improve the clinical
outcomes is not justified.
35. Preventing or Impeding the
Epithelial Migration
Carranza 13th
35
Total removal of the interdental papilla covering the defect
and its replacement with a free autogenous graft obtained
from the palate.
The graft simply delays the epithelium from proliferating
into the healing area.
This method has not been widely used.
Coronally Displaced Flaps
increase the distance between the epithelial wound edge
and the healing area.
suitable for the treatment of mandibular molar furcations
used mostly in conjunction with citric acid
36. GTR
CARRANZA 13TH
36
The term Guided tissue
regeneration refers to the
procedures attempting to
regenerate specific anatomical
structures through differential
tissue responses.
Gottlow.,1986 coined the term
‘GTR’
Nyman, Gottlow, Lindhe,
Karring., 1982
38. INDICATIONS
38
Narrow 2 - or 3 - wall defects
Class II / III (Early)furcations
Deep craters
Marginal tissue recession (Class I / II)
Circumferential defects
Combined osseous defects
Ridge augmentation / Guided bone regeneration
Peri-implant defects
39. Contraindications
39
Poor oral hygiene
Class III/IV furcations
One wall defect
Lack of motivation
Horizontal bone loss
Smoking
Medical history
40. Generations of GTR Membranes -
Gottlow
40
I II III
Non
Resorbable
Bioresorbable
Bioresorbable with
additional activity
Antimicrobial activity
Bioactivity
Growth factor release
41. Classification of GTR Membranes
41
I. Non-resorbable membranes
a. Cellulose filters
b. Expanded poly tetrafluoroethylene membranes (GORE TEX®)
II. Resorbable materials
a. Collagen membranes
b. Polylactic acid
c. Polyglycolic acid
d. Synthetic liquid polymer Polyglactin
e. Calcium sulfate
f. Acellular dermal allografts
g. Oxidized cellulose mesh
42. Scantlebury’s criteria
42
Tissue Integration 1982 W.L. Gore & Associates
Cell Separation 1982, Dr. John Prichard
Clinically Manageable 1985 Karring and Nyman
Space Making 1988 Spring
Biocompatibility Scantlebury, 1993
43. ePTFE Membrane
43
Fluoropolymer - with carbon and
fluorine bonds
No enzyme in human body can
cleave C-F bond
‘Nodes & fibrils’ microstructure
Allowed the passage of liquid and
nutritional products through the
barrier, but their microporosity
excluded cell passage .
44. CONFIGURATION
44
Apical border of the
membrane should
extend 3 to 4 mm apical
and laterally 2 to 3 mm
and occlusally should be
placed 2 mm apical to
the CEJ.
47. Biodegradable Membranes
47
Collagen barriers
Extracellular macromolecule of the periodontal
connective tissue
physiologically metabolized
Chemotactic for fibroblasts
Hemostatic
A weak immunogen
Scaffold for migrating cells
48. Arun K Garg. Bone biology, harvesting, grafting for dental implants. 1st ed. Quint Pub48
Sources - Bovine tendon, bovine dermis, calf skin,
porcine dermis, fish skin, fascia lata, fascia temporalis.
Available in different configurations and sizes.
CollaTape used to cover and stabilize graft materials,
CollaPlug can be placed into or over extraction sockets,
CollaCote can be used to fill in harvested soft tissue
sites, such as the palate
CollaTape
CollaPlug CollaCote
49. 49
1.COLLAGEN OF PORCINE ORIGIN (BIO-GUIDE)
2.COLLAGEN DERIVED FROM BOVINE ACHILLES
TENDON (BIO-MEND), (PERIOGEN)
3.COLLAGEN DERIVED FROM BOVINE CORIUM
(AVITENE), (NEO-MEM)
4.COLLAGEN FROM OX PERITONEUM (CARGILE
MEMBRANES)
5.COLLAGEN OF FISH ORIGIN (PERIOCOL-GTR)
50. Polylactic acid
50
Guidor
Composed of a blend of polylactic acid softened with
citric acid for malleability and to facilitate clinical
handling.
Multilayered matrix.
51. 51
The inner layer-contact with
the bone or tooth, features
small circular perforations
and several space holders
for formation of new
attachment.
The outer layer- contact
with the gingival tissue, has
larger rectangular
perforations to allow rapid
growth of gingival tissue
into the interspace between
the two layers, preventing or
minimizing epithelial
downgrowth
52. 52
Studies demonstrated
the efficacy of PLA
membranes for
treatment of
interproximal defects
and gingival recession in
primates, as well as
infrabony defects and
Class II furcation
defects in humans
Studies also failed to
show adequate
regeneration in
circumferential
periodontal lesions in
primates
It was concluded further modification and transformation were required to create
a membrane that possesses all of the properties necessary to obtain better results
53. PRF
53
Platelet rich fibrin (PRF) is a totally
autologous blood concentrate system.
Due to the easy accessibility, minimal
invasivity and time saving.
preparation, the role of PRF-based
matrices gained in importance.
Direct contact of PRF with
periosteum substantially improves the
blood supply to the keratinized soft
tissue favoring its thickness, as well
as improves blood supply to the
underlying bone tissues.
54. ADVANTAGE
54
Facilitates blood clot formation.
Growth factor release kinetics is slow so Regeneration
occur over extended period of time.
PRF contains leukocytes and macrophages, known cell
types implicated in immunity and host defense.
Studies found that the use PRF in combination with a
bone-grafting material was superior to either PRF
alone, or bone-grafting material alone.
55. Fate of biodegradable membranes
55
Collagen -> Collagenase-> Gelatinase->
Oligopeptides->peptidases-> Aminoacids.
Polylactic acid - 2 stage degradation - Random non
enzymatic cleavage and second loss of mechanical
strength and weight (Pitt et al., 1981)
Free lactic acid - Carbondioxide & Water
Calcium sulfate - Giant cell reaction
Amnion & Chorion - autolytic reaction
56. 56
Advantages
No second surgery
Chemotaxis of
fibroblasts
Weak immunogenicity
Easy manipulation
Direct effect on bone
formation Augment
tissue thickness
Disadvantages
Lack of stability
Poor Space making
Fast biodegradation
62. Evidence on GTR
62
Systematic review - Sculean et al., 2008 - most
preclinical studies have histologically demonstrated
periodontal regeneration when grafting materials are
combined with barrier membranes.
Needleman et al., 2006
GTR has a greater effect on probing measures of
periodontal treatment than open flap debridement,
including improved attachment gain, reduced pocket
depth, less increase in gingival recession and more
gain in hard tissue probing at re-entry surgery.
63. 63
Viable tissue transplanted from donor to recipient site
Any biomaterial implanted into osseous defect to
stimulate periodontal regeneration
GRAFT
65. 65
By function during
healing
Osteogenesis
Osteoinduction
Osteoconduction
Based on location
Extraoral grafts
Intraoral grafts
By composition
Cortical
Cancellous
Cortico-cancellous /
Osteochondral
Combined hard and soft
tissue graft
By anatomical
placement
Orthotopic
Heterotopic
66. Lindhe 6th ed.66
Osteoproliferative (osteogenetic): new bone is formed
by bone‐forming cells contained in the grafted material.
Autograft
Osteoconductive: the grafted material does not
contribute to new bone formation per se but serves as a
scaffold for bone formation originating from adjacent
host bone.
Autograft , Allograft
Osteoinductive: bone formation is induced in the
surrounding soft tissue immediately adjacent to the
grafted material.
Autograft, Allograft, Alloplasts, Xenograft
67. BONE GRAFTING TECHNIQUE
Raymonda . Yukna Svnthetic bone grafts in periodontics67
1. Remove all etiologic factors.
2. Stabilize teeth if necessary
3. Flap design with a plan for closure
4. Degranulation of defect and flap
5. Root preparation
6. Pre-suturing
7. Condense graft materials well
8. Fill to a realistic level.
9. Periodontal dressing.
10. Antibiotic coverage
11. Postsurgical care
69. Bone Grafts and Bone Substitutes
Periodontics Rose and Mealey
69
Bone-Derived Material
Vital Bone Graft
Autograft
Oral- Osseous coagulum
Bone blend
Bone harvested from extraction site, Tuberosity,
Edentulous ridge
Extraoral- Iliac crest
70. 70
Allograft
Cryopreserved bone
Fresh bone from iliac crest
Nonvital Bone Graft
Allografts (human bone)
Freeze-dried bone allograft
Demineralized freeze-dried bone allograft
Xenograft
Anorganic bovine bone
72. 72
In determining what type of graft material to use, the
clinician must consider
The characteristics of the bony defect to be restored.
The larger the defect, the greater the amount of
autogenous bone required.
For small defects and for those with three to four bony
walls still intact, alloplasts may be used alone or with
allografts.
For relatively large defects or those with only one to
three bony walls intact, autogenous bone must be
added to any other type of graft material
73. Indications & Contraindications
73
Intrabony defect
Deep crater
Class II / III furcation
Combined osseous defect
Circumferential defect
Socket preservation
Ridge augmentation
Sinus augmentation
Subnasal elevation
Ridge split / expansion
Periimplant defect
Non contained defect
Defect depth < 3mm
One wall defect
Shallow crater
Horizontal bone loss
Local infection
Systemic condition
75. 75
Osseous Coagulum
Robinson 1969
Bone dust + Blood
obtained by carbide bur #6 or #8 at speeds between
5000 and 30,000 rpm
Advantage- provides additional surface area for the
interaction of cellular and vascular elements on
intraoral bone
Disadvantages- low predictability and inability to
procure adequate material for large defects
aspiration problems
76. 76
Bone Blend
Diem 1972
Plastic like mass
particle size range from 210 X 105µm
Cancellous bone marrow transplants
Maxillary tuberosity,
Extraction sockets 8-12 weeks and apical portion is used as donor
material
Bone swaging
Ewen 1965
requires an edentulous area adjacent to the defect, from which
the bone is pushed into contact with the root surface without
fracturing the bone at its base
77. 77
Bone From Extraoral Sites
Hegedus 1923
Iliac crest
Tibial plateau
Cranium
ILIAC BONE AND MARROW
Have the most osteogenic and regenerative potential and
one of the two graft materials with reported ability to
regenerate periodontium horizontally or with “zero wall”
defects, meaning actual crestal apposition of bone.
78. 78
Schallhorn & colleagues(1970)
Treated 182 osseous defects ranging from 3.3-4.2mm in 52
patients with iliac graft Resultant bone fill was 2.6mm in
‘zero or no wall’ defects,3.75mm in one wall defects &
4.16mm in 2 wall defects. Approximately 87% of class II
furcation had complete fill.
Hiatt & Schallhorn(1971)
Considered the fill of crestal facial and furcation defects to
be more clinically predictable using iliac autografts than
with intraoral cancellous bone.
79. Disadvantage
79
Second surgical site and
Possible morbidity associated with these procedures
Iliac bone and marrow may induce ankylosis and root
resorption, although the reported frequency is 5% or less
(Schallhorn 1972).
Increased patient expense and difficulty in procuring the
donor material
80. Nature of autograft
80
Cortical graft - Less surface & lining cells
Most cells undergo necrosis - cytolysis - releases
BMPs
Cancellous graft - More surface cells & lining cells
Surface cells get nutrition by diffusion
Only inner osteocytes - necrosis
For augmentation - Cortical
For regeneration - Cancellous
Composite bone graft - Minimum 20% autogenous
graft should be present
81. Allografts
81
Same species, but different genotype.
Source
Frozen iliac cancellous bone and marrow,
Cryopreserved bone from the head of femur
Freeze-dried bone allograft (FDBA),
Decalcified FDBA(DFDBA)
Mechanism - ‘Osteogenic stimulus
82. Bone allografts
82
Obtained from cortical
bone within 12 hours of
the death of the donor,
defatted, cut in pieces,
washed in absolute
alcohol, and deep-frozen
sieved to a particle size of
250 to 750 μm, and
freeze-dried.
Finally, it is vacuum-
sealed in glass vials
83. Drawbacks
83
Antigenicity
Risk of disease transfer
Need for extensive cross matching
All these have precluded the use of frozen iliac allografts in
periodontics
84. Bone biology harvesting grafting84
FDBA can be used in either a mineralized or a
demineralized (DFDBA) form.
FDBA may form bone by osteoinduction and
osteoconduction. Because it is mineralized, it
hardens faster than DFDBA.
FDBA is more effective than DFDBA in the following
situations:
1. Repair and restoration of fenestrations
2. Minor ridge augmentation
3. Fresh extraction sites (used as a fill)
4. Sinus lift cases (used as a graft)
5. Repair of dehiscences and failing implants
85. 85
Demineralised Freeze-dried bone allograft
Marshall Urist 1965
Induces host mesenchymal cells to differentiate into osteoblasts
DFDBA are more inductive FDBA
Healing following the use of DFDBA
Day 1 -Attachment of fibroblasts to ECM.
Day 5- Cell proliferation and differentiation of chrondroblasts .
Day 7- chondrocytes with synthesis and secretion of matrix.
Days 10-12 Vascular invasion, bone formation and
mineralization.
Day 21, marrow is observed.
86. Xenografts
86
Bone products from other species
Calf bone (Boplant) treated by detergent extraction,
sterilized, and freeze-dried.
Kiel bone is calf or ox bone denatured with 20%
hydrogen peroxide, dried with acetone, and sterilized
with ethylene oxide.
87. 87
Anorganic bone is ox
bone from which the
organic material has been
extracted by means of
ethylenediamine; it is
then sterilized by
autoclaving
Yukna et al - 15-amino
acid sequence Collagen I
+ Anorganic bovine bone
(PepGen P-15)
88. 88
Anorganic, bovine-derived bone (Bioss)
Osteoconductive, porous bone mineral matrix from
bovine cancellous or cortical bone.
The organic components of the bone are removed, but
the trabecular architecture and porosity are retained.
The physical features permit clot stabilization and
revascularization to allow for migration of osteoblasts,
leading to osteogenesis.
Used in combination with GTR for periodontal
regeneration
89. Periodontal surgery cohen89
Advantages
1. Unlimited supply
2. Safe
3. Biocompatible
4. Nonantigenic
5. Permits physiologic vascular
ingrowth
6. Permits complete integration and
incorporation into bone
7. Possesses the same structure as
bone:
a. Compact appetite crystalline
structure
b. Large inner surface area
c. Porosity similar to that of human
cancellous bone
91. Alloplasts
91
Inert Biologic fillers / Synthetic grafts
Ceramics and polymers
Ashman’s Criteria (1992)
Biocompatible Serve as framework
Resorbable and replaced by bone Osteogenic
Radiopaque Easy to manipulate
Not support growth of pathogen Hydrophilic
Surface electrical activity Microporous
Non allergenic Act as vehicle
High compressive strength
92. Classification of Ceramics
92
Hydroxyapatite (Ca : P = 1.67)
Calcium phosphate cement
Calcium sulphate (POP)
β tricalcium phosphate (Ca : P = 1.5)
Bioactive glasses
C-Graft
93. Plastic Materials
93
Hard tissue replacement (HTR) polymer
Non resorbable
Micro porous
Biocompatible composite of polymethylmethacrylate
and polyhydroxyethylmethacrylate
Histologically, encapsulated by connective tissue
fibers, with no evidence of new attachment
94. Calcium Phosphate Biomaterials
94
Periograf
Excellent tissue compatibility
Osteoconductive
Two types
Hydroxyapatite (HA) has a Ca:P -1.67
Similar to that found in bone material.
HA is generally nonbioresorbable.
Tricalcium phosphate (TCP) Calcium:P- 1.5
mineralogically B-whitlockite.
Partially bioresorbable.
Histologically these materials appeared to be
encapsulated by collagen
95. Beta- Tri CalciumPhosphate
95
Cerasorb
facilitates incorporation
of new tissue.
stable and highly
resistant to abrasion.
a round-particle size of
10 to 63 μm prevents
phagocytosis by
macrophages.
use as a PRP carrier.
96. Bioactive Glass
Carranza 13th
96
PerioGlas 90 to 170 μm, BioGran 300 to 355 μm
Consists of Na and Ca salts, phosphates and silicon
dioxide.
Bioactive Glass Tissue fluids Particle surface
Hydroxycarbonate apatite Organic ground
proteins( chondroitin sulfate and GAG) attracts
osteoblasts rapidly form bone.
Contacts
coated incorporates
97. COMPOSITE GRAFT
97
Used most frequently to
increase the advantages
of each product in the
mix and minimize the
disadvantages of each.
DFBA is added to
previously harvested
autogenous bone to
create a composite graft
mix.
98. Factors for the successful
incorporation
Gordh & Alberius 199998
Embryonic origin of the graft
Rate and extent of revascularization
Structural and biomechanical features
Rigid fixation of the graft to the recipient site
Graft orientation and
Availability of local growth factors.
99. Arun K Garg. Bone biology, harvesting, grafting for dental implants. 1st ed. Quint Pub.99
The higher the osteogenic potential of the defect and of the patient, the smaller the
amount of autogenous bone required and the more allogeneic and alloplastic materials
can be used.
100. Systematic review & Meta analysis
by Chen et al., 2013
100
GTR only group
GTR + Bone graft group
In Class II furcations
Findings
•GTR seemed to be more effective than OFD
•GTR + Bone graft technique showed even better clinical
results
101. RIDGE AUGMENTATION
101
At times, when teeth are lost due to periodontitis, large
defects in the alveolar bone involving the loss of one
or more socket walls results in defects in ridge
morphology.
Augmenting and regenerating the deficient alveolar
bone mainly for implant placement and restoring the
lost bone for functional and esthetic purposes
102. Alveolar crest defects
Classification(Siebert)
Class 1 Ridge Defects
when the bone deficiency is
predominantly
in horizontal dimension
Class 2 Ridge Defects
when the bone deficiency
is predominantly
in vertical dimension
Class 3 Ridge Defects
when the bone deficiency
affects both the vertical
and horizontal dimensions
Lindhe 6
103. RIDGE AUGMENTATION
103
Soft tissue Augmentation
Hard tissue Augmentation
Horizontal
Vertical
Combined
Both soft and Hard tissue Augmentation
104. Particulate bone grafting technique
Block grafting approaches
Combination approaches
Ridge expansion/ ridge splitting techniques
Distraction osteogenesis
Bone augmentation approaches using growth factors
TECHNIQUES
105. Critical size defect
105
Defined as the smallest osseous wound that does not
heal spontaneously over a long period of time.
Minimum size that renders a defect “critical”
is not well understood.
It has been defined as a segmental bone deficiency of a
length exceeding 2-2.5 times the diameter of the
affected bone.
Critical size defect model have been developed to
assess the biologic potential, safety, and efficacy of
new regenerative approaches prior to their use in
humans.
106. Optimal Bone Graft
106
Particle size - 125μm to 2mm
Most commercial products 500-1000μm
Critical minimum value - less than 75 μm to 125 μm is
rapidly resorbed
125μm to 1000μm - Highest osteogenic potential
Density = Compressive strength, Porosity = Extent of
vascular ingrowth
107. 107
GRAFT APPROXIMATE RESORPTION TIME
Illiac crest, Tibial plateau, Maxillary
Tuberosity
3-6 mos
Mandibular symphysis 4-8 mos
Bone shavings from adjacent surgical
site
3-7 mos
Bone suctioned while drilling
osteotomies
1-3 mos
FDBA 6-15 mo
108. 108
DFDBA 2-4 mo
POP 1-2 Wks
P-15 18-36 mo
Anorganic bovine bone 15-30 mo
HA 18-36 mo / Non resorbable
b-TCP 4-12 mo / Partial
Coral 5-7 yr
CaSo4 1-2 mo
HTR 10-15 yr / Non resorbable
Perioglass/Biogran 18-24 / 20-22 mo
110. Signaling molecules
Kao RT, Murakami S, Beirne OR: The use of biologic mediators and tissue engineering in dentistry.
Periodontol 2000 20:127, 2009110
Enamel matrix derivative
Autologous platelet-rich plasma preparations
recombinant growth factors
recombinant human platelet-derived growth factor-BB
recombinant human basic fibroblast growth factor
Morphogens
recombinant human bone morphogenetic protein
111. Enamel Matrix Derivative for
Periodontal Regeneration
111
Harvested from developing porcine teeth
Contains a mixture of low-molecularweight proteins that
stimulate cell growth and the differentiation of
mesenchymal cells, including osteoblasts.
Stimulates angiogenesis directly by stimulating endothelial
cell proliferation and chemotaxis, and stimulates VEGF
production by periodontal ligament cells.
113. 113
This mixture of growth factors in PRP stimulates the
Proliferation of fibroblasts and Pdl cells
ECM formation
Neovascularization.
Suppress cytokine release
Limit inflammation
Promoting tissue regeneration
114. Bone morphogenetic proteins
114
BMP are a group of regulatory glycoproteins that are
members of the transforming growth factor-beta
superfamily.
BMP 1 to 9, 12, 13, 14
Urist in 1965 coined the term BMPs or Osteogenetic
protein
Primarily stimulate differentiation of mesenchymal
stem cells into chondroblasts and osteoblasts.
115. 115
The available sources of BMPs
1) Human or animal bone matrices.
2) Recombinant DNA Technology.
3) Direct site application of DNA encoding for the
desired factor
Carriers
Natural-collagen, hyaluronin, chitosan, gelatin.
Synthetic- polyethelene glycol, polyethelene oxide,
matrix extracts
Non-resorbable- EPTFE, Ceramic, Titanium mesh.
Resorbable- Alpha hydroxyl acids,polyglycolic acids,
poly lactic acid.
116. Role of BMPs in Periodontal
Regeneration
116
RhBMP-2 has been proved to initiate bone induction process
through many histological studies.
When rhBMP-2 carrier complex is implanted, mesenchymal
cells which are undifferentiated infiltrate the periphery of
matrix, to degrade the matrix and invade the vascular
endothelium to differentiate into osteoblasts laying bony
trabeculae.
Later bony trabeculae undergoes physiological remodeling
Major limitations associated with the use of growth and
differentiation factors are their short biological half-lives
117. Scaffold or supporting matrices
117
Roles
To provide physical support for the healing area so that
there is no collapse of the surrounding tissue.
To serve as a barrier to restrict cellular migration.
To serve as a scaffold for cellular migration and
proliferation.
To potentially serve as a time-release mechanism for
signaling molecules
119. Gene therapy
119
Used for extended local delivery of factors.
Gene delivery of platelet-derived growth factor was
accomplished by the successful transfer of the platelet-
derived growth factor gene into the cementoblast and
other periodontal cell types.
Stimulates more cementoblast activity.
Safety and efficacy of using gene therapy for
regeneration have yet to be evaluated
122. Combination therapy
122
An additive effect from combining different
regenerative principles, including
Osteoconductivity and Osteoinductivity,
Capacity for space provision
Blood clot stabilization,
Ability to induce or accelerate the processes of matrix
formation and cell differentiation that are inherent in
barriers, grafts, and bioactive substances
123. Factors That Influence Therapeutic Success
123
Selection of the appropriate surgical technique.
Accurate assessment of the periodontal defect.
Clinician's clinical experience.
Importance of the tooth in the overall restorative
treatment plan.
Patient's selection of the regenerative options.
124. Therapeutic Considerations
124
Delicate and timely tissue management to minimize
tissue shrinkage
Passive flap closure for encasement of the graft
materials.
Flap design to allow tension-free suture placement
125. Tooth and Defect Related
Considerations
125
Tooth's importance in
Prosthetic rehabilitation
Endodontic status
Osseous defect characteristics.
Improved Regenerative results
Narrow defect > Wide defect
3/2 wall defect > 1/0 wall defect
126. Patient-Related Considerations
126
After therapy, the difficult challenge is to motivate
patients to be skilled, enthusiastic, and passionate
about their oral hygiene and compliant with
periodontal maintenance.
127. 127
Clinical Guidelines to Guide Clinicians in
Their Patient Management
Early diagnosis and appropriate addressing of the
defect
Early narrow intrabony (<3 mm) and furcation defects
can be blended in with the adjacent osseous contour.
Intrabony and furcation defects of >3 mm, periodontal
regeneration should be considered
128. Conclusion
128
Regenerative surgical treatment of intrabony periodontal
defects results in dramatic improvements of bone loss, CAL
and PD that cannot be matched by other nonsurgical and
surgical approaches.
These improvements are maintainable over many years if
appropriate maintenance care is used.
The combined approach is most useful in large wide
defects where bone grafts supply structural functions,
membranes provide guided tissue and graft retention
functions, and biologic agents give cellular enhancement.
130. ALLODERM
130
Acellular dermal allografts
Obtained from cadaver skin
Immunologically inert
Compatible
Memory free, easy to place
and adapt, and able to be
covered by soft tissue.
Unlimited supply, color
match, thickness.
Formation of additional
attached gingiva
131. 131
Maintains its collagen, elastin, and proteoglycans,
providing an undamaged acellular dermal matrix.
At the start of the surgery, the AlloDerm graft is placed
in saline solution for rehydration.
Once rehydrated it is indistinguishable
It is important to follow the product’s instructions
carefully to ensure that the correct side of the tissue is
placed.
Editor's Notes
Regeneration can either be complete whether the new tissue is same as the lost tissue or incomplete where lost tissue is replaced by fibrous tissue
The loss of tissue may be the result of birth defects, disease, trauma, malignancies, atrophy, or surgical excision.
When there is periodontal inflammation periodontal therapy is accomplished.periodontal therapy can be local or systemic or combination of both as require and tissue responses to periodontal apparatus are as follows Epithelium responded by Restoring surface continuity. Role of Connective tissue is to Attach bone to cementum. Bone responses by Restoring balance between bone formation and resorption and CEMENTUM by
Attaching periodontal fibers
For the successful reconstruction of periodontal tissues, the methods that are to be utilised should respect the natural sequence of biological events that occur during the periodontal healing The basic healing processes are same after all forms of periodontal therapy.
These processes consist of the removal of degenerated tissue debris and the replacement of tissues destroyed by disease
Stages of periodontal wound healing. Optimal periodontal healing requires different processes in a sequential manner.
After the initial coagulation phase, inflammatory reaction, and granulation tissue formation events, progenitor cells involved
in multitissue regeneration are locally recruited and mediate the bioavailability of important growth factors. As the healing
progresses, mechanical stimuli increase and promote an organized extracellular matrix (ECM) synthesis as well as cementum
and bone formation and maturation. Once those structures are established, periodontal ligament (PDL) fibers are organized and
oriented. Progressively, the tissues mature and ultimately increase in mechanical strength. Remodeling processes continue in the
regenerated periodontium as an essential mechanism that monitors the adaptation potential to the challenging local and systemic
environment.
Which type of healing occur in different disease.
Pericytes are perivascular endothelial cells from which osteoprogenitor cells as well as budding endothelial cells arise. Hence both blood supply and bone forming cells are pericytes .But they are one of the sources.. Since other sources are stem cells,bone marrow cells, etc
Gingival connective tissue Fibers parallel to the root surface and
remodeling of the alveolar bone with no
attachment to the cementum
New attachment with periodontal regeneration is the ideal outcome of periodontal therapy
This return of the destroyed periodontium to health involves regeneration and mobilization of epithelial and connective tissue cells into the damaged area and increased local mitotic divisions to provide sufficient numbers of cells
probing cannot accurately measure the connective
tissue attachment level, i.e., the coronal level of the
periodontal ligament . Large gains in clinical
attachment can occur after therapy without regeneration
of new periodontal ligament. These
“false” gains are due to resolution of inflammation,
bone fill, reformation of the gingival collagen fibers
and a long junctional epithelium. Probing
methods are therefore not adequate to evaluate periodontal
regenerative therapies.
Re-entry procedures typically involve reflapping a
site at some time after surgical therapy in order to
directly compare new bone levels to initial bone
levels. Although this method can measure the gross
behavior of bone, bone measurements do not reflect
connective tissue attachment levels and cannot distinguish
bone that is attached to the root surface via
a periodontal ligament and are, therefore, inappropriate
Similarly, changes in bone height, density
and volume can be estimated by pre- and posttreatment
radiographs but cannot distinguish whether
the bone is connected to the tooth by new periodontal
ligament and cementum (true regeneration
Histological evaluation is the only reliable method of
determining the efficacy of regenerative periodontal
therapies aimed at the creation of a new attachment
apparatus consisting of new bone, cementum and
Periodontal ligament
When considering periodontal regeneration, we
believe that at least four criteria must be met in
order for regeneration to have occurred. These include
all the features of the normal dentogingival
complex that would equate to restoration of these
tissues to their original form, function and consistency:
There are two primary sources of stem cells: adult stem cells and embryonic stem (ES) cells. In addition to these stem cells, which are naturally present in the human body, induced pluripotent stem (iPS) cells have been recently generated artificially via genetic manipulation of somatic cells . ES cells and iPS cells are collectively referred to as pluripotent stem cells because they can develop into all types of cells from all three germinal layers
Osseous
With all these surgical techniques outcome of healing is repair not regeneration because the original form and architecture of the
tissues have not been restored. This realization led
to further modifications to surgical treatments including
root surface conditioning and the use of
bone grafting materials in further attempts to attain
the elusive goal of periodontal regeneration.
In order to create an environment suitable to cell
repopulation it was considered that the root surface
needed to be cleaned and prepared in a manner
conducive to cell attachment and subsequent matrix
synthesis. For these reasons root surfaces were ‘‘conditioned. Mechanical biomodification in its simplest form, involves scaling & root planing. This may include cementum removal, removal of softened dentin or smoothening of surface irregularities
Chemical biomodification has centered on acid therapy to demineralize an overly mineralized root
It was suggested for smear layer removal by Register & Burdick, 1976
broad-spectrum antibiotics which are effective in controlling periodontal pathogens.
Studies have shown that a chelating agent such as EDTA working at a neutral pH appears preferable with respect to preserving the integrity of exposed collagen fibers, early cell colonization and periodontal wound healing
Elimination of the junctional and pocket epithelium may not be
sufficient because the epithelium from the excised margin may
rapidly proliferate to become interposed between the healing
connective tissue and the cementum
GTR used for Prevention of epithelial migration along the cemental wall of the pocket.
maintaining space for clot stabilization. Derived from the classic studies of Nyman, Lindhe,
Karring, and Gottlow in 1982 , GTR is based on the assumption that
periodontal ligament and perivascular cells have the potential for
regeneration of the attachment apparatus of the tooth
The goal of tissue integration is to prevent rapid epithelial downgrowth on the outer surface of the material or encapsulation of the material, and to provide stability to the overlying flap membranes needed an
organized open microstructure to encourage tissue integration.
a second design criterion:
membranes should separate cell types so that the
desired cells (those originating from the periodontal ligament
and bone) could repopulate the defect area.
third design criterion: materials would have to be cut and shaped easily. They had
to hold sutures and, in case of complication, had to be
removed easily.
With the spacemaking design criterion in mind, the material
was redesigned and the center portion of the membranes stiffened to support the membrane and resist collapse
from the pressure of overlying tissue. The periphery of the
membranes was left soft and more porous to provide for
tissue ingrowth and wound stabilization, while allowing the
membrane to contour and seal against the bony defect margins,
.
Used to treat bone resorption around a crowned molar.
Membrane attached with resorbable sutures will act as a barrier for 6 weeks and will completely resorb after 12 months
In this
system, peripheral blood is collected from
the patient in specific tubes and immediately
processed by one-step centrifugation. This
process activates the coagulation cascade and leads to three-dimensional fibrin clot formation
ADVANTAGE
Interest in bone replacement grafts has emerged
from the desire to “fill” an intrabony or furcation defect
rather than radically resect surrounding intact
bone tissue.
In 1923, Hegedüs attempted to use bone grafts for the
reconstruction of bone defects produced by periodontal disease.
The method was revived by Nabers and O'Leary in 1965, and
numerous efforts have been made since that time to define its
indications and technique. Shavings of cortical bone removed by hand chisels during osteoplasty and ostectomy were used to treat one, two wall defects(Nabers & O’Leary 1965)
Due to large particle size(1559.6 X 183µm), and potential for sequestration, they were replaced by osseous coagulum and bone blend
BONE BLEND Bone is removed from a predetermined site,using a trephine, chisel or rongeur triturated in the capsule to a workable, plastic-like mass, and packed into bony defects.
Disadvantages - postoperative infection, Bone exfoliation, Sequestration, root resorption, recurrence of defect, increased patient expense and difficulty in procuring the donor material
No longer used in periodontal regenerative therapy
Cancellous graft /Trabecular bone - 75%
soft tissue (endosteum & bone marrow)
and 25% trabeculae
• Rapid graft revascularization (in weeks)
• Rapid incorporation Cancellous bone grafts have a greater likelihood of supporting cell survival possibility of diffusion of nutrients and revascularization from the recipient bed
• Cortical bone - 90% mineralised tissue -
maintains graft volume
Fresh allografts are the most antigenic; freezing or freeze-drying the bone significantly reduces the
Antigenicity. Bone allografts obtained from cadavers undergo strict screening and
processing by tissue banks before they are made available to surgeons.
(a) Strict donor screening begins with blood tests.
(b) Culture studies are performed on tissue samples from the medullary canal,
the specific tissues being donated, and the entire donor.
Additional cultures are taken throughout the various steps of tissue
processing. Material that is ready for distribution may have undergone as many
as 200 cultures.
(d) High-quality tissue banks follow strict procedures for preparing and
procuring specimens, beginning with a full surgical preparation within 24 hours
of the donor’s death.
(e) The donor is prepared in completely sterile and aseptic conditions. A detailed
autopsy is conducted to ensure that there are no underlying medical conditions
that could contraindicate the use of the donor’s tissues.
(f) The different tissues are classified and placed in trays.
(g) The soft tissue is stripped from the bone surface, both by hand and
mechanically.
(h) Large pieces of bone are cleaned and placed in separate containers.
(i) Osseous tissues are cut into different configurations according to the request
of various surgical specialties (eg, orthopedics, oral surgery).
(j) Bones are cut into standard sizes and shapes or, when possible, based on a
surgeon’s particular needs.
(k) The grafts are then ready for the removal of lipids, cells, and moisture.
(l) Tissues are soaked in sterile solutions to remove unwanted compounds.
(m) Once the lipids and cells are removed, the pieces are crushed into powders.
(n) The bone powders are passed through sifters to obtain particles of various
sizes.
.
Demineralization removes the mineral phase of the graft material and
exposes the underlying bone collagen and possibly some growth
factors, particularly bone morphogenetic proteins (BMPs), which may increase
its osteoinductive capabilities. FDBA may form bone by osteoinduction
and osteoconduction.
PepGen P-15 mimics autogenous bone; it has an inorganic bovine bone
mineral and an organic component (the specific sequence of 15 amino acids
designated as P-15). This peptide is involved in cell binding, attracting
osteoblasts at a rate exponentially higher than that of the same graft material
without the peptide.
(c) PepGen P-15 is available in 1-and 2-g vials. Adding a small amount of PepGen P-15 to
harvested autogenous bone will assist in slowing the rapid resorption rate of
autogenous bone and enhance the radiopacity of the graft for better definition on
radiographs.
This material has been used in the fabrication of contact lenses, lens transplants, and prosthetic heart valves over many years. The polymer does not produce an inflammatory or immune response in contact with bone or soft tissue as described by Yukna in 1990
completely resorbed and replaced by new
bone 3 to 24 months after grafting.
PerioGlas has demonstrated two favorable characteristics:
ease of compactability and ability to promote hemostasis. When well packed
into osseous defects, this material was strongly adherent and appeared to harden
into a solid mass after placement in the defect. After a few minutes, it remained
in the osseous defect, even when a suction tip or handpiece was used in the
vicinity. Hemorrhaging from the defects stopped within a few seconds after graft
placement.
In wound healing, the natural healing process usually results in
tissue scarring or repair. By using tissue engineering, the wound
healing process is manipulated so that tissue regeneration occurs.
This manipulation usually involves one or more of the three key
elements: the signaling molecules, scaffold or supporting matrices,
and cells
PRP is a concentrated autologous source of several growth factors A mixture of thrombin and calcium chloride
is used to activate the concentrated platelets to release their growth factors and
to initiate gelling for better clinical handling
role of BMPs in regeneration is being enlightened based on its unique property of osteoinduction
Chitosan: a deacetylated derivative of chitin is biomaterial used for regeneration
Gene therapy uses genetically
modified cells to deliver specific doses of a bioactive protein
for a sustained period.
If the tooth has little or no importance in the overall treatment plan, extraction may be
indicated to avoid potential technical difficulties, postsurgical
complications, and expenses
AlloDerm has two distinct sides, the “dermal” side and the “basement membrane”side. The dermal side absorbs blood. The basement membrane side repels blood. When applied to the wound bed in a grafting procedure, the dermal side should be placed against the wound bed, with the basement membrane side facing up.
Procedure for determining orientation To determine proper orientation once the graft has been rehydrated, add a drop of blood to both sides of the graft and rinse with rehydration solution. The dermal side will have a bloody appearance, whereas the basement membrane side will appear pink