Orthognathic Surgery
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Orthognathic surgery involves the surgical manipulation of the elements of the facial skeleton to restore the proper anatomic and functional relationship in patients with dentofacial skeletal anomalies. [1, 2]
This article provides an overview of the principles used in orthognathic surgery, which can be used to manage a broad spectrum of maxillofacial abnormalities, including congenital, developmental, and acquired deformities.
While an exhaustive history is not possible, a brief chronologic history of orthognathic procedures follows.
1846 – Hullihan – Anterior mandibular subapical osteotomy and setback
1906 – Blair – Mandibular body osteotomy
1907 – Blair – Horizontal osteotomy of the ramus, external approach
1925 – Limberg – Posterior oblique vertical ramal osteotomy, external approach
1927 – Wassmund – Inverted “L” ramal osteotomy, external approach
1939 – Kazanjian – Beveled horizontal osteotomy of the ramus, extraoral approach
1942 – Schuchardt – Step horizontal osteotomy of the ramus, intraoral approach
1954 – Caldwell and Letterman – Vertical ramal osteotomy, external approach
1955 – Obwegeser – Sagittal split ramal osteotomy
1968 – Caldwell et al – “C” ramal osteotomy
1970 – Hebert, Kent, and Hinds – Intraoral vertical ramal osteotomy
1927 – Wassmund – Le Fort I osteotomy with the pterygomaxillary junction left intact; elastic forces used to bring the maxilla forward
1928 – Axhuasen – Segmental osteotomy through the mid palate
1942 – Schuchard – Staged Le Fort I osteotomy, followed by pterygomaxillary separation; external traction used to bring the maxilla forward
1949 – Moore and Ward – Horizontal transection of the pterygoid plate
1965 – Obwegeser – Fully mobilized the maxilla; in a single step brought it into the predicted position
1942 – Hofer – Horizontal sliding osteotomy of a receding chin (extraoral)
1957 – Trauner and Obwegeser – Intraoral approach to osseous genioplasty [3]
Historically, the ability to reposition the mandible in a stable manner long preceded the ability to reposition the maxilla. As a consequence, many patients underwent only mandibular surgery to correct a primary maxillary deformity. The specialty of orthognathic surgery did not fully develop until Obwegeser demonstrated the possibility of repositioning the maxilla in a stable consistent manner in 1965 and reported simultaneous repositioning of the maxilla and mandible in 1970.
The word orthognathic comes from the Greek word orqos, meaning to straighten, and gnaqos, meaning jaw. Orthognathic surgery thus means to straighten a jaw. Defining a straight jaw versus one that is not requires determining the degree of deviation from a specified population norm. Nevertheless, restoring the orthognathic form of the face ultimately depends upon achieving the ideal facial esthetics of the individual patient, not simply restoring the average normative values of a population.
Remember that the face is more than the upper and lower jaw; when deformities extend to involve the cranio-orbital skeleton, evaluation and management expand the scope of maxillofacial surgery to craniofacial surgery. Thus, orthognathic or maxillofacial surgery is a subset of craniofacial surgery.
Correction of maxillofacial deformities requires careful analysis of the soft tissue with clinical examination and supporting photographs, skeletal evaluation with standardized radiographs, and dental evaluation with study dental casts. Formulation of a treatment plan thus requires close cooperation of the surgeon working with the dentist, the orthodontist, and at times the restorative prosthodontist. Unlike many surgical procedures, outcome depends not only on the surgical procedure but also on a multitude of factors that begin long before the actual surgery as well as on control of the variables long after surgery.
The exact incidence of dentofacial deformities requiring orthognathic surgery is difficult to estimate because it includes a broad population of patients with deformities of congenital, developmental, and traumatic origin. However, the number of individuals with developmental dentofacial deformities in the United States who may benefit from orthognathic surgery is estimated at 1.5–2 million; of these, approximately 1 million present with Class II deformities and 0.5 million with Class III deformities. In other regions of the world, the distribution among these classes seems to vary.
Dentofacial skeletal anomalies generally occur as a result of a differential in growth of the upper facial skeleton to the lower facial skeleton, resulting in discrepancy of the normal relationship that exists between the upper and lower jaw. Underlying genetic predisposition and acquired causes can influence the normal growth of the facial skeleton. Congenital anomalies, from syndromic conditions such as Apert and Crouzon syndromes to facial clefts, affect normal growth and development.
Traumatic events in the mature skeleton can displace the normal elements and require repositioning osteotomies if improperly reduced initially. Traumatic events in the developing facial skeleton can disturb normal subsequent growth. Other etiologies that can result in significant dentofacial anomalies include neoplastic growth, surgical resection, and iatrogenic radiation. However, of all the etiologies, developmental anomalies representing the extremes of population norms are the most common conditions requiring orthognathic surgery.
A wide range of clinical presentations is possible, some of which are outlined in the table below. Diagnosis is based on a comprehensive assessment that includes clinical examination, skeletal evaluation with standardized radiographs, and dental evaluation with study dental casts addressed as an integral part of the workup.
See the image below.
Clinical assessment should be directed specifically at evaluating the relative position and size of each of the facial skeletal elements, the degree of zygomatic projection, and the maxillary and mandibular positions in space relative to each other and to the cranial-orbital region. The nasolabial angle, upper lip length, lip competency, labial-mental sulcus, and cervicomental angle should be documented. Any facial asymmetry should be noted along with the relationship of the maxillary dental mid line to the mandibular dental mid line and the dental mid lines to the facial mid line. The intraoral examination should focus on the dental alignment within each arch and relationship of the dental arches to each other. The degree of dental display on repose and smile also should be recorded with the amount of gingival display.
Facial balance typically is assessed by dividing the face in thirds. The upper third is from the anterior hairline (trichion) to the glabella, the middle third from the glabella to the subnasale, and the lower third from the subnasale to the menton. When each of the thirds is equal, the face is said to be balanced and of “ideal” proportions. The lower third may be further divided into an upper third (subnasale to oral commissure) and a lower two thirds (oral commissure to menton). Additionally, in profile view the face should have a slight degree of convexity as measured from the glabella to the subnasale to the menton.
See the image below.
Excess facial convexity, flatness, or concavity is felt to be less than ideal. However, facial proportions are only idealized concepts and have changed over time. They merely provide a guideline that is not true for every patient; a wide range of aesthetic faces defies such absolute canons.
See the image below.
Maxillofacial deformities can be divided broadly into 3 major categories: (1) dental dysplasias, (2) skeletal dysplasias, and (3) dentoskeletal dysplasias.
Dental dysplasias are limited strictly to malocclusions that result from abnormal spatial relationship of the dentition and not from the skeletal position of the upper and lower jaws. These can be corrected with orthodontic treatment.
In patients with skeletal dysplasia only, the dentition is in good alignment, but the maxilla and/or mandible are dysplastic. Skeletal dysplasias require correcting the skeletal deformity without altering the occlusion. An example is a patient with retrogenia without retrognathia or a patient with hemifacial microsomia who has a normal maxillary-mandibular dental relationship but has an occlusal cant because of skeletal asymmetry.
In dentoskeletal dysplasias, the dentition is malpositioned within each arch and with each other; additionally, the skeletal relationship of the upper and lower jaws is abnormal. An example is a patient with a maxillary sagittal and transverse width deficiency from a facial cleft. Correction requires aligning the dentition within each arch with orthodontic treatment and restoring the maxillary-mandibular dental relationship with skeletal osteotomies and repositioning. In addition, dentoskeletal dysplasias can be classified further based on the position in space and on the volume or mass (whether deficient or in excess) of the individual elements. For example, the mandible can be of normal shape and volume but retrognathic in relationship to the maxilla, or it may be both retrognathic and volumetrically deficient.
Table. Typical Presentation of Maxillofacial Deformities (Open Table in a new window)
Deformity
Clinical Features
Skeletal Assessment
Dental Assessment
Maxilla: Sagittal deficiency
Concave facial profile
Retrusive upper lip
Acute nasolabial angle
Alar base narrow
Lack of dental display
SNA* decreased
SNB† normal
ANB‡ decreased
Class III
Maxillary dental crowding
Maxillary incisors proclined
Mandibular incisors normal or retroclined
Maxilla: Sagittal excess
Convex facial profile
Obtuse nasolabial angle
SNA increased
SNB normal
ANB increased
—
Maxilla: Vertical excess (long face syndrome)
Convex profile
Lower facial height increased
Alar base constricted
Nasolabial angle obtuse
Excessive incisor show
Excessive gingival show
Lip incompetence
Mentalis strain with lip closure
Chin vertically long, retruded
Lower FH§ increased
SNA decreased
SNB decreased
ANB increased
Mandibular plane angle steep
Palatal-occlusal plane increased
Class II, Class I
Anterior open bite
Maxillary arch constricted
Curve of Spee, flat-accentuated
Dental crowding
Maxilla: Vertical deficiency (short face syndrome)
Concave facial profile
Lower facial height decreased
Acute nasolabial angle
Alar base widened
Lack of incisor show
Edentulous appearance
Chin protruded
Lower FH decreased
SNB increased
ANB negative
Palatal-occlusal plane decreased
Mandibular plane angle acute
Class II, Class I
Deep bite
Crowding
Mandibular dentition
Curve of Spee reverse
Mandible: Deficiency
Convex profile
Retruded chin
Everted lower lip
Deep labiomental crease
Mentalis strain with lip closure
SNA normal
SNB decreased
ANB increased
Ar-Gn¶ decreased
Class II
Mandibular incisors proclined
Maxillary incisors retroclined
Curve of Spee accentuated
Mandible: Excess
Concave profile
Midface appears deficient
Lower third broad
Lower lip thin
SNA normal
SNB decreased
ANB decreased
Class II
Maxillary incisors proclined
Mandibular incisors retroclined
* SNA = Sella-nasion-A point angle
† SNB = Sella-nasion-B point angle
‡ ANB = A point-nasion-B point angle
§ FH = Frankfort horizontal
¶ Ar-Gn = Articulare-gnathion
Indications for orthognathic surgery include facial dysmorphism with and without functional implications. As an illustration, an osseous genioplasty for a patient with retrogenia but without malocclusion should be considered for facial form. If the retrogenia is associated with retrognathism resulting in a malocclusion, orthognathic surgery is indicated for restoring the facial form and for functional occlusion. Airway and speech are other indications when considering the functional need for orthognathic surgery. Restoration of the normal anatomic relationship between the maxilla and mandible relative to the cranial base reestablishes the functional components (ie, form and function) of the facial skeleton.
As relevant skeletal and neurovascular anatomy can be found in many anatomic atlases, this section focuses on specific aspects pertinent to the procedures described.
With maxillary osteotomies, an understanding of the vascular blood supply to the mobilized maxilla is crucial. The arterial blood supply to the maxilla is derived from 4 primary sources: (1) the descending palatine branch of the maxillary artery, (2) the ascending palatine branch of the facial artery, (3) the anterior branch of the ascending pharyngeal artery from the external carotid, and (4) the alveolar branches of the maxillary artery. With complete mobilization of the maxilla, frequently the descending palatine vessels are disrupted and the mobilized maxilla derives its vascularity from the remaining sources, primarily the ascending palatine and pharyngeal vessels.
To avoid neurosensory deficits with mandibular osteotomies, the surgeon must be cognizant of the course of the inferior alveolar nerve from its entrance at the mandibular foramen on the medial aspect of the ramus to its emergence from the mental foramen between the first and second premolars. Vertically, the mandibular foramen typically lies approximately 8 mm inferior to the lingula mandibularis (the anterior wall of the mandibular foramen), and the lingula is approximately 5 mm above the occlusal plane. With the sigmoid notch as a reference point, the foramen is approximately 20 mm inferior. Regarding the anterior-to-posterior relationship, the foramen is located 20 mm from the anterior mandibular ramal border, a depth of approximately two thirds of the total mandibular ramal width.
The canal then courses within the mandible, measuring 2-2.5 mm in diameter. Its lowest point from the inferior mandibular border is in the region of the first and second molars, approximately 7.5 mm, before continuing anterior and superior to its emergence from the mental foramen, where it is approximately 8 mm from the inferior border. At the mental foramen, the canal extends caudally before emerging. Regarding the transverse position of the canal within the mandible, it is most superficial in the region of the third molar, approximately 2 mm from the buccal plate. In the region of the first molar, it is 4 mm from the buccal plate.
A number of basic dental concepts pertinent to orthognathic surgical procedures are important.
Universal Dental Notation is the most common system for numerically identifying permanent dentition. The maxillary dentition is numbered sequentially from 1-16 starting with the right maxillary third molar as 1. The numbering system continues from 17-32 beginning with the left mandibular third molar as 17.
Orientation with respect to intraoral anatomy is referenced to the following terms:
Mesial – Toward the dental mid line
Distal – Away from the dental mid line
Labial – Toward the lips
Buccal – Toward the cheek
Apex – Toward the root tip
Lingual – Toward the tongue
Incisal – Toward the biting surface (anterior dentition)
Occlusal – Toward the biting surface (posterior dentition)
Angulation – Mesiodistal tipping of the long axis of the tooth
Inclination – Labiolingual or buccolingual tipping of the long axis of the tooth
See the list below:
Cusp – Pronounced elevation on the occlusal surface
Groove – Depression on the occlusal surface
Crown – Visible portion of the tooth covered by enamel
Cingulum – Bulbous convexity of the cervical one third of the lingual surface of anterior dentition
Cervix (neck) – Junction of the crown and root
Root – Portion of the tooth covered by cementum within the alveolar bone
Curvature of the dental arches – Normal reciprocal curvature in the dental arches with the maxilla convex and the mandible concave (allows the dentition maximal contact during function)
Curve of Spee – Normal curvature of the dental arch in the sagittal plane
Curve of Wilson – Normal curvature of the dental arch in the coronal plane
The classification of dental occlusions is based on Edward Angle’s observation in 1899 that the key to occlusion is the relationship of the mandibular first molar to the maxillary first molar. [4]
Angle Class I (neutro-occlusion): The mesiobuccal cusp of the maxillary first molar articulates within the mesiobuccal groove of the mandibular first molar.
Angle Class II (disto-occlusion): The mandibular first molar articulates distal to the mesiobuccal cusp of the maxillary first molar. [5]
Angle Class III (mesio-occlusion): The mesiobuccal groove of the mandibular first molar is mesial to the mesiobuccal cusp of the maxillary first molar. [6]
Angle’s original classification has been expanded to include the anterior dentition. Class II is subdivided further to include the angulation of the anterior dentition. In Class II, Division 1, the molar relationship is Class II, but the maxillary anterior teeth are flared labial. In Class II, Division 2, the molar relationship is Class II, but both the maxillary and mandibular anterior teeth are retruded with a deep bite. The terms Class I, II, and III also are used to relate the maxillary and mandibular canine relation.
The Angle classification relates only to maxillary dentition with the mandibular dentition. While it generally is assumed that a similar skeletal relationship of Class I, II, and III follows, this is not always the situation. A Class I molar relationship is possible with a Class II skeletal relationship by dental extractions and orthodontic alignment without regard to basal skeletal morphology.
Additional terms are used to describe the relationship between the dentition of the upper and lower arches.
Overjet – Horizontal distance between the incisal edges of the maxillary incisor to the mandibular incisor
Overbite – Vertical distance between the incisal edge of the maxillary incisor and the mandibular incisor
Crossbite – Lingual-buccal malposition of the normal relationship between the upper and lower dentition (negative overjet)
Deep bite – Condition of excessive overbite
Open bite – Condition of negative overbite (teeth do not meet)
The anterior dentition typically inclines so as to partly offset the malocclusion and may allow some degree of anterior occlusion to occur depending on the maxillary-mandibular discrepancy. In prognathism, the lower incisors may be flared lingual and the upper incisors flared labial to compensate for the Class III malocclusion. Conversely, with mandibular deficiency the opposite occurs; the mandibular dentition is flared labial and the maxillary dentition flared lingual.
Centric relation is the most retruded position of the condyle within the glenoid fossa (terminal hinge position). It refers to the condylar-glenoid fossa relation but does not indicate the occlusion. Centric occlusion indicates the maximum intercuspal contact of the dentition and does not refer to the condylar position. In the ideal situation, when the patient is in centric occlusion (maximum), the condylar-glenoid is in proper centric relation.
Numerous risk factors may alter the treatment plan or preclude surgery, including underlying medical conditions, bleeding dyscrasias, systemic disease or local factors that may affect normal wound healing, compromised vascularity of the surgical region, a patient with unrealistic expectations, a noncompliant patient, and patients with poor oral hygiene.
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Naini FB, Gill DS. Orthognathic Surgery: Principles, Planning and Practice. Wiley Blackwell; 2017.
Trauner R, Obwegeser H. The surgical correction of mandibular prognathism and retrognathia with consideration of genioplasty. I. Surgical procedures to correct mandibular prognathism and reshaping of the chin. Oral Surg Oral Med Oral Pathol. 1957 Jul. 10(7):677-89; contd. [Medline].
Angle EH. Classification of Malocclusion. Dental Cosmos. 1899. 41(3):
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Deformity
Clinical Features
Skeletal Assessment
Dental Assessment
Maxilla: Sagittal deficiency
Concave facial profile
Retrusive upper lip
Acute nasolabial angle
Alar base narrow
Lack of dental display
SNA* decreased
SNB† normal
ANB‡ decreased
Class III
Maxillary dental crowding
Maxillary incisors proclined
Mandibular incisors normal or retroclined
Maxilla: Sagittal excess
Convex facial profile
Obtuse nasolabial angle
SNA increased
SNB normal
ANB increased
—
Maxilla: Vertical excess (long face syndrome)
Convex profile
Lower facial height increased
Alar base constricted
Nasolabial angle obtuse
Excessive incisor show
Excessive gingival show
Lip incompetence
Mentalis strain with lip closure
Chin vertically long, retruded
Lower FH§ increased
SNA decreased
SNB decreased
ANB increased
Mandibular plane angle steep
Palatal-occlusal plane increased
Class II, Class I
Anterior open bite
Maxillary arch constricted
Curve of Spee, flat-accentuated
Dental crowding
Maxilla: Vertical deficiency (short face syndrome)
Concave facial profile
Lower facial height decreased
Acute nasolabial angle
Alar base widened
Lack of incisor show
Edentulous appearance
Chin protruded
Lower FH decreased
SNB increased
ANB negative
Palatal-occlusal plane decreased
Mandibular plane angle acute
Class II, Class I
Deep bite
Crowding
Mandibular dentition
Curve of Spee reverse
Mandible: Deficiency
Convex profile
Retruded chin
Everted lower lip
Deep labiomental crease
Mentalis strain with lip closure
SNA normal
SNB decreased
ANB increased
Ar-Gn¶ decreased
Class II
Mandibular incisors proclined
Maxillary incisors retroclined
Curve of Spee accentuated
Mandible: Excess
Concave profile
Midface appears deficient
Lower third broad
Lower lip thin
SNA normal
SNB decreased
ANB decreased
Class II
Maxillary incisors proclined
Mandibular incisors retroclined
Pravin K Patel, MD Chief of Craniofacial Surgery and Professor of Surgery, Division of Plastic Surgery, University of Illinois College of Medicine; Chief of Plastic and Craniofacial Surgery, Shriners Hospitals for Children
Disclosure: Serve(d) as a director, officer, partner, employee, advisor, consultant or trustee for: ImmersiveTouch.
David E Morris, MD Assistant Professor of Surgery, Division of Plastic, Reconstructive, and Cosmetic Surgery, University of Illinois at Chicago College of Medicine; Staff Surgeon, Shriner’s Hospital for Children
David E Morris, MD is a member of the following medical societies: Chicago Medical Society, Illinois State Medical Society
Disclosure: Nothing to disclose.
Linping Zhao, PhD Research Specialist and Craniofacial Fellow, Shriners Hospitals for Children, Chicago; Visiting Research Assistant Professor of Surgery, Department of Surgery, University of Illinois at Chicago; Adjunct Assistant Professor, Bioengineering Department, University of Illinois at Chicago; Adjunct Assistant Professor, Biomedical Department, Marquette University
Linping Zhao, PhD is a member of the following medical societies: American Cleft Palate-Craniofacial Association
Disclosure: Nothing to disclose.
Francisco Talavera, PharmD, PhD Adjunct Assistant Professor, University of Nebraska Medical Center College of Pharmacy; Editor-in-Chief, Medscape Drug Reference
Disclosure: Received salary from Medscape for employment. for: Medscape.
Jorge I de la Torre, MD, FACS Professor of Surgery and Physical Medicine and Rehabilitation, Chief, Division of Plastic Surgery, Residency Program Director, University of Alabama at Birmingham School of Medicine; Director, Center for Advanced Surgical Aesthetics
Jorge I de la Torre, MD, FACS is a member of the following medical societies: American Burn Association, American College of Surgeons, American Medical Association, American Society for Laser Medicine and Surgery, American Society of Maxillofacial Surgeons, American Society of Plastic Surgeons, American Society for Reconstructive Microsurgery, Association for Academic Surgery, Medical Association of the State of Alabama
Disclosure: Nothing to disclose.
John Arthur Persing, MD Chief and Professor, Department of Surgery, Sections of Plastic Surgery and Neurosurgery, Yale University School of Medicine
John Arthur Persing, MD is a member of the following medical societies: American Academy of Pediatrics, American Society of Plastic Surgeons, American Association of Neurological Surgeons, American Cleft Palate-Craniofacial Association, American College of Surgeons, American Medical Association, American Society of Maxillofacial Surgeons, New York Academy of Sciences, Society for Neuroscience
Disclosure: Nothing to disclose.
Andrew Gassman, MD Resident Physician, Department of General Surgery, Loyola University Medical Center
Disclosure: Nothing to disclose.
Acknowledgments
The authors are grateful for the many years of generous support provided by Shriners Hospitals for Children in caring for children with facial skeletal deformities.
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