Otoplasty (Greek, Modern (1453-);: [[Wikt:οὖς|οὖς]],, "ear" + Greek, Modern (1453-);: [[Wikt:πλάσσω|πλάσσειν]],, "to shape") is a procedure for correcting the deformities and defects of the auricle (external ear), whether these defects are congenital conditions (e.g. microtia, anotia, etc.) or caused by trauma.[1] Otoplastic surgeons may reshape, move, or augment the cartilaginous support framework of the auricle to correct these defects.
Congenital ear deformities occasionally overlap with other medical conditions (e.g. Treacher Collins syndrome and hemifacial microsomia).
Otoplasty (surgery of the ear) was developed in ancient India and is described in the medical compendium, the (Sushruta's Compendium,). The book discussed otoplastic and other plastic surgery techniques and procedures for correcting, repairing and reconstructing ears, noses, lips, and genitalia that were amputated as criminal, religious, and military punishments. The ancient Indian medical knowledge and plastic surgery techniques of the were practiced throughout Asia until the late 18th century; the October 1794 issue of the contemporary British Gentleman's Magazine reported the practice of rhinoplasty, as described in the . Moreover, two centuries later, contemporary practices of otoplastic praxis were derived from the techniques and procedures developed and established in antiquity by Sushruta.[2]
In German: Die operative Chirurgie (Operational Surgery, 1845), Johann Friedrich Dieffenbach (1794–1847) reported the first surgical approach for the correction of prominent ears — a combination otoplasty procedure that featured the simple excision (cutting) of the problematic excess cartilage from the posterior sulcus (back groove) of the ear, and the subsequent affixing, with sutures, of the corrected auricle to the mastoid periosteum, the membrane covering the mastoid process at the underside of the mastoid portion of the temporal bone, at the back of the head.[3] [4]
In 1920, Harold D. Gillies (1882–1960) first reproduced the auricle by burying an external-ear support framework, made of autologous rib cartilage, under the skin of the mastoid region of the head, which reconstructed the auricle; he then separated this from the skin of the mastoid area by means of a cervical flap. In 1937, Dr. Gillies also attempted a similar pediatric ear reconstruction with an auricle support framework fabricated from maternal cartilage. This otoplasty correction technique proved inadequate, due to the problems inherent to the biochemical breakdown and elimination (resorption) of the cartilage tissue by the patient's body.
In 1964, Radford C. Tanzer (1921–2004) re-emphasized the use of autologous cartilage as the most advantageously reliable organic material for resolving microtia (abnormally small ears), because of its great histologic viability, resistance to shrinkage, and resistance to softening, and lower incidence of resorption.
The development of plastic surgery procedures, such as the refinement of J.F. Dieffenbach's ear surgery techniques, has established more than 170 otoplasty procedures for correcting prominent ears, and for correcting defects and deformities of the auricle; as such, otoplasty corrections are in three surgical-technique groups:
The external ear (auricle) is a surgically challenging area in terms of anatomy, composed of a delicate and complex framework of shaped cartilage that is covered, on its visible surface, with thin, tightly adherent, hairless skin. Although of small area, the surface anatomy of the external ear is complex, consisting of the auricle and the external auditory meatus (auditory canal). The outer framework of the auricle is composed of the rim of the helix, which arises from the front and from below (anteriorly and inferiorly), from a crus (shank) that extends horizontally above the auditory canal. The helix merges downwards (inferiorly) into the cauda helices (tail of the helix), and connects to the lobule (earlobe). The region located between the crura (shanks) of the antihelix is the triangular fossa (depression), while the scapha (elongated depression) lies between the helix and antihelix. The antihelix borders in the middle (medially) to the rim of the concha (shell) and the concha proper, which is composed of the conchal cymba above (superiorly) and the conchal cavum below (inferiorly), which are separated by the helical crus, and meet the antihelix at the antihelical rim. The tragus (auditory canal lobule) and the antitragus (counterpart lobule) are separated by the intertragal notch; the auditory canal lobule does not contain cartilage, and displays varied morphologic shapes and attachments to the adjacent cheek and scalp.
The superficial temporal and posterior auricular arteries preserve the arterial blood supply of the external ear. The sensory innervation involves the front and back (anterior and posterior) branches of the greater auricular nerve, and is reinforced by the auricular temporal and lesser occipital nerves. The auricular branch of the vagus nerves supplies a portion of the posterior wall of the external auditory canal.[14]
The support framework of the reconstructed auricle must be more rigid than the natural cartilage framework of a normal ear, in order for it to remain of natural size, proportion, and contour. If the reconstructed auricle framework were as structurally delicate as the cartilage framework of a natural auricle, its anatomic verisimilitude as an ear would gradually be eroded by a combination of the pressure of the tight skin-envelope in the temporal region of the head, and of the pressure of the progressive contracture of the surgical scar(s).
In the practice of otoplasty, the term "prominent ears" describes external ears (auricles) that, regardless of their size, protrude from the sides of the head. The abnormal appearance exceeds the normal head-to-ear measures, wherein the external ear is less than 2cm (01inches), and at an angle of less than 25 degrees, from the side of the head. Ear configurations, of distance and angle, that exceed the normal measures, appear prominent when the man or the woman is viewed from either the front or the back perspective. In the occurrence of prominent ears, the common causes of anatomic defect, deformity, and abnormality can occur individually or in combination; they are:
Although most prominent ears are anatomically normal, morphologic defects, deformities, and abnormalities do occur, such as the:
The degrees of angle between the head and the ear, and the degrees of angle between the scapha and the concha, determine the concept of prominent ears. The study, Comparing Cephaloauricular and Scaphaconchal Angles in Prominent Ear Patients and Control Subjects (2008) reported that the comparisons of the head-to-ear angles and the scapaha-to-concha angles of a 15-patient cohort with prominent ears, with the analogous ear angles of a 15-person control group, established that the average head-to-ear angle was 47.7 degrees for the study group, and 31.1 degrees for the control group; and that the average scapha-to-concha angle was 132.6 degrees for the study cohort, and 106.7 degrees for the control group.[15]
The antihelix normally forms a symmetric Y-shaped structure in which the gently rolled (folded) crest of the root of the antihelix continues upwards as the superior crus, and the inferior crus branches forwards, from the root, as a folded ridge. The root of the inferior crus of the antihelix sharply defines the rim of the concha. Moreover, the inferior crus also forms the wall that separates the concha from the triangular fossa. The root and superior crus of the antihelix form the anterior wall of the scaphoid fossa, and the helix forms the posterior wall. The triangular fossa dips within the Y-arms of the superior and inferior crura. The corrugated contours of these auricular crests and valleys provide a pillar effect (support) that stabilizes the auricle. The vertical walls of the conchal cup translate to a semi-horizontal plane as the concha merges with the folded crest of the antihelix. The scapha–helix is nearly parallel to the plane of the temporal surface of the head. If the roll of the antihelix and its crest are effaced and flat, rather than rolled or folded, the steep pitch of the conchal wall continues into the un-formed antihelix and scapha and ends at the helix, with little interruption. Said planar orientation places the scapha–helix complex nearly perpendicular to the temporal plane of the head — because of which the ear appears prominent, thus, such an ear also lacks the stability provided by the pillar effect, and so allows the superior auricular pole to protrude. In the literature, effacement (deficiency) of the antihelical fold is the foremost subject of most discussions of the prominent ear, because it is an aurical deformity manifested as a spectrum of defects and deformities — ranging from an indistinguishable antihelix (with a confluent concavity, from antihelix to scapha and the helical rim projected outwards and forwards) to loss of definition solely of the superior antihelix (with prominence of the upper pole of the ear).
The concha of the ear is an irregular hemispheric bowl with a defined rim. The normal scapha–helix surrounds the posterior part of the bowl (much as the brim of an inverted hat surrounds the crown). The pitch at which the scapha–helix projects from the conchal cup is determined:
If the posterior wall of the concha is excessively high, and the concha is excessively spherical, then there is an excessive angle and distance between the plane of the scapha–helix and the plane of the temporal surface of the head. Such protrusion usually is evenly distributed around the posterior conchal wall, however, the cephalad part of the concha can protrude disproportionately, another cause for a protruding upper pole. Similarly, the caudal part of the concha can project disproportionately, and cause a protruding lower auricular pole, therefore, these deformational features require special attention in the operating room.
Moreover, regarding the shape and projection of the ear, the importance of the concha must be considered in relation to the three-tiered configuration of the auricular cartilage framework, because the more delicate antihelix and helical complex are mounted upon the sturdier concha; therefore, changes in conchal size and shape greatly influence the overlying tiers, hence it is rare to see prominence of the ear that does not have a conchal element. The concha affects the prominence of the ear three-fold ways:
Understanding the first deformational element is well recognized, and, despite limited attention to the second element, once seen, it is easily understood. Therefore, understanding the third element leads to understanding the surgical-technical approach to correcting the isolated lower-pole and lobule prominence. The latter feature of conchal shape, while not the sole cause of lobular prominence, appears to play a key role. As the cartilage angle, between the concha cavum and the antitragus, becomes more acute (i.e. as the antitragus tips closer towards the concha), this supporting structure outwardly projects the lobule and the lower-third of the ear. This feature has a greater influence upon the lobule position than does the commonly described helical tail.
The combined effects of an effaced antihelix and a deep concha also contribute to severe auricular protrusion (a very prominent ear).
The occurrence of a prominent mastoid process tends to push the concha forward, which extends the auricle (external ear) away from the side of the head. The external ear is mounted upon the bony base of the underlying temporal bone, therefore, anomalies and asymmetries of the skeletal shape can cause either auricle, or both auricles, to become prominent. In relation to the protruding mastoid process, the most recognizable skeletal anomaly is the change in the position and in the projection of the auricle, as associated with non-synostotic plagiocephaly (the positional flattening of the side of the head, not caused by the inappropriate union of two bones). Hence, in the occurrence of a flattening of the skull (parallelogram deformation of the cranial vault), the side of the head afflicted with occipital plagiocephaly presents a prominent ear. In subtle cases, the prominent ear might be more readily evident in an elder patient, whose ears are asymmetrically positioned, reason for which the residual occipital flattening (occipital plagiocephaly), and mild facial asymmetry, are unapparent at first view. This effect, of the shape of the patient's head, upon the outward and extended position of the ear is notably indicated in the 1881 illustrations that describe the Ely otoplasty technique.
The undersized development of one side of a person's face, demonstrates the influence of skeletal development upon the position of the external ear on the head, as caused by the deficient morphologic development of the temporal bone, and by the medial positioning of the temporomandibular joint, the synovial joint between the temporal bone and the mandible (upper jaw). Moreover, in severe cases of hemifacial microsomia, without the occurrence of microtia (small ears), the normal external ear might appear to have been sheared off the head, because the upper half of the auricle is projecting outwards, and, at the middle point, the lower half of the auricle is canted inwards, towards the hypoplastic, underdeveloped side of the face of the patient. A similar type of asymmetric development of the head and face features a relatively broad head, a narrow face, and a narrow mandible; when observed from the front perspective, the head and face of the person present a triangular configuration. Such wide-to-narrow skeletal sloping, from the head to the face, might create the bone promontory upon which rests and from which projects the upper anatomy of the auricle, which otherwise is an external ear of normal proportions, size, and contour.
The cauda helicis (tail of the helix) is bound to the fibrofatty tissues of the earlobe by a network of connective tissue. The tail of the helix (cauda helicis), which projects outwards from the concha, carries the earlobe with it, causing it to protrude, which physical condition contributes to prominence of the lower pole of the auricle.
Given the morphological diversity of the earlobes found among men, women, and children, some earlobes are large, some earlobes are pendulous, and some earlobes are large and pendulous, but some are prominent because of the structure and form of the dense, interlacing connective tissue fibers that shape the earlobe anatomy independent of the tail of the helix (cauda helicis).
Functionally, the external ear is served by three ear muscles, the auricularis posterior muscle (rear ear-muscle), the auricularis superior muscle (upper ear-muscle), and the auricularis anterior muscle (front ear-muscle), the most notable of which is the auricularis posterior muscle, which functions to pull the ear backwards, because it is superficially attached to the ponticulus (bridge) of the conchal cartilage, and to the posterior auricular ligament (rear ligament of the ear). The posterior muscle of the ear is composed of two to three fascicles (skeletal-muscle fibers contained in perimysium connective tissue), originates from the mastoid process of the temporal bone and is inserted to the lower part of the cranial surface of the concha, where it is surrounded by fibroareolar tissue deep within the temporal fascia. The posterior auricular artery irrigates the ear tissues with small, branch-artery blood vessels (rami). Likewise, the rear muscle of the ear is innervated with fine rami of the posterior auricular nerve, which is a branch of the facial nerve. Deep within these muscle and ligament structures lie the mastoid fascia and the tendinous origin of the sternomastoid muscle.
The corrective goal of otoplasty is to set back the ears so that they appear naturally proportionate and contoured without evidence or indication of surgical correction. Therefore, when the corrected ears are viewed, they should appear normal, from the:
The severity of the ear deformity that is to be corrected determines the advantageous timing of an otoplasty; for example, in children with extremely prominent ears, 4 years old is a reasonable age. In cases of macrotia associated with prominent ears, the child's age might be 2 years. Nonetheless, it is advantageous to restrict the further growth of the deformed ear. Regardless of the patient's age, the otoplasty procedure requires that the patient be under general anaesthesia.
Generally, for reconstructing an entire ear, or a portion of the rim cartilage, the surgeon first harvests a costal cartilage graft from the patient's rib cage, which then is sculpted into an auricular framework that is emplaced under the temporal skin of the patient's head, so that the skin envelope encompass the cartilage framework, the ear prosthesis. Once placed and anchored with sutures, the surgeon then creates an auricle (outer ear) of natural proportions, contour, and appearance. In the next months, in follow-up surgeries, the surgeon then creates an earlobe, and also separates the reconstructed auricle from the side of the head (15–), in order to create a tragus, the small, rounded projection located before the external entrance to the ear canal.
In the case of the patient encumbered with several congenital defects of the ear or who has insufficient autologous cartilage to harvest, it might be unfeasible to effect the corrections with grafts of rib cartilage. In such a case, the reconstructive Antia–Buch helical advancement technique may instead be used, wherein tissue is moved from behind the ear rim and then around and forward to repair the defective front of the ear rim. To perform the Antia–Buch helical advancement, the surgeon first designs the incision inside the helical rim and around the crus (shank) of the helix with ink. The surgeon then cuts the skin and the cartilage, but does not pierce the posterior skin of the ear. The helical rim then is advanced to allow the suturing (closure), and a dog-ear-shaped graft of skin is removed from the back of the ear. The closure of the sutures advances the crus of the helix into the helical rim.
The ear defect or deformity to be corrected determines the otoplasty techniques and procedures to be applied: for example, a torn earlobe can be repaired solely with sutures; a slight damage to the rim of the auricle might be repaired with an autologous skin graft harvested from the scalp; and conversely, a proper ear reconstruction might require several surgeries. In the correction of infantile ear defects and deformities, the otoplasty usually is performed when the child is about six years old, as the healthy ear is almost adult-sized, and thus can act as a corrective template for the auricular reconstruction.
The otoplastic technique(s) applied to correct, reconstruct, or replace a deformed, defective, or a missing ear, is determined by the indications that the patient presents; some are:
Otoplastic surgery can be performed upon a patient under anesthesia — local anesthesia, local anesthesia with sedation, or general anesthesia (usual for children). In order to correct a lop ear with a small helix (the cartilage-supported outer rim of the auricle), an incision to one side of a flat cartilage piece leaves unopposed elastic forces on the opposite side, which permits the evolution of the ear contour; thus, a small incision on one side of the lop-ear cartilage, along the new anti-helical fold, can be a technical element of the corrective ear surgery. Yet, when done without an incision, the procedure is deemed an 'incisionless otoplasty', wherein the surgeon places a needle through the skin, to model the cartilage and to emplace the retention sutures that will affix the antihelix and conchal bowl areas.
Depending upon the auricular defect, deformity, or reconstruction required, the surgeon applies these three otoplastic techniques, either individually or in combination to achieve an outcome that produces an ear of natural proportions, contour, and appearance:
Repositioning the earlobe is the most difficult part of the otoplasty, because when an auricle that has been repositioned in its upper two-thirds, and that yet retains a prominent lobule (earlobe) will appear disproportionate to and malpositioned upon the head — as it did in the original, uncorrected deformity. The otoplastic technique most effective for lobular repositioning is the Gosain technique (or a variant), wherein the surgeon cuts the skin on the medial surface of the earlobe, and, in suturing it closed, takes a bite of the conchal undersurface to pull the earlobe towards the head.
Another prominent-earlobe correction technique is suturing the helical-cartilage tail to the concha, yet, because the tail of the helix does not extend much into the lobule, setting it back does not reliably correct the set back of the earlobe proper; other techniques involve skin excision and sutures, between the fibrofatty tissue of the lobule and the tissues of the neck.
Depending upon the pre-surgical degree of prominence of the upper-third of the auricle, the surgical creation of the antihelical fold might be inadequate to fully correct the position of the helical rim, near the root of the helix.
The internal sutures usually are permanent (non-absorbable), but the surgical wound or wounds can be sutured with either absorbable sutures or with non-absorbable sutures that the plastic surgeon removes when the surgical wound has healed. Depending upon the deformity to be corrected, the otoplasty can be performed either as an outpatient surgery or at hospital; while the operating room time varies between 1.5 and 5 hours.
For several days after the surgery, the otoplasty patient wears a voluminous, non-compressive dressing upon the corrected ear(s), and must avoid excessive bandage pressure upon the ear during the convalescent period, lest it cause pain and increased swelling, which might lead to the abrasion, or even to the necrosis of the ear's skin. After removing the dressing, the patient then wears a loose headband whilst sleeping for a 3–6-week period; it should be snug, not tight, because its purpose is preventing the corrected ear(s) from being pulled forward, when the sleeping patient moves whilst asleep. An overly-tight headband can abrade and erode the side surface of the ear, possibly creating an open wound. A dressing does not have to be worn if the patient was operated upon with the stitch method.[6]
Approximately 20–30 per cent of newborn children are born with deformities of the external ear (auricle) that can occur either in utero (congenitally) or in the birth canal (acquired). The possible defects and deformities include protuberant ears ("bat ears"); pointed ears ("elfin ears"); helical rim deformity, wherein the superior portion of the ear lacks curvature; cauliflower ear, which appears as if crushed; lop ear, wherein the upper portion of the auricle is folded onto itself; and others. Such deformities usually are self-correcting, but, if at 1 week of age, the child's external ear deformity has not self-corrected, then either surgical correction (otoplasty 5–6 years of age) or non-surgical correction (tissue molding) is required to achieve an ear of normal proportions, contour, and appearance.
In the early weeks of infancy, the cartilage of the infantile auricle is unusually malleable, because of the remaining maternal estrogens circulating in the organism of the child. During that biochemically privileged period, prominent ears, and related deformities, can be permanently corrected by molding the auricles (ears) to the correct shape, either by the traditional method of taping, with tape and soft dental compound (e.g. gutta-percha latex), or solely with tape; or with non-surgical tissue-molding appliances, such as custom-made, defect-specific splints designed by the physician. Therapeutically, the splint-and-adhesive-tape treatment regimen is months-long, and continues until achieving the desired outcome, or until there is no further improvement in the contour of the auricle, likewise, with the custom and commercial tissue-molding devices.
The traditional, non-surgical correction of protuberant ears is taping them to the head of the child, in order to "flatten" them into the normal configuration. The physician effects this immediate correction to take advantage of the maternal estrogen-induced malleability of the infantile ear cartilages during the first 6 weeks of their life. The taping approach can involve either adhesive tape and a splinting material, or only adhesive tape; the specific deformity determines the correction method. This non-surgical correction period is limited, because the extant maternal estrogens in the child's organism diminish within 6–8 weeks; afterwards, the ear cartilages stiffen, thus, taping the ears is effective only for correcting "bat ears" (prominent ears), and not the serious deformities that require surgical re-molding of the auricle to produce an ear of normal size, contour, and proportions. Furthermore, ear correction by splints and tape requires the regular replacement of the splints and the tape, and especial attention to the child's head for any type of skin erosion, because of the cumulative effects of the mechanical pressures of the splints proper and the adhesive of the fastener tape.
Congenital ear deformities are defined as either malformations (microtia, cryptotia) or deformations, wherein the term "ear deformation" implies a normal chondrocutaneous component with an abnormal auricular architecture. The conditions are categorized as constricted ears, Stahl's ear deformity, and prominent ears, which derive from varied causes, such as the abnormal development and functioning of the intrinsic and extrinsic ear muscles, which might generate forces that deform the auricle; and external forces consequent to malpositioning of the head during the prenatal and neonatal periods of the child's life. A study, Postpartum Splinting of Ear Deformities (2005), reported the efficacy of splinting the ears of a child during the early neonatal period as a safe and effective non-surgical treatment for correcting congenital ear deformities.[19] The study used a variety of physician-designed, physician-fabricated and commercially fabricated splints, such as a wire core segment in 6-French silastic tubing, self-adhering foam, temporary stopping with dental material, dental waxes, thermoplastic materials and other commercial ear-splint devices.
28. Merck, W.H. (2017) "Ohrmuschelkorrektur ohne Hautschnitt - die Fadenmethode von Merck". In: K.Bumm (Herausgeber): Korrektur und Rekonstruktion der Ohrmuschel. Springer, 153–169.