The role of tissue expansion in the treatment of atypical facial clefting

Tissue expansion can be a valuable tool in the reconstruction of soft-tissue defects in craniofacial clefts. To our knowledge, there have been no reports in the literature of the use of tissue expanders to help solve this problem. We report the case of a child with an atypical Tessier no. 3 craniofacial cleft who had a forehead tissue expander placed, inflated, and thus used to provide sufficient local facial skin for repair of the soft-tissue defect.     

Rare craniofacial clefts: Tessier no. 4 clefts

A major difficulty in understanding rare craniofacial clefts arises from the fact that previous reports have focused on a single case or have grouped together different types of rare clefts. Less than 50 Tessier no. 4 clefts have been reported. This paper examines our experience with eight patients treated primarily or secondarily for Tessier no. 4 clefts. A treatment plan is recommended. The primary early concern is protection of the eye. Early correction of soft-tissue deformities should include skin, muscle, and lining of the orbit, cheek, and oral cavity. Contrary to the dictum that all soft tissue must be preserved, the medial portion of the upper lip from the cleft to the philtral ridge must be resected to prevent poorly camouflaged scars, muscle deficiency, and macrostomia. Bone grafting should be undertaken at an early age using calvarial bone. Late operations will be necessary for correction of medial and lateral canthal position, epiphora, lower eyelid skin deficiency, and further bony augmentation.     

Rare facial clefts: treatment during charity missions in developing countries

During 10 charity missions in developing countries, 14 patients of a total of 374 children with cleft lip and palate deformities were treated for rare facial clefts. There were three midline clefts (Tessier no. 0 cleft, n = 1; Tessier no. 14 cleft, n = 2), four oblique facial clefts (Tessier no. 3 cleft, n = 2; Tessier no. 5 cleft, n = 2), and seven lateral facial clefts (Tessier no. 7 cleft). Surgical treatment focused on cleft repair by soft-tissue reconstruction apart from two Tessier no. 14 clefts, in which the bony gap was also closed using bone grafts from the iliac crest. The postoperative course was uneventful except for one local wound infection that was treated successfully using oral antibiotics. This article summarizes the authors' experience with the surgical management of these malformations and considers the limitations under conditions of charity missions in developing countries. Furthermore, some rare forms of cleft formation are added to the existing literature.     

Congenital nasal anomalies: a classification scheme

The purpose of this work was to develop a simple yet comprehensive classification scheme dedicated to congenital nasal anomalies. To date, no such classification system has been proposed and widely used. A 22-year retrospective review was performed. Two hundred sixty-one patients with congenital nasal anomalies were identified. From this extensive database, a systematic morphogenic classification system was devised. Congenital nasal deformities were classified into four categories. Type I, hypoplasia and atrophy, represents paucity, atrophy, or underdevelopments of skin, subcutaneous tissue, muscle, cartilage, and/or bone. Type II, hyperplasia and duplications, representing anomalies of excess tissue, ranging from duplications of parts to complete multiples, are categorized here. In the type III category, clefts, the comprehensive and widely utilized Tessier classification of craniofacial clefts is applied. Type IV deformities consist of neoplasms and vascular anomalies. Both benign and malignant neoplasms are found in this category.     

Bone graft survival in expanded skin

The effect of tissue expansion on iliac bone graft (onlay) survival was studied on the skulls of 35 New Zealand white rabbits. Wet bone weights at the time of grafting and at sacrifice in control animals (group I) were compared to three experimental groups. Histologic sections of the developing and resolving pseudosheath and skin envelope were performed. A self-inflating 5-mil-thick silicone expander was used for soft-tissue expansion over the rabbit snout. Bone grafts were subsequently placed in this site. Elliptical snout excision without expansion (group II) demonstrated no statistically significant difference in bone graft survival when compared to controls (group I) (p = 0.350). Full tissue expansion followed by immediate bone grafting (group III) within the pseudosheath cavity likewise demonstrated no statistically significant difference in bone graft survival when compared to controls (group I) (p = 0.500); however, when full tissue expansion was followed by delayed (2 weeks) bone grafting to allow for resolution of the giant cell inflammatory reaction of the pseudosheath (group IV), a statistically significant increased bone graft survival was achieved (p less than 0.001). The study demonstrates that the increased vascularity in the pseudosheath and in the expanded soft-tissue envelope significantly increased bone graft survival only when bone grafting was delayed.     

Early definitive bone and soft-tissue reconstruction of major gunshot wounds of the face

The use of craniofacial surgical techniques, extended open reduction, rigid fixation with plates and screws, and the replacement of severely damaged or missing bone with immediate bone grafting in the treatment of complex facial fractures has been applied to the management of severe gunshot wounds of the face. Early definitive bone and soft-tissue reconstruction has been performed in 37 patients. One-hundred and seventy-seven primary bone grafts were utilized in 33 patients for orbital, nasal, zygomatic, and maxillary reconstruction. Twenty-six patients required mandibular repair with compression or reconstruction plates. Soft-tissue reconstruction was provided by a combination of flaps. Four patients had extensive soft-tissue loss replaced by free vascularized omental flaps. The omentum provided circumferential coverage of the mandibular reconstruction and reconstruction of the floor of the mouth and was then tunneled in a circle through both cheeks into the middle and upper face. The omentum reconstructed deficits in the hard palate and upper buccal sulcus and was then wrapped around all zygomatic, orbital, and midfacial bone grafts and used to fill in dead space in the maxillary, ethmoid, and frontal sinuses. The omentum is not used to provide contour and bulk, but to cover bone grafts and plates and fill in dead space. Carefully shaped bone grafts provide the correct craniofacial scaffold. Early restoration of a midfacial bony scaffold and the prevention of soft-tissue contraction facilitate secondary reconstruction. Four late total nasal reconstructions with tissue-expanded forehead skin wrapped around bone grafts were performed.     

Hairline indicators of craniofacial clefts

The review of a complete series of Tessier craniofacial cleft patients presenting to the South Australian Cranio-facial Unit has identified within the hairline a regular marker of clefting. Tongue-like projections of the temporal and frontal hairline pointing in the direction of their respective clefts have been identified for Tessier clefts numbered 7 to 14. No hairline indicator was revealed in "southbound" clefts numbered 0 to 6 without "northbound" extension. The hairline markers of laterally and superiorly bound clefts are a complementary element of the Tessier classification system.     

Reconstruction using a three-dimensional orbitozygomatic skeletal model of titanium mesh plate and soft-tissue free flap transfer following total maxillectomy

The surgical strategy for maxillary reconstruction after maxillectomy has yet to be standardized. The authors developed a technique using a three-dimensional orbitozygomatic skeletal model of a titanium mesh for skeletal reconstruction after maxillectomy. From May of 1996 to September of 2000, 18 patients underwent reconstruction using the titanium mesh model in conjunction with a soft-tissue free flap following total maxillectomy for a maxillary malignancy. The soft-tissue free flap was conventional and consisted of two skin paddles to the maxillary defect. One skin paddle became the lateral nasal wall and the other was used to close the palatal defect. After modeling, the titanium mesh plate was implanted between the orbital contents and the upper edge of the free flap to lie over the front of the flap. The model was fixed to the residual zygoma laterally and to the nasal or frontal bone medially. The palatal skin paddle was anchored by three or four dermal stitches to the bottom edge of the titanium mesh to create a concave neopalate that allowed the patient to wear a denture. Thirteen of 18 patients who underwent implantation had good facial appearance and oral function. This procedure prevented lagophthalmos, facial deformity, and sagging of the palatal skin paddle caused by gravitational force. Five patients (27.8 percent) developed exposure or infection of the implant and lost the benefit of having the prosthesis. However, treatment did not require total removal of the implant. Maintaining adequate tissue volume during soft-tissue transfer on either side of the mesh plate may minimize the complication rate. Titanium mesh implantation for skeletal reconstruction after maxillectomy avoids the need for bone grafting and may be especially beneficial in fragile or aged patients.     

The role of gingival mucoperiosteal flaps in the repair of alveolar clefts

Secondary bone grafting of alveolar clefts has become a well-established procedure. However, little attention has been given to the soft-tissue coverage of these grafts. We present our experience with 32 patients in which gingival mucoperiosteal flaps were used exclusively in conjunction with bone grafting for patients with residual alveolar clefts. The indications and timing of the procedure as well as the steps of the technique are presented. The advantages of bone grafting at the stage of mixed dentition and the superiority of gingival mucoperiosteal flaps, including teeth eruption through the graft, additional teeth support, dental hygiene and aesthetic appearance of the alveolar ridge, are discussed. Our results are compared with those obtained with similar or other techniques.     

The spectrum of median craniofacial dysplasia

Given the multiple permutations in craniofacial malformations, classification of median craniofacial dysplasia or midline Tessier no. 0 to 14 clefts has been difficult and disjointed. In this review, the authors present a summary of normal embryology, prior terminology, and their proposed new classification system. Median craniofacial dysplasia has tissue agenesis and holoprosencephaly at one end (the hypoplasias), frontonasal hyperplasia and excessive tissue (the hyperplasias) at the other end, and abnormal splitting or clefting and normal tissue volume (dysraphia) occupying the middle portion of the spectrum. These three distinct subclassifications have different forms of anomalies within their groups.     

Facial skeletal expansion: treatment strategies and rationale.

Forty-three nonconsecutive patients presenting with dentofacial deformity underwent surgical procedures designed intentionally to create skeletal disproportion in the sagittal and/or vertical dimensions. This was accomplished through expansion (enlargement) of the facial skeleton beyond normative standards. At the time of follow-up, which ranged from 14 to 36 months (mean 18.4 months), soft-tissue cephalometric analyses documented facial disproportion to exist in 37 of the 43 patients treated. Thirty-two patients had excessive anterior divergence (facial protrusion) at pogonion, and 17 patients had excessive lower face height as measured from subnasale to menton. All patients were judged to have had a favorable aesthetic outcome. This philosophy of facial skeletal expansion is predicated on two concepts: The first of these is that facial proportions and dimensions beyond those which are considered normal may be extremely attractive in a given individual. Second, the soft-tissue response to skeletal expansion is more favorable and predictable than it is to skeletal contraction in providing for well-supported soft tissues. This treatment planning approach is based on the dynamic interrelationship between the skeletal foundation and the soft-tissue facial mask. It relies on physical examination as the major determinant of aesthetic surgical options.     

The role of primary bone grafting in complex craniomaxillofacial trauma

The role of craniofacial surgical techniques and immediate bone grafting in the management of complex craniofacial trauma has been reviewed. Four hundred and one patients with complex facial injuries have been treated. Two hundred and forty-one primary bone and cartilage grafts have been performed in 66 patients. Complex facial injuries should be managed by direct exposure, reduction, and fixation of all fractures utilizing interfragmentary wiring. Very comminuted or absent bone is replaced by immediate bone grafting, producing a stable skeleton without the need for external fixation devices. Associated mandibular fractures are managed with rigid internal fixation utilizing A-O technique. Results of immediate bone grafting have been excellent, and complications are rare. All deformities should be corrected, whenever possible, during the initial operation. This one-stage reconstruction of even the most complex facial injuries will prevent severe postoperative traumatic deformity and disability that may be extremely difficult or impossible to correct secondarily.     

Fgf8 haploinsufficiency results in distinct craniofacial defects in adult zebrafish

Significant progress has been made toward understanding the role of fgf8 in directing early embryonic patterning of the pharyngeal skeleton. Considerably less is known about the role this growth factor plays in the coordinated development, growth, and remodeling of the craniofacial skeleton beyond embryonic stages. To better understand the contributions of fgf8 in the formation of adult craniofacial architecture, we analyzed the skeletal anatomy of adult ace(ti282a)/fgf8 heterozygous zebrafish. Our results revealed distinct skeletal defects including facial asymmetries, aberrant craniofacial geometry, irregular patterns of cranial suturing, and ectopic bone formation. These defects are similar in presentation to several human craniofacial disorders (e.g., craniosynostosis, hemifacial microsomia), and may be related to increased levels of bone metabolism observed in ace(ti282a)/fgf8 heterozygotes. Moreover, skeletal defects observed in ace(ti282a)/fgf8 heterozygotes are consistent with expression patterns of fgf8 in the mature craniofacial skeleton. These data reveal previously unrecognized roles for fgf8 during skeletogenesis, and provide a basis for future investigations into the mechanisms that regulate craniofacial development beyond the embryo.     

Selective alteration of palpebral fissure form by lateral canthopexy

A method is described for altering the shape and position of the palpebral fissure at the lateral canthus. Three steps are essential to alter shape and position. They are (1) identification of a lateral canthal soft-tissue mass consisting of periosteum, lateral canthal ligament, and orbicularis muscle, (2) extensive subperiosteal soft-tissue mobilization of the lateral canthal soft-tissue mass (LCSTM) from a point just superior to the zygomaticofrontal suture and inferiorly along the infraorbital rim to a point corresponding with a vertical line drawn from the pupil downward, and (3) cutting of all soft tissue, including orbicularis muscle from dermis to bone and from bone to conjunctiva, from the lateral canthal soft-tissue mass medially to a point equal to a vertical line drawn from the pupil downward. After tension-free shifting laterally and superiorly has been accomplished, the lateral canthal soft-tissue mass is fixed into bone with minimal overcorrection. If there is still soft-tissue skin resistance, then overcorrection is desirable. The most difficult judgments in the procedure are the amount of superior and lateral tension to be placed on the palpebral fissure. As an aid in these judgments, the lateral-most extent of the palpebral fissure should be approximately 3 mm above the medial canthus horizontally and 3 to 4 mm medial to the medial-most portion of the lateral orbital rim. If overcorrection occurs, it can be released relatively simply.     

Tissue engineered hybrid tooth-bone constructs

Proper rehabilitation of craniofacial defects is challenging because of the complexity of the anatomy and the component tissue types. The ability to simultaneously coordinate the regeneration of multiple tissues would make reconstruction more efficient and might reduce morbidity and improve outcomes. The craniofacial complex is unique because of the presence of teeth, in addition to skin, bone, cartilage, muscle, vascular, and neural tissues since teeth naturally grow in coordination with the craniofacial skeleton, our group developed an autologous, tooth-bone hybrid model to facilitate repair of mandibular defects in the Yucatan minipig. The hybrid tooth-bone construct was prepared by combining tooth bud cell-seeded scaffolds with autologous iliac crest bone marrow derived stem cell-seeded scaffolds, which were transplanted back into surgically created mandibular defects in the same minipig. The constructs were harvested after 12 and 20 weeks of growth. The resulting bone/tooth constructs were evaluated by X-ray, ultra high-resolution volume computed tomography (VCT), histological, immunohistochemical analyses, and transmission electron microscopy (TEM). The observed formation of small tooth-like structures consisting of organized dentin, enamel, pulp, cementum, periodontal ligament, and surrounded by regenerated alveolar bone, suggests the feasibility for regeneration of teeth and associated alveolar bone, in a single procedure. This model provides an accessible method for future clinical applications in humans.     

胸三角皮瓣并自体脂肪移植修复颌面部大面积缺损畸形

目的：探讨颌面部皮肤软组织大面积缺损凹陷的理想修复方法。方法：本组6例均为爆炸伤后颌面部皮肤软组织缺损及严重凹陷畸形,采用胸三角皮肤扩张形成带蒂皮瓣修复上述皮肤缺损及自体脂肪移植纠正残存凹陷畸形。手术分五步进行：1．胸三角深筋膜浅层埋植500mL-800mL皮肤扩张器并注水扩张3个月。2井艮据面颈部预计皮肤缺损大小及形状作皮瓣预制并面部局部皮瓣纠正器官移位。3．带蒂皮瓣转移修复颌面部缺损。4．蒂部延迟及断蒂微整形。5．自体脂肪移植。结果：所有皮瓣成活良好,皮瓣色质接近面颈部周围正常皮肤,缺损畸形修复,外观形态好,供区直接缝合无需植皮,取得了较好的面部改观效果。结论：对于面部大面积皮肤软组织缺损,合并面部凹陷、面部器官缺损及移位,采取胸三角扩张延迟预制皮瓣并自体脂肪移植修复可取得良好的整复效果,为颌面部战创伤畸形提供了理想的修复方法。     

Distraction osteogenesis of the craniofacial skeleton

In summary, distraction osteogenesis is a safe and effective means of achieving bone lengthening. These techniques were originally applied to the long bones of the extremities; over the past 10 years they have been effectively applied to the bones of the craniofacial skeleton. The new bone regenerate that is observed after distraction osteogenesis is stable, and relapse rates after skeletal advancement are believed to be lower than with conventional osteotomy and bone graft techniques. There is considerable variability in distraction protocols employed in clinical practice, including differences in the types of devices used and in the rate, rhythm, latency, and period of consolidation for distraction osteogenesis. The greatest application for distraction osteogenesis in the craniofacial skeleton has been with mandible lengthening, for which there is presently a 10-year clinical experience. Midfacial advancement is a newer application of distraction osteogenesis, for which clinical experience has been accrued over the past 5 years. This latter experience indicates that distraction osteogenesis is a viable treatment option for lengthening of the hypoplastic mandible and midface. These techniques have advantages over conventional means of bone graft and rigid fixation because of the quality of the bone regenerate, the decrease in the long-term relapse rate of the advanced bone segments in both the mandible and the midface, and the simultaneous soft-tissue elongation that accompanies the distraction process. Distraction osteogenesis is particularly applicable to the correction of severe deformities of the mandible and midface in children with developmental hypoplasia and syndromic craniosynostosis. However, growth is an added variable in this patient population. The amount of overcorrection in lengthening of the hypoplastic bone required to compensate for continued growth discrepancy of the adjacent facial bones is difficult to predict. Therefore, the families of these patients should be informed that many children will require repeated operations at a later age as they reach skeletal maturity.     

Variation in soft-tissue thicknesses on the human face and their relation to craniometric dimensions

The average thickness of soft tissues on parts of the face is known, but its variation has not been related to cranial morphology. To investigate this relationship, measurements of facial soft-tissue depths and craniometric dimensions were taken on adult, white Australian cadavers (17 male and 23 female). Significant correlations between many soft-tissue depths and craniometric dimensions were found, suggesting a relationship between the amount of soft tissue present on the face and the size of the underlying bony skeleton. Soft-tissue depths were highly positively correlated with each other; craniometric dimensions were correlated but to a lesser extent. Males had thicker soft tissues and larger craniometric dimensions than females; considerable overlap of ranges was also noted. Multiple regression analysis was used to produce equations predicting the soft-tissue depth at specified areas of the face from craniometric dimensions. A subsample of nine cadavers was examined for the effects of tissue embalming. Embalming caused significant initial increases in facial soft-tissue depths. Cadavers embalmed for less than 6 months had soft-tissue depths significantly greater than for fully embalmed cadavers. The evidence that facial soft-tissue thicknesses vary with craniofacial dimensions has implications for forensic identification, facial aesthetic surgery, and approximation of the facial features of extinct individuals.