A mixed longitudinal study of 90 patients with complete BCLP from 5 to 18 years (Semb 1991b) found the maxilla in BCLP to be relatively prominent in early childhood (4° more prominent at 5 years), but it steadily receded so that by 7 years, it was similar to the value for non-cleft subjects (Broadbent et al. 1975) and by 18 years, it was 6° less (see Fig. 15.2). Throughout the period of observation, the mandible was less prominent (4° less at 5 years and 6° less at 18 years). Vertically, lower facial angulation remained higher in BCLP (2° at 5 years and 9° at 18 years). Similar findings have been reported (Heidbüchel et al. 1994; Gnoinski and Rutz 2009).

Thus, the growth pattern is different between UCLP and BCLP groups in one obvious respect. In comparison with UCLP patients, subjects with BCLP displayed greater maxillary prominence in early childhood (SNA was 5.3° larger at 5 years), but this difference reduced with time so that by 18 years, the maxilla was only slightly (1.4°) more prominent on average. In other respects, facial growth patterns were similar in both conditions, although the gonial angle was somewhat greater (3°) in BCLP throughout the period of observation.

Impairment of maxillary development continues into the late teens and early adulthood while mandibular growth continues (Enemark et al. 1990; Paulin and Thilander 1991; Semb 1991a, b; Friede and Enemark 2001; Brattström et al. 2005; Gnoinski and Rutz 2009; Myklebust et al. 2009; Friede et al. 2011; Semb et al. 2011). Thus, the anteroposterior jaw relationship worsens over time and with it the occlusion.

Since there are few publications of longitudinal follow-up beyond age 20, it is not possible to say when this growth differential ends. Enemark et al. (1990) followed 57 patients with UCLP from birth to 21 years of age. The cephalometric study showed that from 16 to 21 years, the maxillary prominence reduced by 1.1° while the mandibular prominence increased by 1.0°. The same was found in a longitudinal cephalometric study of 60 patients with UCLP from Oslo studied at 16, 18 and 21 years of age (Myklebust et al. 2009). Maxillary prominence (SNA) is reduced by 0.3° from 16 to 18 years and by 0.3° from 18 to 21 years; maxillary length (condylion to A-point) is increased by 0.6 mm from 16 to 18 years and by 0.5 mm from 18 to 21, while the mandibular length is increased by 2.3 mm from 16 to 18 years and with 1.1 mm from 18 to 21 years. A deterioration of the occlusion in the late teens/early adulthood has been reported by Lilja et al. (2006), Marcusson and Paulin (2004), and Semb et al. (2011).

It would be surprising if the catastrophic events leading to failed union of the facial processes were not associated with dysmorphology beyond the cleft site. Some indication of the extent to which the variations in facial form in UCLP and BCLP described above are intrinsic can be obtained by comparing individuals with unrepaired clefts and normal controls.

On anteroposterior cephalograms, increased width of various facial parts in unoperated infants with UCLP and BCLP has been found (Hermann et al. 2000, 2004). On lateral cephalograms, the maxilla in the UCLP group was smaller, though more protrusive at the alveolar level and at the level of the anterior nasal spine in the male subjects. The mandible was also smaller, the gonial angle was increased, the mandibular plane was steeper and the lower incisors were retroclined in the UCLP group. There was a reduced posterior height and a tendency towards increased anterior lower facial height. These differences in mandibular shape were more marked in females. The nose was less protruded, but as a result of the maxillary protrusion, there was an increase in profile convexity (Capelozza et al. 1993; Mars and Houston 1990). Differences likely to be intrinsic in nature also include abnormalities in the size and form of the cranial base (although the literature is contradictory on this point). One consistent finding is the smaller craniofacial dimensions (including size of the maxilla) found in both unoperated and operated individuals with UCLP and BCLP compared with non-cleft subjects, though this may relate to a smaller overall stature in individuals with clefts (Jensen et al. 1983).

Evidence that the prominence of the cleft maxilla is similar to that of the non-cleft is a key issue in the debate concerning surgical iatrogenesis. Therefore, it is noteworthy that the comparisons between individuals without cleft and individuals with unoperated cleft have revealed similar anterior projection of the basal maxilla on the greater segment (Capelozza et al. 1993; Mars and Houston 1990), and the same is true preoperatively for infants with complete clefts compared to infants with cleft lip and alveolus (Hermann et al. 2000, 2004).

A variety of reports including twin and fetal studies point to intrinsically reduced nasal airway volume in individuals with clefts, repaired or not. This in turn may contribute the mandibular abnormalities that are observed (Semb and Shaw 1996).

Surgery has a great impact on maxillary growth that becomes progressively apparent as patients reach maturity with reduced prominence of the maxilla at the basal (anterior nasal spine) and dentoalveolar (A point) level (Liao and Mars 2005a, b). The mandibular growth pattern is ­unaffected by the ­surgical repair of complete clefts (da Silva et al. 1992).

It is conceivable that patients with a significant deficiency of tissue are most at risk for post-operative maxillary distortion and restraint. However, the specific cause of growth disturbance remains unclear, but lip closure as well as palate closure has been implicated (Ross and Johnston 1972; Mars and Houston 1990; Normando et al. 1992).

It is possible that the iatrogenic effects of lip closure may have been underestimated. Experimental animal studies have reported that increased pressure from the repaired cleft lip is the primary cause of maxillary growth restraint (Bardach et al. 1984a). Lip pressure in infants with UCLP has been measured after lip repair and until 2 years of age and found to be significantly higher than in a non-cleft control group. Furthermore, follow-up of partially operated human subjects with complete UCLP and BCLP where only the lip has been repaired, in comparison to individuals with both lip and palate repair, points to the significant role of lip closure. Indeed, increased lip pressure probably continues to mould the anterior dentoalveolar region and reduce the SNA angle into adulthood.

Two studies have focused on this question on relatively large samples of subjects with UCLP (Mars and Houston 1990; Capelozza et al. 1996). The length of the maxilla (Ar-ANS) was reduced after lip surgery by 6.3 and 4.0 mm, respectively, in the Sri Lankan and Brazilian lip-only samples, an effect that appears to be largely due to moulding of the anterior alveolus (Liao and Mars 2005b). In the samples where lip surgery and subsequent palate surgery were performed, palatal surgery appeared responsible for only a small additional amount of retrusion, 1.0 mm in the Sri Lankan sample and 0.7 mm in the Brazilian sample. The same effect was seen in the prominence of the anterior alveolar process. Dahl (1970) also found a substantial reduction in maxillary prominence in patients with UCLP who had undergone lip surgery only. However, because individuals with complete clefts who have undergone only palatal surgery are not available, this experiment cannot be considered complete. It is by no means certain that the effect of palatal repair alone would be limited to 1 or 2 mm (i.e. whichever operation is undertaken first could have the major restraining effect).

The transverse dimension of the basal maxilla does not seem to be affected by surgery, but the dental arches are highly affected. Palatal closure often includes incisions alongside the dental arches, and the scars produced may induce an inward deflection of the dentoalveolar processes, resulting in anterior and traverse crossbites (Ross and Johnston 1972; Bergland and Sidhu 1974; Dahl et al. 1981). It is therefore likely that different surgical techniques for closing the palate give rise to malocclusions of different extent without necessarily altering the neighbouring structures.

Considerable ingenuity has been applied in the development and modification of primary surgical protocols for closing UCLP and BCLP. And if one takes the technique, timing and sequence of operations into account, the variations in practice between centres can be extreme. One survey funded by the European Union found that 201 cleft teams employed a total of 194 different protocols in the closure of UCLP (Shaw et al. 2001). The total number of primary operations to close the cleft varied from 1 to 4; a total of 17 possible sequences of operation for closing the cleft were practised; lip closure was performed at all possible points between birth and 12 months; the timing of hard palate closure ranged from birth to 13 years. Almost half the centres used presurgical orthopaedics. In fact, all of the 201 teams would have differed in their protocols had not seven of them previously agreed to participate in a randomised trial.

In general, developments of new or modified ­surgical protocols have been founded on one or other theoretical premise, and disappointment with current results. Examples of these would include assumptions concerning the underlying mechanisms of maxillary growth, the presence and location of growth centres (to be avoided during surgery) or the role of muscular function in optimising growth potential. However, present understanding of the controlling mechanisms of facial growth is incomplete and derives from observational work and speculation in earlier decades.

However, this field of research no longer seems popular with craniofacial biologists, and understanding of the mechanisms of facial growth has not advanced in recent years. Current research mostly focuses on genetic causation, on gene environment interaction and on Hox genes, growth factors and signalling molecules that influence facial embryogenesis, providing, at this stage, few options for surgical manipulation.

Examples of theories that have influenced surgical management in a quest for better maxillary growth include:

As we shall see below, however, most of these theories and assumptions have proved unreliable in actual practice, except possibly in the case of the last. The following appraisal is based upon earlier reviews (Semb and Shaw 1996, 1998), three more recent comprehensive reviews (Liao and Mars 2006; Friede 2007; Yang and Liao 2010) and reports of additional studies that set out to make explicit intra- or intercentre comparisons of different surgical protocols using cephalometry and/or indices of dental arch relationship.