Bilateral orbital advancement

The standard treatment is bilateral supraorbital bar advancement and reshaping within the first year of life.

For this procedure the coronal approach is used.

After the exposure of the forehead and the orbits via a coronal approach, a bifrontal craniotomy beginning 1 cm superior to the superior orbital rim and extending to behind the coronal sutures is outlined.

Burr holes are first placed at the vertex, avoiding the sagittal sinus, and nasal frontal region as well as temporally. An epidural dissection between these points is made.

The neurosurgeon then completes the osteotomies using a craniotome.

After the bone flap is removed, the dura is freed from the anterior and middle fossae in the epidural plane.

The dura is protected with neurosurgical cottonoids.

Malleable retractors are used intracranially to retract and protect the dura and intraorbitally to protect the orbital contents when performing the osteotomies.

The supraorbital bar is then osteotomized.

A vertical osteotomy near the pterion (1) is followed by a horizontal osteotomy to the lateral orbital rim (2). An oblique osteotomy is then made through the orbital rim (3) and a transverse osteotomy is completed at the nasal frontal junction (4).

Alternatively, a tongue-in-groove a) or a step osteotomy b) can be used in the temporal region as shown.

With the brain carefully retracted, a right angle saw is then turned intracranially and the orbital roof is osteotomized beginning at pterion laterally and ending at the nasal frontal osteotomy medially, joining the osteotomy made extra cranially across the nasal frontal region.

An osteotome is then inserted at the pterion and the lateral orbital wall osteotomy completed on both sides, releasing the supraorbital bar.

The supraorbital bar is then advanced 10-15 mm.

In infants a maximal advancement is usually chosen.

In adults who have finished craniofacial growth, advancement is done so that the superior orbital rim is approximately 12 mm anterior to the cornea.

The advanced bar is then stabilized. A wire or suture is placed between the stable lateral orbital rim and the supraorbital bar.

Pearl: To improve the stability of the advanced segment, a cranial bone graft may also be wedged and placed in the orbital roof between the stable posterior segment and the advanced anterior segment.

Bone graft harvested from the frontal bone flap is then inserted in the temporal gap and held in position with a resorbable plate (infants and children) or metallic plate (adults).

If metallic or resorbable plate fixation is unavailable, self-retaining osteotomies may be designed and utilized in conjunction with wire or suture fixation.

The frontal bone flap is then replaced in the desired position.

If the frontal bone flap is irregular, it can be
rotated, bent and/or reshaped to get the best possible fit and contour before replacement using:

• A bone bending forceps (children).
• Partial osteotomies and plate fixation (adults).

The bone flap is then affixed to the supraorbital bar with resorbable plates or resorbable sutures (infants), or titanium plates (adults).

The coronal bone gap created from the advancement and harvesting of bone is then filled with particulate bone shavings harvested with a manual hand-held burr-hole instrument or commercial harvester (eg, Safe scraper) from the frontal bone flap or the posterior skull.

This picture demonstrates the large volume of particulate bone that can be harvested from the inner surface of a bone flap using a hand-held burr-hole instrument.

Most surgeons favors placement of a bulb suction drain under the scalp for 3-5 days. Resorbable skin sutures are often used.

A circumferential head dressing is utilized for 48 hours. The neurosurgeon may request placement of a lumbar drain if significant dural tears have occurred during surgery. Patients should spend at least 1-2 days in an intensive care unit for neurological monitoring.

Keeping the patient’s head in an upright position postoperatively may significantly improve periorbital edema and pain. Some surgeons use injectable corticosteroids during surgery to reduce periorbital swelling.

To prevent orbital emphysema, nose-blowing should be avoided for at least 10 days.

The following perioperative medications are controversial. There is little evidence to make strong recommendations for postoperative care.

• Avoidance of aspirin or nonsteroidal antiinflammatory drugs (NSAIDs) for 7 days.
• Analgesia as necessary.
• Antibiotics (many surgeons use perioperative antibiotics. There is no clear advantage of any one antibiotic, and the recommended duration of treatment is debatable.).
• Nasal decongestant may be helpful for symptomatic improvement in some patients.
• Steroids may help with postoperative edema. Some surgeons have noted increased complications with perioperative steroids.
• Ophthalmic ointment should follow local and approved hospital protocol. This is not generally required in case of periorbital edema. Some surgeons prefer it. Some ointments have been found to cause significant conjunctival irritation.
• Regular perioral and oral wound care has to include disinfectant mouth rinse, lip care if intraoral incision has been used.

Postoperative examination by an ophthalmologist may be requested, although sever periorbital edema may prevent useful assessment. The following signs and symptoms are usually evaluated:

• Vision
• Extraocular motion
• Diplopia
• Globe position
• Lid position

Postoperative imaging has to be performed within the first days after surgery to verify accuracy of surgery. 3-D imaging (CT, cone beam) is recommended.

Remove sutures from skin after approximately 7-10 days if nonresorbable sutures have been used.
Apply ice packs for the first 12 postoperative hours as able although infants and young children do not tolerate this well (may be effective in a short term to minimize edema).
Avoid sun exposure and tanning to skin incisions for several months.

Soft diet can be taken as tolerated until there has been adequate healing of any maxillary vestibular incision. In children and infants age appropriate diets are then prescribed.
Patients in MMF will remain on a liquid diet until such time the MMF is released.

Clinical follow-up depends on the complexity of the surgery, and whether the patient has any postoperative problems. Most patients are discharged at postoperative day 3-5 and seen again in 2-3 weeks.

• In patients undergoing monoblock or Le Fort III distraction, distraction typically begins at day five at 1 mm/day and is assessed weekly with plane radiographs and clinical examination until the desired position is reached. After advancement a period of consolidation of 1-3 months is recommended before the retractors are removed.
• In patients undergoing conventional advancement with intermaxillary fixation, MMF is kept in place for 4-6 weeks. Routine oral hygiene is prescribed. Patients with arch bars and/or intraoral incisions and/or wounds must be instructed in appropriate oral hygiene procedures. The presence of the arch bars or elastics makes this a more difficult procedure. A soft toothbrush (dipped in warm water to make it softer) should be used to clean the surfaces of the teeth and arch bars. Elastics are removed for oral hygiene procedures. Chlorhexidine oral rinses should be prescribed and used at least 3 times a day to help sanitize the mouth.
  For larger debris, a 1:1 mixture of hydrogen peroxide/chlorhexidine can be used. The bubbling action of the hydrogen peroxide helps remove debris. A Waterpik® is a very useful tool to help remove debris from the wires. If a Waterpik is used, care should be taken not to direct the jet stream directly over intraoral incisions as this may lead to wound dehiscence.

The patient needs to be examined and reassessed regularly and often. Additionally, ophthalmological, ENT, and neurological/neurosurgical examination may be necessary. If any clinical signs for meningitis or mental disturbances develop, professional help has to be sought. Due to the young age of many patients, routing CT-scans are performed only if clinically indicated to avoid excessive radiation exposure.