-------------------------------------------------------------------------------
TITLE:   NASAL RECONSTRUCTION INCLUDING FOREHEAD FLAPS
SOURCE:  Dept. of Otolaryngology, UTMB, Grand Rounds
DATE:    March 20, 1996
RESIDENT PHYSICIAN:     John K. Yoo, MD
FACULTY:                Karen H. Calhoun, MD
SERIES EDITOR:          Francis B. Quinn, Jr., M.D.
-------------------------------------------------------------------------------

"This material was prepared by resident physicians in partial fulfillment 
of educational requirements established for the Postgraduate Training 
Program of the UTMB Department of Otolaryngology/Head and Neck Surgery 
and was not intended for clinical use in its present form.  It was 
prepared for the purpose of stimulating group discussion in a conference 
setting.  No warranties, either express or implied, are made with respect 
to its accuracy, completeness, or timeliness.  The material does not 
necessarily reflect the current or past opinions of members of the UTMB 
faculty and should not be used for purposes of diagnosis or treatment 
without consulting appropriate literature sources and informed professional 
opinion." 


Introduction

Various deformities of the nose can be brought about due to trauma, as well
as iatrogenically through the excision of skin malignancies via Mohs
microsurgery.  Just as many techniques have evolved to repair those various
deformities, but a set of general principles guides the reconstruction of the
nose with loss of soft tissue and/or underlying framework.  First, since the
defect belongs to the patient, it is incumbent on the surgeon to determine,
"What does the patient want?" Some patients desire as much as can be done in
order to obtain a normal as possible nose even if it means multiple staged
procedures with multiple hospitalizations.  Other patients desire the bare
minimum, such as leaving the defect alone and allowing the defect to heal by
secondary intention or skin grafting the wound, even if this bare minimum
will produce a suboptimal cosmetic result.  Next, the defect must be analyzed
in terms of which tissues are missing, since nasal tissue must be replaced by
like tissue in order to effect the best cosmesis.  

The nose is by and large made up of three layers: the thin, vascular nasal
mucosa, the nasal framework consisting of cartilage or bone, and the
overlying skin and soft tissues of the nose.  Reconstructive techniques must
also take into account the varying thickness of nasal skin depending on the
location.  The skin of the upper two thirds of the nose is thin, mobile, and
has fewer sebaceous glands, whereas the skin over the lower one third is
thicker, filled with sebaceous glands, and lacks mobility.  In addition to
replacing the missing tissues, however, the nasal contours, highlights, and
shadows must also be restored.  In order to do this, the nose must be
analyzed with regards to the topographic nasal subunits.  The nose is divided
into 9 subunits: dorsum, 2 nasal side walls, tip, 2 ala, 2 soft tissue
triangles, and the columella.  Of these, 5 of them are convex (dorsum,
columella, tip, and 2 nasal ala) and 4 are concave (2 sidewalls and 2 soft
tissue triangles).  In order to maintain these concavities and convexities,
it is usually best to repair the nasal defect with a different flap or graft
technique for each subunit.  If a defect involves more than 1/2 of a nasal
subunit, the rest of that subunit is excised to achieve better cosmesis.

Incisions should be placed along the midline, at the subunit boundaries, and
along the lines of minimal tension (vertical in glabella and horizontal over
the rest of the nose) to maximize scar camouflage.  The patient should be
questioned regarding any intercurrent illnesses as well as previous
surgeries.  Especially important is whether the patient has a smoking history
or any peripheral vascular disease which may compromise the cutaneous
vascular supply of the flaps used for reconstruction.

Anatomy

The framework and underlying support of the nose is provided by the nasal
bones, upper and lower lateral cartilages, and indirectly by the septum.  The
blood supply of the nose is provided by the alar and septal branches of the
facial artery to the ala and lower septum, respectively.  The dorso-lateral
areas are nourished by the dorsal nasal branch of the ophthalmic artery and
the infraorbital branch of the maxillary artery.  The superior labial and
angular branches of the facial artery supply the lower and upper nose.  The
anterior facial and ophthalmic veins provide the venous drainage of the nose.
The lymphatics of the anterior nose drain into the submandibular nodes and
the rest of the nose drains into the parotid and upper deep cervical lymph
nodes.

Techniques for Repair (by subunit)

The actual reconstruction for each patient's nasal defect must be
individualized and tailored to optimize cosmesis, but at all times following
the general guidelines as outlined above.  However, a systematic guide to the
the repair of nasal defects has been published by Larrabee and Sherris and
addresses each subunit separately as per the topographic subunit principle.
	
1. DORSAL SUBUNIT

For superficial defects less than 2.0 cm in size that are vertical or round,
the defect can be repaired by primary closure, single transposition flap, or
a bilobed flap.  For superficial defects less than 2.0 cm that are
horizontal, the defect can be repaired by primary closure or a glabellar
flap.  For defects that are greater than 2.0 cm or are deep, a forehead flap
should be used for reconstruction.

2. SIDEWALL SUBUNIT

For defects in the medial canthal area that are less than 1.0 cm, primary
closure, FTSG, secondary intention, or a glabellar flap can be used.  For
medial canthal area defects greater than 1.0 cm, secondary intention or a
glabellar flap can be used.  In other areas of the sidewall, a modified
bilobed flap is used for defects less than 2.0 cm, a superiorly based
melolabial flap for defects greater than 2.0 cm, and a forehead flap for
defects that are greater than 2.0 cm and/or are deep.

3. TIP SUBUNIT

For superficial defects less than 1.5 cm, primary closure, delayed FTSG, or
bilobed flap can be used.  For superficial defects 1.5-2.5 cm in size can be
repaired with a two stage melolabial flap.  If the defect is superficial, but
greater than 2.0 cm or if the defect is deep involving underlying cartilage
or nasal lining, then a forehead flap should be used.

4. SOFT TISSUE TRIANGLES

The defect of the soft tissue triangles should be allowed to granulate to
avoid unsightly notching.

5. COLUMELLA SUBUNIT

Skin only defects of the columella can be repaired by secondary intention or
be FTSG.  For defects involving both skin and cartilage, a composite graft of
lobule and cartilage can be used if the vascular supply is good, and a two
stage melolabial flap if the vascular supply is compromised.

6. ALAR SUBUNIT

For superficial defects less than 1.0 cm in size, FTSG can be used (secondary
intention may cause excessive alar retraction).  For superficial 1.0-2.0 cm
defects, a bilobed flap, two stage melolabial flap, or a nasofacial groove
flap can be used.  For full thickness alar defects less than 1.5 cm, a
composite graft of skin and cartilage can be used to reconstruct.  For full
thickness alar defects greater than 1.5 cm, reconstuction can be performed
using the melolabial flap or a forehead flap.
		  
Full thickness skin graft skin grafts (FTSG) work well for defects involving 
thin nasal skin or those subunits that are concave.  These areas include the
columella, sidewalls, dorsum, and soft triangles.  FTSG's blend in well in
defects of the upper 2/3 of the nose.  They can be harvested anywhere, but
the best donor site for the reconstruction of the superficial defects is
preauricular skin where 2.0 to 2.5 cm grafts can be taken.  The underlying
recipient area must be well vascularized and quilting sutures must be placed
to avoid sheering.

Bilobed flap

The Zitelli modification of the bilobed flap is a useful tool for the
reconstruction of nasal defects, particularly if the defect is between
0.5-1.5 cm in diameter in the thick-skinned part of the nose.  The
modification allows for only 45-50 degrees of rotation for each lobe of the
flap (rather than the original 90) for a total arc of rotation of 90-100
degrees (rather than the original 180).  The smaller arc of rotation poses a
lesser problem with a standing cone defect.  A triangle of skin equal in
length to one radius of the defect is excised to the pivot point.  The second
lobe of the flap should be brought from the loose skin of the upper 2/3 of
the nose.  As per Dr. Burget, the bilobed flap should be based laterally for
defects of the tip, and medially based for the defects of the ala.
	
Glabellar/Finger flap

A rotational flap utilizing the lax skin of the glabella can be used to fill
in defects of the upper 1/3 of the nose.  A midline transposition flap
(finger flap) can also repair defects of the upper 1/3 of the nose, but can
also address defects if the medial canthal area as well.  A standing cone in
the inferior rotational area can be trimmed without compromising the blood
supply.  In both flaps, the donor site is closed primarily without dificulty.


Melolabial flap

The superiorly based melolabial flap can be used to repair defects greater
than 1.5 cm on the ala.  This flap is nourished by the branches of the facial
and angular arteries that perforate the levator labii muscle near the ala and

then extend laterally.  Because of this hearty blood supply, the proximal
pedicle need not be wide.  The flap is elevated in a plane superficial to the
facial musculature and can be thinned prior to insetting.  This flap can be
rolled onto itself (with a cartilage graft placed at the most inferior end to
prevent alar retraction) to provide inner nasal lining if none are available.
The donor site can be closed along the melolabial crease.  At 3 weeks
post-operatively, the pedicle can be divided, trimmed, and thinned to close
the remnant donor site and the lateral flap bed.

An inferiorly based variation of the this flap can be used to repair small
defects of the ala and can be useful because of its use of the nose/cheek
boundaries.

Paramedian Forehead Flap

The forehead is a source for abundant donor tissue available for large and/or
deep nasal defects.  The paramedian forehead flap has a hearty blood supply
in a vertical orientation provided primarily by the supratrochlear vessels
and to a lesser extent, the supraorbital and dorsal/angular branches of the
facial artery.  The supratrochlear artery exits the orbital septum and
crosses the orbital rim deep to the orbicularis oculi and superficial to the
corrugator muscles.  The supratrochlear vessels travel 2 cm lateral to the
midline and superficial to the frontalis muscle.

The precise location of the supratrochlear artery is identified with a pencil
Doppler, so that the base of the flap can be narrowed to approximately
1.0-1.5 cm.  A base that is too wide can strangulate the flap as it twists to
reach the recipient bed or limit the length of the flap.

The shape of the distal flap is planned with the use of a foil template taken
of the contralateral uninvolved side (*remember to flip the template over for
the mirror image of the defect*).  A suture or gauze measured from the pivot
point to the most distal portion of the nasal defect is used to determine if
the flap is going to be long enough.

The flap is elevated in a subgaleal plane and just above the periosteum
inferiorly to avoid injurying the vascular pedicle.

Prior to insetting the flap, the nasal lining and the underlying framework
are reconstructed, and any remaining portions of the subunit(s) are excised.
To match the thickness of the defect, the distal end of the flap may be
thinned before suturing into place.  However, thinning of the distal flap
should be avoided at the primary repair in a smoker due to compromised blood
supply.  The length of the flap can be increased by 1.5 cm by extending the
flap into the scalp or across the orbital rim.  Regrowth of hair can be
prevented by clipping the bulbs of each hair follicle if extended into the
scalp.

If the defect to be reconstructed also involves the nasal lining, the
forehead flap can be harvested with the underlying pericranium 2 cm beyond
the confines of the distal flap attached to the forehead flap, in a flap
designed by Seikaly.  Once the flap and its pericranium is elevated, the
pericranium can be separated from the overlying skin and sutured into place
to replace the nasal lining.  Next, the cartilaginous framework can be
inserted inset superficial to the pericranial flap, followed by the placement
of the skin of the forehead flap.

The donor site can usually be closed primarily after undermining the
surrounding skin, but healing by secondary intention or STSG can be used if
closure is not possible.

The forehead flap pedicle can be divided 3 weeks post- operatively under
local anesthesia.  The proximal portion of the flap is trimmed/thinned and
used to fill in the V-shaped donor defect and trimming/thinning of the distal
flap/nasal dorsum is performed to obtain maximal cosmesis of the distal
portion.

Nasal lining

Nasal defects involving all three layers require that the deepest layer
(nasal mucosa/vestibular skin) be reconstructed.  Since this tissue is thin,
soft, and vascular, the optimal donor tissue should be similar in character.
The nasal lining can be provided by skin grafts, local turn-in flaps, or
nasolabial flaps, but the best donor tissue is uni-pedicled or bi-pedicled
intranasal tissues such as from the vestibule, middle vault, or the septum.
In small full thickness defects of the alar margin, the lining can be
replaced by freeing the vestibular skin from its attachment superiorly and
rolling it inferiorly and outward like the hem of a skirt until it lines the
margin.  In addition, if a paramedian forehead flap is used to reconstruct a
defect and nasal lining is required, pericranium associated with the distal
flap can be used to replace the nasal lining.  
	
Framework

When the nasal defect involves the underlying bone and cartilage framework,
like tissues must be used to replace them.  Bone may be obtained from the
cranial, iliac, or costal bone.  Cartilage from the septum, conchal, or
costal areas may be obtained to recreate the cartilaginous nasal framework.
Because of the close proximity to the surgical field, the conchal and septal
cartilages are more widely used.  The conchal cartilage has the advantage of
having inherent curves that more closely mimic the shape of the alar
cartilages.  The septal cartilage has to be weakened at certain points in
order to bend, but is more easily carved due to its hyaline nature.  

Conchal cartilage is harvested by making an incision medial to the rim of the
conchal bowl, elevating the overlying mucoperichondrium, excising the conchal
cartilage, repairing the incision, and placing a bolster on both sides of the
conchal bowl.

Burget recommends even placing cartilage grafts in those parts of the nose
that normally contain no cartilage (such as the alar lobule) in order to
impart stability to the overlying soft tissue reconstructions.
--------------------------------------------------------------------------
BIBLIOGRAPHY

Burget, GC and Menick, FJ.  Aesthetic reconstruction of the nose.  Mosby-Year
Book: St.Louis, MO. 1994.

Larrabee, WF and Sherris DA.  Principles of facial reconstruction.
Lippincott-Raven publishers: Philadelphia, PA.  1995. 

Jackson, IT.  Local flaps in head and neck reconstruction.  C.V. Mosby Co.:
St.Louis, MO.  1985.

Burget, GC.  Nasal restoration with flaps and grafts in: Head and neck
surgery-Otolaryngology edited by Byron J.  Bailey.  J.B.Lippincott Co.:
Philadelphia, PA.  1993.

Stucker, FJ and Shaw GY.  Reconstructive rhinoplasty in: Otolaryngology-Head
and neck surgery edited by Charles Cummings.  Mosby-Year Book: St.Louis, MO.
1993.
--------------------------------END----------------------------------------


Nasal Reconstruction Including Forehead Flaps

John K. Yoo, MD
Karen H. Calhoun, MD

3-20-96