Keywords
nasal reconstruction - total nasal defect - forehead flap - full-thickness nasal defects
The nose is a central aesthetic feature of the face and key in establishing self and
familial identity. Studies using eye-tracking technology show that observers track
the human face in a stereotypical pattern focusing on the central facial triangle.[1] This characteristic visual scan path is distorted by distracting abnormalities of
the central face such as nasal defects. Consequently, patients with central facial
defects can have challenging social interactions because of distracted eye to eye
contact. The principal goal of nasal reconstruction is to restore a functional nose
that is aesthetically normal. Experience with nasal reconstruction has evolved over
several centuries with each century adding a level of sophistication. Despite the
accumulated experience, reconstructing a three-dimensional (3D) multilayer nasal defect,
particularly those involving tip and ala with consistently normal aesthetics and functional
outcomes remains a challenge. For the purposes of focused analysis, we define complex
nasal defects as those involving all layers of the nose. Over the past three decades,
there have been significant advances toward reliably reconstructing complex nasal
defects. These advances have resulted from experience accumulated from critical analysis
of poor outcomes and modification of techniques to address misjudgments and complications.
This article reviews principles, concepts, and evolving advances for reconstructing
full-thickness nasal defects from subunits defects to extended total nasal defects.
Clinical Presentations
The nose is the most common site for nonmelanoma skin cancer due to its prominent
location and vulnerable exposure to ultraviolent rays.[2] Fortunately, most nasal lesions are discovered early and their timely excision results
in small and often superficial defects that can be reconstructed with minimal impact
on function and aesthetics. Resection of advanced and more aggressive neoplasms results
in larger and complex multilayered defects that may extend beyond the boundaries of
the nose and are challenging to reconstruct. In such cases, it is essential to ensure
complete disease clearance prior to initiating the reconstructive process. This may
require delaying the reconstruction until permanent pathologic reports are available
and excising additional margins if necessary. A temporary application of adhesive-retained
prosthetic noses should be considered when a long waiting period is contemplated.
The long-term use of implant-anchored prosthesis is also an alternative.
Complex nasal defects in children present a particular challenge beyond the technical
aspects of reconstruction. Common causes of complex nasal defects in children include
vascular malformations and dog bites. Congenital capillary hemangioma extensively
involving the nasal tip, even after regression, leaves a deformed fibrous nose that
often requires reconstruction. Dog bite injuries in children commonly involve complete
avulsion of the nasal tip. The timing for reconstructing a nose in a child, the selection
of less involved temporizing measures with skin grafts and local flap versus embarking
on full scale complex reconstruction with forehead flaps are forefront in deliberations
around the management of such defects. Burget detailed his experience over several
years on the feasibility, outcomes, and long-term follow-up in 29 children who underwent
complex nasal reconstruction using forehead flaps.[3] In that series complex reconstruction began as early as 3.5 years and the reconstructed
noses grew into adult-sized noses, although additional delayed cartilage grafting
was necessary in some patients.
Principles and Concepts of Complex Nasal Reconstruction
Principles and Concepts of Complex Nasal Reconstruction
It is broadly established that complex nasal defects involving the nasal skin envelope,
supportive substructure, and nasal lining require replacement and reconstruction of
all three layers without compromise. The donor skin should provide excellent color
and texture match and should reflect the contours of a normal nose. The supportive
substructure should be stable from displacement, maintain nasal patency, and withstand
secondary contraction from inevitable scarring. The nasal lining should be thin to
maintain nasal patency and well vascularized to support overlying grafts. Beyond these
foundational principles, several concepts that can guide complex nasal reconstruction
have evolved.
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Defects involving large portions of subunits, particularly the convex contours of
the nasal tip, are best resurfaced as a whole unit.
-
It is advantageous to delay cartilage grafting till a well-vascularized lining has
been established.
-
More nasal lining than imagined is often necessary to maintain nasal patency.
-
Skin grafts supported by vascularized forehead flaps are reliable sources of nasal
lining.
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The donor tissues, sequence of surgeries, and the timing should permit intraoperative
modification, opportunities to revise imperfections, or salvage complications. A three
to four-stage procedure is often necessary for complex nasal defects.
-
There is benefit in delaying division of the forehead flap pedicle until all intermediate
steps including soft tissue partition, thickness modification, and 3D contouring have
been satisfactorily completed.
-
Small salvage steps often yield small unsatisfactory results. A revision case may
require starting all over.
Defect Analysis and Planning
Defect Analysis and Planning
Successful reconstruction of a complex nasal defect starts with a thorough assessment
of the defect to establish the layers involved and extent of tissue missing. An organized
and systematic approach is necessary to streamline the analysis, planning, and reconstruction
to achieve optimal results with consistency. The entire nose, both external and internal,
should be carefully examined. The quality, vascularity, and mobility of surrounding
skin and supporting structures should be evaluated to establish where donor tissue
could be recruited from without distorting adjacent structures. Based on the extent
of tissue involved, full-thickness nasal defects can be subclassified as ([Fig. 1]):
Fig. 1 Subclassification of complex nasal defects. (A) Complex subunit defect. (B) Complex subtotal defect. (C) Total nasal defect. (D) Extended total nasal defect.
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A. Complex subunit defect involves all layers of one subunit.
-
B. Complex subtotal defect involves more than one subunit; caudal septum is present.
-
C. Total nasal defect involves multiple subunits and caudal septum with or without
nasal bone involvement.
-
D. Extended total nasal defect; total nasal defects as above with involvement of cheek
or lip.
Defining the presented defect, after resection of scar tissue and expansion of the
defect into subunits allows a tailored approach into solving the puzzle. An inside-out
approach beginning with evaluation for lining, followed by structural needs and then
external soft tissue coverage, forces the surgeon to avoid focusing only on the obvious
surface tissue loss.
Reconstructing the Nasal Lining
Reconstructing the Nasal Lining
The nasal lining is the least visible portion of a complex nasal defect but perhaps
the most important aspect of the reconstruction. The nasal cavity is lined with squamous
epithelium and respiratory epithelium that filters and conditions inspired air. The
vibrissae filter large particles, while the moist mucosal lining traps smaller particles
and provides humidification. A well-vascularized nasal lining is critical for successful
complex nasal reconstruction. Suboptimal lining with gaps leads to graft exposure,
infections, undesirable contractions, and ultimately reconstruction failure. An adequately
vascularized lining is necessary to support structural grafts. The ideal lining should
be thin to allow airway patency. In addition, maintaining maximal humidification and
filtration of inspired air is desirable to minimize intranasal crusting of the reconstructed
nose. Options for reconstructing lining defects include grafts, local flaps, regional
flaps, and microvascular tissue transfer.
Free grafts have limited role in the reconstruction of full-thickness nasal defects
unless a vascularized supportive bed can be provided. A commonly used free graft is
the composite skin-auricular cartilage graft. These are useful for small defects isolated
to the alar subunit. Small windows can be made through the cartilage to allow vascularization
of the adherent skin.[4] The main advantages of the composite auricular skin cartilage graft are their favorable
contour and the simultaneous introduction of thin lining skin adherent to a supporting
cartilage. These grafts should be avoided in children as they rarely provide adequate
support and growth over time.
Hinged turn-in skin flaps recruited from subunits adjacent to the defect to be repair
are also alternative sources of lining.[5] While these may be partially vascularized, their distal end should be considered
as free grafts requiring a good vascularized bed for reliable survival. Hinged turn-in
skin flaps are rarely adequate sources of lining and are often combined with additional
sources of lining. While it is tempting to stretch these turn-in flaps, this leads
to tenting and secondary contraction. Turn-in flaps that may have appeared to be acceptable
lining initially contracts over time and becomes inadequate coverage to maintain a
patent intranasal vault. Another source of skin for nasal lining is the distal tip
of a forehead flap as described by Menick.[6] The designed lining is incorporated as an extension of the distal edge of the forehead
flap to draped internally beyond the alar and nostril margin. Once the folded skin
has integrated into the adjacent normal lining, it can be completely separated from
the overlying cover from which it was initially vascularized. The folded forehead
flap is incised free along the rim, completely separating the proximal cover flap
from the distal lining extension. Supporting and contouring cartilage grafts can then
be placed.
Another source of intranasal lining is nasal mucosa. Various mucosal flaps have been
described for small and intermediate sized defects. These include turbinate mucosal
flaps, bipedicled vestibular flap, ipsilateral and contralateral septal flaps.[7]
[8] Intranasal mucosa is an attractive source of lining because it replaces like tissue,
it is adjacent to the nasal defect, and has the potential of providing a moist and
humidified reconstructed nose. There is, however, a finite amount of nasal mucosa
limiting their use when defects are large. When available, one versatile way to recruit
septal mucosa for inner lining is the transposition of the septum as a composite bilateral
mucosal–cartilage flap (septal pivot flap) pedicled on the septal branch of the superior
labial artery. The septal pivot flap was described by Burget and Menick in 1989[9] and its application in complex nasal reconstruction was also detailed by Quetz.[10]
[11] The septal branch of the superior labial artery is likely preserved if the nasal
defect is limited to the upper half of the caudal septum and the central upper lip
is uninvolved. The pair of septal branches of the superior labial artery allows almost
the entire septum to be elevated as a bimucosal cartilage composite flap after a superior,
posterior, and inferior septal release. At least a 12-mm wide intact mucosal bridge
should be preserved inferiorly as a pedicle. With the composite flap transposed, the
cartilage provides caudal septal replacement and support for the nasal tip and the
mucosa can be elevated bilaterally to line the nasal tip and vestibule.
Laminated versus Prelaminated Forehead Flap
Laminated versus Prelaminated Forehead Flap
An extension of the use of hinged skin flaps and small skin grafts sutured to mucosal
flaps is the use of skin graft to replace all the needed lining. The primary attraction
for this approach is the unlimited supply of skin graft. The skin graft requires a
vascularized bed, which is provided by a full-thickness forehead flap. The forehead
flap is elevated with all the layers above the periosteum. For this approach to be
successful, the skin graft needs to be immobilized to the undersurface of the forehead
flap till the skin becomes fully vascularized. In the prelaminated approach, a split-thickness
skin graft (STSG) is harvested and sutured to the undersurface of the elevated forehead
flap.[12] The graft is sutured to the edge of the forehead flap as well as with central tucking
sutures ([Fig. 2]). The STSG is oversized forming some rugae; these smooth out with contraction. The
forehead flap with the STSG is replaced and sutured back on the forehead. The frontal
bone acts as a compressive bolster and thus an external bolster is not necessary.
Potential complication with this approach is seroma formation, which is treated with
needle decompression. In cases where postoperative radiation is anticipated, the forehead
flap is elevated at the time of primary tumor resection and prelaminated. We have
left the prelaminated forehead flap in place as long as 6 months to allow completion
of radiation. The forehead flap is usually out of the radiation field. This approach
saves the patient one operation, allows contraction of the forehead flap to occur
and stabilize prior to flap transfer, and yields a well-vascularized lining.
Fig. 2 Prelaminated forehead flap. (A) Split-thickness skin graft is sutured to the undersurface of a forehead flap elevated
in a plane above the periosteum. The skin graft is made slightly loose with some rugae
that smooths out with secondary contraction. (B) The composite flap is elevated after a minimum or 3 to 4 weeks and transposed to
the nasal defect. At an intermediary stage, the forehead skin is elevated in a subcutaneous
plane leaving the skin graft, galea and frontalis muscle as the new vascularized lining.
Alternatively, STSG may be applied in a laminated approach. With the laminated approach,
the STSG is sutured to the edges of the nasal defect accounting for the anticipated
nasal projection ([Fig. 3]). The forehead flap is then elevated and transposed to provide external coverage
of the nasal defect. An intranasal bolster is necessary to support and immobilize
the STSG against the undersurface of the full-thickness forehead flap. Options for
intranasal bolster include cotton packed to support the STSG and to act as an absorbent
or packed petroleum gauze. We have also found a modified inflated low-pressure endotracheal
tube very effective. The cuff conforms to the intranasal space and is easily deflated
and reinflated to inspect the STSG.
Fig. 3 Laminated forehead flap. Split-thickness skin graft is sutured to the edges of the
nasal defect and supported by a bolster packing. The forehead flap is then harvested
above the plane of the periosteum and transposed over the skin graft lining. The forehead
skin can be elevated 3 to 4 weeks later in a subcutaneous plan leaving the skin graft,
galea and frontalis muscle as the new vascularized lining.
With either the prelaminated or laminated approach, an intermediate stage is performed
to split the forehead flap elevating the entire flap in a subcutaneous plane. The
nasal lining consisting of the STSG, galea, and some frontalis muscle is now vascularized
from surrounding vessels as well as the forehead pedicle. The pedicle is kept intact,
the lining is modified as needed, and cartilage grafts are placed ([Fig. 4]). The use of prelaminated and laminated forehead flap has altered our approach to
complex nasal reconstruction. We now consider this our primary approach for providing
nasal lining leaving native nasal mucosa in place to maximize their humidifying function.
With either the prelaminated or laminated approach, secondary contraction in the transposed
flap should be anticipated and accounted for in the design of the flap and lining
by slightly over-sizing. We harvest the STSG from the chest wall in line with the
incision for future rib cartilage graft harvest and consequently avoiding a second
donor site scar.
Fig. 4 Separating the lining: 3 to 4 weeks following a insertion of the composite forehead
flap with skin graft lining, a robust vascularized lining made of the skin graft,
galea and frontalis muscle results. The new lining is vascularized from the surrounding
tissues and from the intact forehead flap pedicle. It can be thinned as needed.
The free transfer of tissue can provide an abundant tissue for lining and should be
considered as primary source in selected cases. We consider these procedures low morbidity
procedures when performed by experienced surgeons and not an option of last resort.
Microvascular flaps are particularly useful in extended total nasal defects where
the foundation of the nose at the maxillary and premaxillary buttresses is involved.
In addition, involvement of the upper lip and extensive segment of the medial cheek
soft tissue necessitates the transfer of distal skin best achieved with free flaps.
The anterolateral thigh (ALT) and radial forearm free flaps are the two most common
free-flap options for reconstructing internal lining defects. The ALT flap is commonly
harvested as a fascia flap and provides thin vascularized tissue to reconstruct the
entire nasal lining and adjacent structures with minimal donor site morbidity. The
ALT fascia becomes secondarily mucosalized.[13]
[14] The radial forearm free flap also provides enough tissue for reconstructing the
lining in total nasal defects. The radial forearm free flap can be harvested with
skin or as a fascial flap with secondary mucosalization.[15]
External Coverage
The nasal skin varies in thickness and texture when one transitions from the upper
to lower thirds of the nose. Together with the underlying layer of subcutaneous fat
and superficial musculo-aponeurotic system, the nasal skin reflects the contours of
the underlying cartilage and bony substructure. The soft tissue envelope has been
divided into topographic subunits that reflect or absorb light differentially to provide
nasal definition. The subunit principle proposed by Burget and Menick when resurfacing
nasal defects recommends replacing an entire subunit when more than 50% of the subunit
is missing. The subunit principle is mainly applicable to defects of the nasal tip
and alar subunits.[16] Because of their convex contour, defects that are irregularly shaped and occupy
more than 50% of the tip or ala subunit are best expanded and replaced as an uninterrupted
unit for a uniform contour and textural match.
Defects of the external soft tissue envelope should be viewed in four dimensions:
length, width, thickness, and time anticipating and factoring secondary changes from
contraction into the design of templates. For unilateral defects, the ideal template
is created from the contralateral side. Templates created directly from the defect
are less accurate as edema and wound contraction will likely distort the size of the
wound. For bilateral defects and more extensive near total nasal defects, additional
aids in obtaining accurate templates may be necessary. Facial surface scanning technology
can be helpful in generating stereolithography data for 3D models of the nose that
can be fabricated by an anaplastologist or 3D printed for intraoperative use. 3D surface
scanning is helpful when the nose is not overly distorted by cancer prior to resection.
Medical artists can be helpful in generating idealized drawings of a patients nose
from which prosthetic models can be generated, scanned, and manipulated for template
generation ([Fig. 5]). The technology for surface scanning has become ubiquitous. There are currently
several 3D scanning applications on the market for smartphones and tablets. Once an
accurate 3D model is obtained, a 2D template is generated from which the desired skin
for precise reconstruction can be determined and outlined on the donor site. While
1:1 tissue replacement of missing skin over the dorsum, tip, and sidewalls is ideal,
a calculated overcorrection may be prudent when designing the 2D template for a circumferential
nostril defect. Templates designed to include the nostril should account for the nasal
sill ([Fig. 6]). A common complication of complex nasal reconstructions is a stenotic nostril that
often fails to respond to stenting. The use of a 2D flap to reconstruct a 3D defect
is not straightforward and entails variables made evident by time, the fourth dimension,
wound healing, and contraction and skin compromise. Consequently, it is prudent to
stage these procedures allowing room for modifications.
Fig. 5 Three-dimensional models are particularly helpful in total nasal defects in determining
the needed lining, projection, and in designing two-dimensional templates for the
forehead flap.
Fig. 6 The forehead flap design should account for the true circumference of the nostrils
(green lines) and should not be compromised to reduce the size of the forehead defect.
The forehead flap remains the workhorse flap for reconstructing large external nasal
soft tissue envelope defects. The forehead flap provides ample vascularized tissue
with excellent color and texture match and acceptable donor site morbidity. There
is no good alternative to the forehead flap so bridges should not be burned in their
design. In rare cases where the forehead skin is unavailable for reconstruction, a
radial forearm free flap is an alternative option for reconstructing the nasal envelope.
The color match for free flaps is usually poor.
Classic Design of the Forehead Flap
Classic Design of the Forehead Flap
Forehead flaps can be harvested as a paramedian flap or midline flap based on the
supratrochlear vessels and the central artery. The extensive vascularization of the
forehead allows for the harvest of two to three flaps from the same side.[17] Intraoperative angiography can be used in assessing vascularity of the forehead
flap in revision cases when available.
The classic forehead flap is harvested as a paramedian flap based on the supratrochlear
artery. Pearls for designing this flap include limiting the pedicle base width to
1.5 cm and designing the flap as vertical as possible and not greater than 15 degrees
off vertical.[3] The size of the forehead flap should not be compromised to save forehead skin. Very
large donor site defects can be narrowed with spanning or purse string suturing and
residual defect allowed to heal by secondary intention. Efforts should be made to
minimize transfer of hair-bearing scalp to the nose but not at the expense of shortening
the reach of the flap. Techniques that increase the reach of the flap reduce the risk
of transferring hair-bearing scalp. For lateral defects, an ipsilateral flap has a
longer reach compared with a contralateral flap. The reach of the flap can also be
increased by extending the medial flap incision below the level of the brow. Careful
transverse release of the frontalis muscle across the width of the flap can gain ∼
1 cm of effective length.
The forehead flap can also be designed as a midline flap based on the central and
paracentral arteries. The pedicle to the midline forehead flap can be oriented slightly
obliquely and extended along the nasal side wall between the medial canthus and the
nasal dorsum extending the reach of the flap. This design is helpful in patients with
a low hairline.[18]
In patients with very low hairline or deficient skin as a result of previous surgery,
expansion of the forehead skin can be considered.[17]
[19] Expanded forehead flaps should be considered as a truly last resort since expansion
can compromise the dense subcutaneous fat of the forehead skin that makes it an ideal
donor site for nasal reconstruction.
Nasal Foundation
A stable foundation is required to support the reconstructed nose. The nose is supported
by the nasal bones and its articulation with the frontal bone and frontal processes
of the maxilla. The midline intranasal support by the perpendicular plate of the ethmoid
bones and the quadrangular septal cartilage is critical for maintaining intranasal
patency. The medial maxillary buttresses as well as the premaxillary bone with their
respective overlying soft tissues (cheek and lip) are essential transitions of the
nose. Defects that extend beyond the nose to involve the cheek and lip soft tissues
require additional attention without which the stability of the reconstructed nose
becomes secondarily compromised ([Fig. 1D]). To obtain a predictable result, deep cheek and lip defects may need to be reconstructed
and allowed to stabilize before reconstructing the nasal defect. Reconstructing the
nose and surrounding facial subunit defects in a single stage produces unpredictable
outcomes secondary to contraction of the cheek or lip repair.
Nasal Framework
The intricate 3D appearance of the nose reflects the underlying framework. The nasal
framework is a composite of the rigid bony vault comprising the paired nasal bones
and the frontal processes of the maxilla. Overlapping and articulating to the bony
pyramid are the upper lateral cartilages and the nasal septum. The shape and support
of the nasal tip is a result of the paired lower lateral cartilages and their interaction
with the nasal spine, caudal septum, supporting ligaments and the resilience of fibrous
tissue of the free alar margins. Without adequate and durable framework replacement,
any elaborate nasal reconstruction is likely to fail. Reconstruction of the nasal
framework can be anatomic and nonanatomic and should be approached with the mindset
of a structural engineer. Rigid grafts should be placed to counter retraction, twisting
and tilting in response to scar contraction. Anatomic grafts replace the named structures
of the nose: septum, upper lateral cartilage, and nasal bones. Nonanatomic grafts
are those grafts placed in areas that are naturally devoid of rigid support such as
alar rim grafts and cartilage grafts placed between the piriform margin and the alar
crease to minimize contraction and retraction. In general, it is best to repair bone
defects with bone graft and cartilaginous defects with cartilage, although replacing
one tissue type with the other is feasible.
When absent, reconstruction of the caudal septum with appropriate projection and stability
is critical. As described earlier, a septal pivot flap is effective in transposing
septal cartilage from the posterior septum anteriorly to provide caudal septal support.
In the absence of septal cartilage, the forehead flap can be designed with a wide
columella segment to wrap around a caudal septal strut.
Autologous bone and cartilage grafts are the ideal options for reconstructing nasal
framework defects. Common donor sites include auricular cartilage, septal cartilage,
septal bone, costal cartilage, and split calvarial bone grafts. Radiated rib cartilage
grafts may also be used, although they introduce an element of uncertainty as to their
long-term stability, increased risk for resorption or infection. The choice of donor
graft material depends on the location and extent of the defect. For instance, the
natural curvature of the concha cartilage makes it an ideal option for the reconstruction
of alar defects. In general, rib cartilage graft is preferred to auricular cartilage
graft in both children and adults as it provides ample cartilage with durable strength.
In children in particular, auricular cartilage does not appear to provide durable
support and lag in growth.[3]
The timing of framework reconstruction is an important consideration when planning
for complex nasal defect reconstruction. For structural grafts to be effective, they
must remain well vascularized over time. As such, it is recommended to defer the placement
of structural grafts to the intermediate stages when the soft tissue envelope and
lining have become well vascularized. A temporary structural support using titanium
mini plates may be used in such cases to prevent excessive contraction and distortion
of the soft tissue construct.
The cartilage graft applied may be considered as structural versus contouring graft.
The central and lateral structural grafts are placed during the intermediate steps
after the nasal lining has stabilized. Central structural grafts include columella
struts, caudal septal graft, dorsal onlay grafts, extended spreader grafts; these
reconstitute the support L-strut and provide the needed projection of the nose. The
lateral structural grafts include the alar batten grafts, rim graft, and nonanatomic
graft placed between the nasal bones and alar batten grafts ([Fig. 7]).
Fig. 7 Structural grafts should include stable central and transverse columns. These include
anatomic and nonanatomic grafts (A). Additional contour grafts are placed as onlay grafts to fill in all the spaces
between the structural grafts. Here diced cartilage stabilized with fibrin glue is
contoured into place with the aid of a transparent three-dimensional model of the
desired nose (B, C).
Alar battens are best sculpted from strips of rib cartilage graft. These strips warp
when carved but may be modified further with sutures and strut grafts to take on the
desired shape. The alar battens graft should have the shape of typical alar lobule
and should extend into the soft triangle region to give support to the nostril margin.[11]
Contouring and Refinement
Contouring and Refinement
To achieve a defined nose, the skin envelope must reflect light over the dorsum and
absorb light along the alar crease, supra tip, and nasal sidewall. This requires an
appropriately thinned skin envelope and strategically placed contour graft. Creation
of the alar crease seems to be elusive. Burget and Menick[3]
[19] had proposed full-thickness skin incision with anchoring sutures to aid in alar
crease formation. We have found the use of subcision with a 2-mm biopsy punch very
effective in creating an alar crease.
The nostrils should be inspected at this stage for patency and symmetry. Minor skin
excision and tissue rearrangement techniques are employed to even out any asymmetries.
Pedicle Division
Pedicle division is reserved as the last step in these complex nasal reconstructions
and is performed only when a stable and satisfactory nose free of complications has
been achieved.
Smokers
It is well known that smoking has a detrimental effect on wound healing. Smoking is
associated with tissue hypoxia and thrombosis of the microvasculature. This physiologic
impact of smoking results in skin necrosis, increased risk of infection, and wound
dehiscence.[20] Smoking cessation should be recommended, and increased risk of complications should
be discussed preoperatively with patients who are active smokers. There is an increased
risk of failure when random flaps and composite grafts are used in active smokers;
these techniques should be avoided in smokers whenever possible.
Conclusion
Techniques for nasal reconstruction have been refined over several decades. Current
techniques allow reconstruction of most complex defects with normal functional and
aesthetic outcomes. With careful planning and meticulous execution consistently, good
results can be achieved.