Contraindications to Skin Resurfacing

Contraindications to skin resurfacing can be extrapolated to resurfacing with peels and lasers. However, what gives chemical peels an advantage over laser resurfacing procedures is that with the proper skin conditioning as well as the proper procedure depth, patients of most skin types can be treated. Furthermore, areas that are usually not amenable to laser resurfacing (neck, lips, eyebrows, ears) can be safely peeled with the proper chemical peel allowing for safe combination resurfacing in one sitting to give overall rejuvenation with little to no lines of demarcation.

Just from the injury to the skin with a peel, darker-complexion patients are at risk for temporary postinflammatory hyperpigmentation (PIH). With peels that reach the reticular dermis, these patients are at risk for permanent hypopigmentation. To minimize this risk for PIH, the length of preoperative skin conditioning should be extended to 3 months and resumed immediately upon reepithelialization of the skin. Because PIH is usually transient, it is not a contraindication to resurfacing; rather, it should be anticipated and addressed before resurfacing.

When performing resurfacing that is deeper than an epidermal-level procedure, the general health and nutritional status of the patient becomes an important consideration. Deeper laser resurfacing and medium-depth and deep peels require a healthy nutritional status and well-functioning immune system for uneventful wound healing. Patients who have undergone bariatric surgery oftentimes are deficient in vital nutrients, iron, and protein. Blood laboratory tests can help identify issues. Immunocompromised patients such as transplant recipients or those on medications for autoimmune diseases are immunologically impaired, putting them at risk for infection. These patients may require coverage with an oral antibiotic during the healing period (penicillin, cephalosporin, or trimethoprim/sulfamethoxazole).

Patients should be asked questions to ascertain issues with wound healing, hypertrophic or keloid scars, or a tendency to develop PIH. Inflammatory skin conditions can also flare post-resurfacing, thus it is important to inquire about the presence of seborrheic dermatitis, atopic dermatitis, and rosacea. Probably, the most challenging patients to treat are those with melasma ( Fig. 14.2 ). This is because the condition can flare and worsen post-resurfacing if the patient is taking exogenous hormones or is exposed to heat or sunlight too soon.

Melasma can be a challenge to treat. Hormonal factors and sunlight can complicate treatment, healing, and relapse. The patient is shown at baseline (A–B), after 7 months of good skincare (C–D), and after 6 years of a good skincare regimen (E–F).

A history of recent systemic retinoid use was once considered an absolute contraindication for skin resurfacing because of concerns of increased hypertrophic scar formation in these patients. More recent studies and case series have shown that this concern may not be valid. Patients having laser hair removal, laser skin resurfacing, or medium-depth peels in these studies did not demonstrate increased adverse outcomes. Although these studies may be small, they do show the complexities associated with keloid formation, and they challenge the conventional thinking that isotretinoin impairs wound healing. For medium-depth peels or dermal-level laser resurfacing procedures, it may be prudent to stop isotretinoin 3–4 months before the peel. If a patient has an inflammatory condition such as acne or rosacea, oral antiinflammatory antibiotics (doxycycline) can be used temporarily to calm the condition down.

A similar question arises with regard to the safety of simultaneous skin resurfacing and cosmetic surgery. The goal is to optimize results for patients by combining skin resurfacing the same day as their surgical procedure. In the past, it was thought that combining these procedures increased the chance of impaired wound healing. Newer studies have shown safe outcomes when combining fractionated laser resurfacing with short-flap rhytidectomy, full-face laser skin ablation combined with rhytidectomy, and fractionated CO ₂ laser, brow lifting, and surgical blepharoplasty ( Fig. 14.3 ). Care should be taken to minimize the depth of resurfacing over flaps (not deeper than the basal layer or papillary dermis) and kept away from incisions, whereas the peel or laser resurfacing can be performed more deeply over the central face (non-undermined skin). The safe window for resurfacing is either the same day as surgery or 6–12 months after a facelift or browlift procedure. The extensive undermining during facelifts/browlifts compromises the skin’s lymphatic drainage, so it is best to wait 6–12 months to reduce the risk for prolonged postoperative edema if the peel is not performed on the same day as the surgery.

The undermined area of the flap during a facelift, where the peel will be the most superficial is shown (left) . This patient underwent laser resurfacing of the central face and a lighter peel over the cheek flap (center) . Another patient underwent a 30% TCA peel with one coat over the flap and two coats over the central face (right) .

Although most patients can safely undergo skin resurfacing, there are certain contraindications. The absolute contraindications include active infection at the treatment site, pregnancy, significant tendency to develop keloids, and the inability to adhere to postoperative instructions.

Evaluating Skin Type

When resurfacing skin, the patient must be evaluated correctly to help choose the correct procedure and depth of treatment and to help reduce postoperative complications. This evaluation must be performed in a standardized fashion. Skin color alone is not sufficient in guiding procedure depth. If one looks more closely, there are some important variations that exist, even among patients of the same skin color. Particular attention should be paid to patients who have freckles, develop melasma, or are prone to PIH. Regardless of ethnic background, the presence of these issues heralds the risk for postprocedure hyperpigmentation.

Fitzpatrick phototype is simply a way to type the skin based on the ability to tan in response to UV exposure. In this classification, patients are categorized from I to VI as their skin color darkens and their ability to tan rather than burn increases. This classification was intended to help physicians treat patients with phototherapy and is limited in that it does not address the degree of photodamage present or assist in selecting the correct procedure depth. Glogau’s classification attempts to objectively quantify the amount of photodamage present, but it does not help determine the best resurfacing modality or depth or resurfacing needed.

In particular, both of these scales were devised before the emergence of nonablative and fractionally ablative technologies and fall short in addressing patients with thicker skin or darker skin types. The author utilizes the Obagi skin classification ( Table 14.3 ) to help with proper procedure planning.

The Obagi skin classification incorporates five variables that are important to address before any resurfacing procedures: skin color, oiliness, thickness, laxity, and fragility. This system helps identify patients who require a longer preoperative and postoperative skin conditioning program, those who are more likely to hyperpigment or hypopigment, those who are prone to delayed healing, and those who require a skin tightening procedure (peels, lasers) over a planing procedure (dermabrasion). The evaluation of all five factors helps maximize skin resurfacing results while minimizing complications.

Although the concern of permanent hypopigmentation exists, there are some patients at risk for pseudohyperpigmentation . These patients tend to have extensive photodamage, and they should be approached with caution. Pseudohypopigmentation refers to an area that once had extensive sun damage and is now resurfaced back to the patient’s baseline skin color and condition. Once the treated area heals, the absence of photodamage may stand out in stark contrast to nearby, untreated, photodamaged skin. This gives the appearance of hypopigmentation of the treated skin. However, when one compares the treated skin to other sun-protected areas, the color of the newly treated skin is not lighter than the patient’s baseline ( Fig. 14.4 ). To minimize this contrast and minimize lines of demarcation, one should consider using topical agents or lighter peels to blend in the skin adjacent to the treated area.

This patient is shown at baseline (A–B) and 4 weeks after medium-depth chemical peel (C–D). The patient exhibited temporary hypopigmentation (E–F), which corrected over several months.

Mechanisms of Action

There are many factors that affect the depth of penetration of a peel. Simply utilizing peel acid concentration or the type of acid as the sole determinant of depth can lead to complications. The most important points to consider in determining peel depth are acid concentration, volume of acid applied, skin thickness, percentage of body surface area treated, skin preconditioning, and in some cases (i.e., glycolic acid), the duration of contact of acid on the skin.

For medium-depth peeling, it is important to understand the main mechanism of action of the acid on the skin, especially when performing combination peels ( Table 14.4 ). This is either a keratolytic effect or a protein denaturant effect. The keratolytics are mainly used for superficial, exfoliative procedures, whereas the protein denaturants can be used both for superficial or deeper peels, as we will discuss in the following sections.

Keratolytics

Keratolytic acids work by disrupting the bonds between the keratinocytes, thereby causing shedding of these layers. Glycolic acid and salicylic acid are the two most commonly used acids for light peels; however, there are many other peels and combination peels that incorporate lactic acid, mandelic acid, citric acid, resorcinol, retinoic acid, and Jessner’s solution. Jessner’s solution is a popular peeling solution composed of 14% each of resorcinol, salicylic acid, and lactic acid mixed in ethanol.

Salicylic acid and Jessner’s solution (contains salicylic acid) have an advantage over glycolic acid in that salicylic acid is lipophilic. Lipophilic agents penetrate acne lesions or oily skin better than hydrophilic agents such as glycolic acid. Another advantage is that salicylic acid and Jessner’s solution do not require close timing of skin contact time, as required with glycolic acid peels.

The main role of keratolytic peels is to address superficial conditions such as acne, mild sun damage, and mild dyschromias. These are oftentimes referred to as lunch-time peels as these light peels have the benefit of little to no down time. Nurses and aestheticians are usually delegated to perform these light peels as there is no anesthesia requirement, and they are relatively straightforward to perform. Patients must be aware that multiple sessions are required to see clinical improvement. A comprehensive skincare regimen can really help speed up the results and increase the results of these light peels.

Protein Denaturants

For medium-depth and deep peels, phenol and trichloroacetic acid (TCA) are the main protein denaturant peeling agents used. TCA has a long, proven safety record, while newer formulations of phenol peel mixtures have increased the versatility and safety of this once aggressive peeling agent. TCA and phenol work by causing protein coagulation and denaturation of the cells of the epidermis, dermis, and blood vessels as they penetrate into the skin. Once a certain volume of the acid is applied to the skin, it will keep coagulating proteins until it is used up. This means that TCA and phenol solutions cannot be neutralized once they begin to be absorbed into the skin. There may be time to wipe excess TCA off the surface of the skin if too much is applied, but phenol rapidly penetrates the skin. After about 2 minutes, the depth of TCA penetration can be observed, and a decision can be made if more acid is needed to drive the peel deeper. Phenol is a lot more rapid in its penetration, and the depth is apparent almost immediately. Subsequent application of acid will continue to drive the peel deeper until it is used up by coagulating proteins deeper in the skin. When used correctly, these acids can be used to achieve a variety of peel depths ranging from exfoliation to deep peels.

It is of utmost importance to purchase the peel solutions from a reputable source to reduce the risk for errors and complications. TCA solutions, for example, can be formulated by four different methods. The safest and most agreed-on method is the weight to volume (W:V) calculation. The author personally only purchases TCA from Delasco (Council Bluffs, IA). To further minimize errors, the author only keeps on hand 1 strength of TCA, 30% TCA solution, which is then modified as part of the Blue peel to create a 15%, 20%, 22.5%, or 24% solution. Similarly, there are many variations on phenol/croton oil peel formulas, requiring a reliable pharmacy to formulate these solutions. All chemical peel solution bottles are clearly labeled. To further increase safety, TCA and phenol solutions are kept in a separate cabinet from the light peel solutions that the aesthetician staff uses.

Trichloroacetic Acid Peels

As mentioned earlier, it is not correct to refer to TCA peels as light, medium , or deep solely based on TCA concentration. Acid concentration is only one variable affecting peel depth. For example, 1 mL of 40% TCA applied to the face will result in less skin penetration than 6 mL of 40% TCA applied over the same body surface area.

Another misconception is that lasers are easier to use once the settings are learned. With proper training and experience, one can perform peels to a number of skin depths with the same aptitude that one uses to dial in laser settings for skin resurfacing. Additionally, TCA peels can be used to blend into the hairline, brows, ears, and onto the neck, whereas lasers may be contraindicated in these areas.

TCA 10%–50% can be used as a sole peeling agent, but using higher concentrations comes with increased risk. The TCA molecule is hydrophilic, thereby allowing for patchy penetration of the peel solution through the lipid-containing, thick stratum corneum. Applying more TCA solution will penetrate further into certain areas (with thinner stratum corneum or denuded skin) than others, risking an uneven peel. Therefore it is a fine balance between reapplying TCA at high concentrations in areas that need it without risking too deep of a peel.

A way around this issue is to prepare the skin topically in a manner that facilitates even TCA penetration by making the stratum corneum more even and compact. Because oil hinders TCA penetration, oily skin must have adequate oil control before performing the peel. This can be achieved with a short course of isotretinoin for a few months ending about 3–6 months before the peel. To address any residual oil or lotions on the skin on the day of the peel, the skin must be properly degreased with 70% alcohol and, in some instances, acetone.

Combination peels or modified TCA peels have been developed to allow for more even penetration of TCA at 30%–35% without having to resort to higher concentrations. These peels are designed to reach the papillary dermis level in a more consistent manner.

The three most commonly used modified TCA peels are the Jessner’s solution–TCA peel, glycolic acid–TCA peel, and the Blue peel ( Table 14.5 ). These peels are designed to peel to a depth of the papillary dermis and at most, to the most superficial aspect of the reticular dermis. The main indications for TCA and modified TCA peels are for epidermal and upper dermal pathology: photodamage, actinic keratoses, lentigines, ephelides, fine rhytids, and very superficial, nonfibrotic (stretchable) scars. These peels are not suited for fibrotic scars, deep nonstretchable rhytids, or extensive laxity. If a rhytid or scar improves with stretching the skin, a medium-depth peel can help improve it. However, if the scar or rhytid is etched into the skin or is fibrotic, the tightening effect of the peel may not be enough to give adequate clinical improvement.

Table 14.5

Modified trichloroacetic acid peel formulas

Modified TCA peels	Solutions	Technique
Glycolic acid–TCA peel	70% glycolic acid 35% TCA	70% glycolic acid applied Neutralized after 2 minutes Light application of 35% TCA
Jessner’s solution–TCA peel	Jessner’s solution 35% TCA	Jessner’s solution applied Rinsed with water after 6 minutes Light application of 35% TCA
TCA-Blue peel	Blue peel base 30% TCA	2 mL (1 tube) Blue peel base mixed with: • 2 mL 30% TCA = 15% TCA-Blue peel • 4 mL 30% TCA = 20% TCA-Blue peel • 6 mL 30% TCA = 22.5% TCA-Blue peel • 8 mL 30% TCA = 24% TCA-Blue peel

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