Abstract
The skin is a very accessible organ for obtaining tissue specimens for pathologic examination or for performing definitive curative surgery. Under local anesthesia, specimens may be obtained via a number of different surgical procedures including curettage, punch biopsy, shave or saucerization excision, incisional sampling, and excision in toto . The wounds then heal by second intention or by a layered closure with initial suturing of the subcutaneous tissue followed by suturing of the epidermis. Contraindications are few although modifications may be required to deal with patient or anatomic site issues. Likewise, complications are few and are generally preventable with appropriate aftercare.
Keywords
skin biopsy, incisional biopsy, excisional biopsy, curettage, punch biopsy, saucerization, shave excision, M-plasty, pursestring suture, undermining, second intention healing, snip biopsy, S-plasty, dog-ears, standing cones, rule of halves
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Choice of a particular biopsy technique is based upon the anatomic site, type of skin lesion, desired histologic information, and patient preference
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Wound closure is accomplished via suturing (primary intention) or second intention
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Choice of a specific suturing technique depends upon the needs of the wound (e.g. eversion of the edges), with the goal being an optimal functional and aesthetic result
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Excision in toto with repair is a common surgical procedure for dermatologists and it is accomplished through a series of well-defined steps
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Postoperative care and instructions minimize the risk of complications
Introduction
The cornerstone of dermatologic diagnosis is the correlation of clinical and histologic findings. A biopsy procedure is required in order to obtain tissue for pathologic examination, and fortunately the skin is more accessible than most other tissues. Modern instruments and techniques allow cutaneous biopsies to be performed efficiently with minimal tissue distortion. In some situations, a biopsy procedure is also curative, either coincidentally or intentionally. Knowledge of basic excisional surgical techniques can minimize cosmetic and functional impairment. Performance of a timely skin biopsy may also circumvent the need for more invasive procedures. Even critically ill patients can undergo a skin biopsy with minimal risk.
Key Concepts
Site Selection
Performance of a biopsy that will yield accurate and relevant histologic information depends upon the selection of an appropriate lesion or site within a lesion ( Table 146.1 ).
| BIOPSY SITE SELECTION | |
| Lesion/disorder | Appropriate site |
| Tumor | Thickest portion; avoid necrotic tissue |
| Blister | Edge of lesion, including perilesional skin (see Fig. 29.12 ) |
| Ulcerated/necrotic lesion | Edge of ulcer or necrosis plus adjacent skin |
| Generalized polymorphous eruption | Characteristic lesion of recent onset (± more developed lesion as multiple biopsies often obtained) |
| Small vessel vasculitis | Characteristic lesion of recent onset |
The anticipated depth of the lesion to be biopsied must also be considered. In the case of a superficial lesion, e.g. an actinic keratosis versus Bowen disease, it can be assessed via a more “superficial” biopsy that extends to the papillary dermis. On the other hand, accurate diagnosis of a subcutaneous nodule, e.g. panniculitis versus polyarteritis nodosa, requires a biopsy that includes subcutaneous tissue. Occasionally, fascia must be obtained, e.g. morphea profunda versus eosinophilic fasciitis. Disorders that primarily affect the collagen and elastic fibers within the dermis may have subtle histologic findings (e.g. atrophoderma of Pasini and Pierini) and longitudinally sectioned wedge biopsies that include both the affected area as well as adjacent normal-appearing skin prove most helpful.
Biopsy Technique Selection
Seven major methods are employed to biopsy skin: curettage, snip or scissors biopsy, shave biopsy, saucerization biopsy, punch biopsy, incisional biopsy, and excision in toto ( Table 146.2 ). Depending upon the type of lesion and its size, several of these procedures are also curative, especially excision in toto. However, these methods do differ with regard to the quality and quantity of skin obtained. Lesional characteristics and operator experience are factors that influence the choice of a particular procedure.
| SELECTION OF TYPE OF BIOPSY TECHNIQUE | ||||
| Method | Indication | Type of specimen obtained | Anesthetic technique (see Fig. 146.1 ) | Closure |
| Curettage |
| Epidermal sheet or fragments of epidermis and dermis | Wheal | Secondary |
| Scissors biopsy |
| Tissue above connection to the epidermis | None or wheal | Secondary |
| Shave biopsy |
| Epidermis, papillary dermis and, occasionally, reticular dermis (elevated lesions) | Wheal | Secondary |
| Saucerization biopsy |
| Similar to a shave biopsy, but specimen is thicker (i.e. contains reticular dermis) | Wheal or deep infiltration | Secondary |
| Punch biopsy |
| Epidermis, dermis and, sometimes, subcutaneous fat | Wheal or deep infiltration | Primary; simple suture |
| Incisional biopsy |
| Epidermis, dermis and subcutaneous fat Can include fascia where needed | Deep infiltration | Primary; layered closure |
| Excision in toto |
| Epidermis, dermis and subcutaneous fat Can include fascia where needed | Deep infiltration | Primary; layered closure |
Curettage is frequently used to remove clinically benign epidermal lesions such as verrucae or seborrheic keratoses, actinic keratoses (AKs), and basal cell carcinomas (BCCs), especially the superficial type. The curettings can also be used to confirm the clinical diagnosis, but histologic interpretation may prove more challenging if the tissue specimen is fragmented and its orientation becomes problematic. Snip or scissors biopsy is an efficient technique for assessing pedunculated lesions as well as removing benign growths (e.g. acrochordons, filiform warts).
The shave biopsy usually provides a specimen consisting of epidermis, papillary dermis, and sometimes reticular dermis (particularly in elevated lesions). It is a popular biopsy technique for recontouring papular, clinically benign lesions (e.g. irritated or unwanted compound and dermal melanocytic nevi, fibrous papules of the nose) where histologic confirmation is desired. Shave biopsy is also a useful procedure for diagnosing superficial carcinomas, e.g. nodular and superficial BCCs, squamous cell carcinoma (SCC) in situ , and lentigo maligna.
Some authors distinguish a shave biopsy from a saucerization procedure in which the depth of the biopsy specimen is intentionally deeper due to angulation of the blade. This latter technique is often used to biopsy melanocytic nevi with atypical features when the differential diagnosis includes a thin melanoma . Its advantage is that it allows histologic examination of the entire lesion, which increases diagnostic accuracy, especially in the case of larger lesions (as compared to partial punch biopsy). Saucerization is also performed to confirm the clinical diagnosis of minimally invasive SCC or keratoacanthoma and to distinguish the former from a hypertrophic AK.
The punch biopsy supplies a cylindrical to conically shaped specimen consisting of epidermis, dermis and, sometimes, subcutaneous fat. The volume of tissue sampled correlates with the size of the punch biopsy instrument. In general, the diameter of the metal “barrel” varies from 2 to 6 mm, and the wider the diameter, the greater the likelihood of obtaining subcutaneous fat. However, the thickness of the dermis and the amount of subcutaneous fat required to establish the diagnosis must be kept in mind. Punch biopsies are particularly helpful for examining processes within the dermis, e.g. tumors, inflammation (see Table 146.2 ). In the case of tumors, sampling a majority of the lesion is desirable, so that for large-sized tumors, multiple punch biopsies may be required.
The incisional biopsy removes a wedge of tissue from the center or edge of a lesion (see Site selection ) and is the best option for obtaining deep subcutaneous fat or fascia for histologic examination. It is also used to sample a significant portion of large-sized tumors. Excision in toto removes the entire lesion and includes epidermis, dermis and subcutaneous fat. For these reasons, it is often utilized when the leading clinical diagnosis is invasive cutaneous melanoma.
Specimen Handling
Transportation of the biopsy specimen to the laboratory differs according to the processing and type of examination required. Most specimens are placed in formalin, but, occasionally, special carrier media are necessary ( Table 146.3 ). Fresh tissue specimens are sent on saline-moistened gauze and either promptly delivered to the laboratory or packed in ice; the laboratory must be in reasonable proximity and have the capability of processing the tissue immediately. When handling small or thin biopsy specimens, it is important to confirm that they are clearly within the formalin solution and not adhering to the upper portions of the container or lid; this prevents desiccation artifact.
| SPECIMEN HANDLING | ||
| Proposed laboratory test | Carrier medium | Comments |
| Routine microscopy, immunohistochemistry, PCR assay | 10% neutral buffered formalin | Fixation process begins immediately |
| Direct immunofluorescence | Michel’s medium or fresh * | Depends on laboratory preference or availability |
| Flow cytometry | Fresh * | Lymphoma cutis |
| Culture for bacteria, mycobacteria or fungi | Fresh * or minced in sterile culture/carrier medium appropriate for organism (usually performed by laboratory) | |
| Culture for viruses | Viral transport medium (e.g. M4RT ® ) | |
| Electron microscopy | Glutaraldehyde | |
* Laboratory must be in close proximity and specimen placed on saline-moistened gauze, but need to avoid bacteriostatic saline solution when culturing for microbes.
A protocol must be established within the clinician’s practice to ensure that specimens and results are appropriately tracked and assigned to the correct patient. Immediately after the biopsy specimen has been obtained, it should be placed in a container prelabeled with the patient’s name and other identifying information. If multiple biopsies are to be performed, pre-labeling the containers alphabetically and with the respective sites avoids confusion. A specimen log book ( Table 146.4 ) ensures notification of the results to the patient and disposition of recommended care.
| LOG BOOK FOR BIOPSY SPECIMENS | |||
|---|---|---|---|
| Date | 2/21/17 | 2/21/17 | 2/22/17 |
| Patient initials with birthdate versus full name | TMF 4/4/87 | John Doe | James Brown |
| Anatomic site | right cheek | right thigh | left scalp |
| Specimen pick-up (+/− initials) | √ | √ | √ |
| Histopathologic diagnosis | BCC | Reactive changes | Pilar cyst |
| Patient informed/plan if needed | Called 2/28/17/surgery SO * | Released to EMR ** | Letter sent ** |
** In the era of EMRs, patients can choose to have personal online portals; letters generated are included in the electronic record (for those who decline the portal).
Patient Preparation
A discussion of the reason(s) to do the biopsy, the site to be biopsied, and the technique to be used can be brief and to the point. Informed consent requires a discussion of the major risks, which include bleeding, discomfort, infection, and scarring (see Ch. 151 ). Bleeding can usually be controlled by firm pressure at the site of the wound, but may require more aggressive forms of hemostasis. Discomfort is usually minimal, although some sites such as the forehead, fingers and feet may throb.
Infection is unusual. Except when the area to be biopsied is already infected or the site is mucosal, the skin can be prepared by application of an antiseptic agent and the procedure is then considered to be a clean procedure. For clean procedures of non-mucosal, non-infected sites, preoperative prophylactic antibiotics are currently not recommended, even in patients with artificial valves or joints (with the possible exception of sites at high risk of infection, e.g. groin, during the first 2 years after joint placement) . The overall goal is a reduction in the emergence of antibiotic-resistant bacteria and in one study, for example, preoperative prophylactic antibiotics increased nasal carriage of methicillin-resistant Staphylococcus aureus . Tables 151.2 and 151.3 review the guidelines for antibiotic prophylaxis as well as regimens for both oral and non-oral sites. Preoperative antibiotics are administered within a 2-hour window before the incision; there is debate as to whether or not a second dose is administered 6 hours later and under which circumstances antibiotics should be continued for 48–72 hours . When pretreated with a 5-day regimen of intranasal mupirocin ointment (twice daily) and a total body wash with chlorhexidine soap (daily avoiding the eyes and ears), nasal carriers of S . aureus were observed to have fewer postoperative infections .
Most patients are primarily interested in discussing whether or not there will be visible scarring. This is best predicted by the type of biopsy to be performed and the anatomic site. Generally, patients can be reassured that small biopsies may be done without grossly noticeable permanent “marks”.
Many patients are anxious about the needle sticks required for administration of the local anesthesia and the pain of the procedure. The patient’s cooperation is easily obtained in an organized and peaceful environment with a calm and reassuring staff. A well-informed, comfortable patient in a supine position will tolerate the procedure without difficulty.
Site Preparation and Anesthesia
Effective site preparation is most efficient if a standard clinical protocol has been established ( Table 146.5 ). Marking and photographing the site , cleansing the skin ( Table 146.6 ) , and draping are important procedures prior to the instillation of local anesthesia. Local anesthesia is adequate for all skin biopsies and is reviewed in detail in Chapter 143 .
| SITE PREPARATION PROTOCOL | |
| Sequential steps | Comments |
| Mark site with surgical pen or ink | Local anesthesia may obscure site, especially when the erythematous color is due to vasodilation or when there is a minimally elevated dermal tumor |
| Time out for patient and site identification | JCAHO universal protocol for patient safety |
| Photograph site or record landmarks | Up to ~15% of biopsy sites may be later incorrectly identified by the patient and ~5% by the surgeon |
| Clip hair as needed | Shaving hair increases incidence of infection |
| Cleanse skin surface | Antiseptic agents listed in Table 146.6 |
| Drape | Gauze (small biopsies) or sterile towels |
| Anesthetize | Local instillation of anesthetic agent |
| ANTISEPTIC AGENTS | ||
| Agent | Advantages | Disadvantages |
| Povidone-iodine (Betadine ® ) | Broad antimicrobial spectrum, including fungi | Irritant and allergic contact dermatitis Residual color May cross-react with iodine in radiocontrast media and iodides in medications |
| Chlorhexidine (Hibiclens ® ) | Broad antimicrobial coverage Limited systemic absorption Prolonged suppression of bacterial growth | Keratitis due to ocular exposure Cochlear damage if enters middle ear Irritant and allergic contact dermatitis Contact urticaria Very rarely, anaphylaxis |
| Isopropyl alcohol | Inexpensive Denatures protein, including bacterial cell walls Immediate (but not prolonged) effect | Weak antimicrobial activity Flammable in the setting of cautery Skin irritant Skin must remain wet for 2 minutes for maximum effect |
| Chlorhexidine–isopropyl alcohol combination (ChloraPrep ® ) | Combination provides both short-term and long-term effects Evidence it is more effective than povidone-iodine | Those of either agent alone (see above) |
| Hexachlorophene (pHisoHex ® ) | Strong effect against Gram-positive cocci | Little effect on Gram-negative organisms or fungi Teratogen Absorbed through skin with potential neurotoxicity in infants |
| Soap and water | Traditional preoperative handwashing regimen Disinfects hands as well as alcohol-based rubs Better against Clostridium difficile and Norwalk virus | At operative site, cumbersome and messy No prolonged antisepsis |
| Hydrogen peroxide | Readily available Inexpensive | No significant antiseptic properties Cytotoxic to keratinocytes in vitro |
When the local anesthetic agent is instilled into a deep compartment (i.e. subcutaneous fat; Fig. 146.1A ), 5 to 10 minutes is required for anesthesia to develop on the surface of the skin. Gentle massage of the site may assist in spreading the agent subepidermally and achieving good anesthesia. Injection of the agent superficially, creating an edematous wheal, has immediate efficacy but is more painful ( Fig. 146.1B ). Since a punch or shave biopsy requires very little agent and therefore a very short injection time, superficial instillation is the technique often used. In addition, a wheal is helpful prior to a shave biopsy as the lesion is further elevated from the plane of the surrounding skin. Of note, since epinephrine (adrenaline) requires up to 15 minutes to produce maximal vasoconstriction and thereby minimize bleeding , lidocaine without epinephrine is sufficient for an immediate biopsy. Regardless of other considerations, it is critical to have the local anesthesia in the compartment that is to be biopsied, i.e. a superficial wheal may be entirely adequate as anesthesia for a shave biopsy but will not suffice for an incisional wedge biopsy that extends into the subcutaneous fat.
Hemostasis
All biopsy procedures require attention to hemostasis of the wound bed ( Table 146.7 ; see Table 151.5 ). While styptics and absorbable hemostatic sponges are used for those wounds healing by second intention, punch biopsy sites are usually closed primarily with the suturing itself providing sufficient hemostasis. Wounds created during an incisional biopsy or excision in toto may require electrocoagulation for hemostasis before closure (see Ch. 140 ). The endpoint is no active bleeding in the wound bed. Bleeding within the dermis in the sides of the wound can be controlled by suturing and does not need cautery. At times, to produce hemostasis, a large actively bleeding vessel may need to be identified, grasped with a hemostat, and tied off with an absorbable suture and a figure-of-eight stitch ( Fig. 146.2 ).
| METHODS OF HEMOSTASIS | |
| Method | Comments |
| Compression |
|
| Styptics: aluminum chloride hexahydrate (Drysol™, Xerac AC™) or ferric subsulfate (Monsel’s solution) * |
|
| Absorbable hemostatic sponge: Gelfoam ® , Instat ® , Oxycel ® |
|
| Electrocoagulation and heat cautery |
|
| Sutures |
|
* Ferric subsulfate (Monsel’s solution) can result in a tattoo.
Wound Closure
Closure of wounds created by a biopsy procedure may occur by either secondary or primary intention healing. Second intention healing repairs wounds by the processes of granulation tissue formation, epidermal cell migration, and contraction (see Ch. 141 ). These processes occur simultaneously, beginning within the first few days after surgery and continuing until the wound has completely re-epithelialized. For the remainder of the patient’s life, maturation of the scar occurs, with gradual improvement in color, texture and contour. Indications, disadvantages, and contraindications for second intention healing are outlined in Table 146.8 .
| SECOND INTENTION HEALING – INDICATIONS, DISADVANTAGES AND CONTRAINDICATIONS |
| Indications |
|
| Disadvantages |
|
| Contraindications |
|
Closure of the wound via suturing is regarded as primary intention healing. The same processes of granulation tissue formation, epithelial migration, and contraction occur; however, they are significantly reduced, because the sides of the wound are already apposed. Processes related to fibroblast activity and collagen deposition play a more important role in primary intention healing, allowing adequate tensile strength to develop in order to keep the wound closed . These scars also undergo maturation throughout the remainder of the patient’s life. Both secondary and primary intention healing are promoted by appropriate wound care and dressings.
For primary intention healing, wounds may be closed either by placement of a simple full-thickness suture or by layered closure. In a layered closure, subepidermal buried sutures appose subcutaneous and dermal tissue, provide alignment of the wound edges, set up the wound edges for eversion, and assist with hemostasis by occluding any vessels bleeding within the edge of the wound. In addition, the subepidermal sutures supply strength to handle tension within the closure. Although subepidermal sutures are generally absorbable, they remain intact within the tissue for 8 to 12 weeks, the period during which the scar is slowly acquiring tensile strength. As a result, they prevent dehiscence and spread of the scar. Epidermal or skin sutures appose the epidermal edges and complete eversion. They can also correct minor degrees of misalignment in the closure. Satisfying these objectives via conscious placement of sutures improves the function and appearance of the scar .
Knotting is the means for stabilizing the placement of the suture, usually produced with an instrument tie ( Fig. 146.3 ). The first throw of the knot is started by pulling the long end of the suture tight with the fingers of the non-dominant hand and looping it around the needle holder once or twice. The needle holder then grasps the short end and pulls it through the loops. The loops are pulled across the wound so that they lie flat. These steps are then repeated to produce the second throw of the knot, but this time with the loop in the opposite direction around the needle holder. When this second loop is pulled across the wound, a square knot is created. Depending on the memory and thickness of the suture material (see Ch. 144 ), three to six throws may be required to properly secure the knot. Care is taken to ensure that the knot lies flat without significant tension or tightness . Sometimes, a loose loop is left in the second throw, to allow the suture to adjust to any wound swelling that may develop.
Sutures commonly used for subepidermal placement are composed of synthetic absorbable materials, e.g. braided polyglactin (Vicryl ® ), monofilament polydioxanone (PDS ® ). The interrupted buried dermal stitch ( Fig. 146.4A ) is designed such that the stitch is in the dermis and fat and the knot is inverted (buried). The needle enters the undermined deep surface of the wound (not the sidewall) and passes up into the dermis. After crossing the wound, it enters the opposite side of the wound at the same level in the dermis and then exits the deep surface. The knot is then tied and the ends of the suture cut. When the suture material is released, the knot settles within the deep portion of the wound, minimizing tissue reaction to the suture and extrusion through the wound. Enough buried dermal sutures are placed such that tension is eliminated and the deep tissues are completely apposed. In order to facilitate eversion, this basic stitch may be modified, creating a buried vertical mattress stitch . In this stitch, the suture is nearest to the skin surface (within the superficial dermis) at a point 3–4 mm lateral to the wound edge, and then it exits the wound deeper in the dermis ( Fig. 146.4B ). A very subtle dimple may be appreciated above the suture where it lies superficially in the dermis.
