Skin Thickness of the Anterior, Anteromedial, and Anterolateral Thigh: A Cadaveric Study for Split-Skin Graft Donor Sites

Article information

Arch Plast Surg. 2014;41(6):673-678
Publication date (electronic) : 2014 November 03
doi : https://doi.org/10.5999/aps.2014.41.6.673
1Department of Plastic and Reconstructive Surgery, Galway University Hospital, Galway, Ireland.
2Department of Anatomy, National University of Ireland, Galway, Ireland.
Correspondence: Jeffrey CY Chan. Department of Plastic and Reconstructive Surgery, Galway University Hospital, Newcastle Road, Galway, Ireland Tel: +353-91-524222, Fax: +353-91-524222, chancy@eircom.net
Received 2014 July 20; Revised 2014 September 22; Accepted 2014 September 23.

Abstract

Background

The depth of graft harvest and the residual dermis available for reepithelization primarily influence the healing of split-skin graft donor sites. When the thigh region is chosen, the authors hypothesize based on thickness measurements that the anterolateral region is the optimal donor site.

Methods

Full-thickness skin specimens were sampled from the anteromedial, anterior, and anterolateral regions of human cadavers. Skin specimens were cut perpendicularly with a custom-made precision apparatus to avoid the overestimation of thickness measurements. The combined epidermal and dermal thicknesses (overall skin thickness) were measured using a digital calliper. The specimens were histologically stained to visualize their basement membrane, and microscopy images were captured. Since the epidermal thickness varies across the specimen, a stereological method was used to eliminate observer bias.

Results

Epidermal thickness represented 2.5% to 9.9% of the overall skin thickness. There was a significant difference in epidermal thickness from one region to another (P<0.05). The anterolateral thigh region had the most consistent and highest mean epidermal thickness (60±3.2 µm). We observed that overall skin thickness increased laterally from the anteromedial region to the anterior and anterolateral regions of the thigh. The overall skin thickness measured 1,032±435 µm in the anteromedial region compared to 1,220±257 µm in the anterolateral region.

Conclusions

Based on skin thickness measurements, the anterolateral thigh had the thickest epidermal and dermal layers. We suggest that the anterolateral thigh region is the optimal donor site for split-skin graft harvests from the thigh.

INTRODUCTION

Split-skin grafts can be harvested from any part of the body using a hand-held or power-driven dermatome. A split-skin graft provides a simple method of wound closure when primary closure is not possible or healing by secondary intention is undesired or prolonged. Common donor sites include the lumbar region, buttock, thigh, and arm. The ideal donor site characteristics are highlighted in Table 1. In clinical practice, when the defect size is small to moderate, the thigh is frequently chosen as the donor site of choice because: 1) it has the largest surface area of any limb, 2) its location provides easy access and setup for graft harvesting when the patient is in a supine position, 3) its firm underlying structures provide a stable platform for the dermatome, and 4) the resultant scar is usually minimal and can be easily hidden under clothing.

Characteristics of the ideal donor site for split-thickness skin grafts

However, delayed donor site healing is a frequently encountered complication. Cosmetically unacceptable hypertrophic scarring and pigmentation changes have also been described [1,2]. Consequently, numerous studies have attempted to determine which dressing is optimal to expedite donor site healing. Although some studies have recommended specific dressings [3,4], others have reported no difference in healing times [5,6]. Interestingly, Giele et al. [7] observed no difference between the commonly used calcium alginate dressings and adhesive retention dressings [8]. Grafting the donor site to accelerate healing has been recommended [9], while some advocate the scalp as the donor site of choice [10,11]. The scalp has been shown to heal more quickly than other areas but the head must be shaved [10]. However, complications such as folliculitis, alopecia, and blood loss can occur on the scalp [10,12]. Nevertheless, it has been suggested that the rich blood supply and thick dermis of the scalp lead to rapid healing, independent of the type of dressings used.

The dermis does not regenerate once it is harvested. The epidermal layer, however, reepithelizes through the migration of epidermal cells originating from hair follicles and adnexal structures within the dermis [13]. Hence, donor site healing is primarily influenced by the depth of the graft harvest, which consequently determines the thickness of the residual dermis available for reepithelization. For this reason, it would be intuitive to opt for a donor site with the thickest dermis whenever possible to prevent visible scarring and preserve as much of the remaining dermal layer as possible.

Since the thigh is routinely used as the preferred donor site, we aimed to establish the optimal region of the thigh for harvesting split-thickness skin grafts. Anecdotal evidence suggests that the anterolateral aspect of the thigh has thicker skin than that in the anteromedial aspect. To our knowledge, no published literature has confirmed this assumption. We hypothesized that the anterolateral thigh region is the optimal donor site based on thickness measurements. Therefore, we aimed to assess variations in skin thickness from the anteromedial, anterior, and anterolateral regions of the thigh and their corresponding epidermal thickness in a cadaveric study. To measure true skin thickness, we designed a novel precision equipment for sectioning skin specimens and applied an unbiased stereological method to determine skin thickness.

METHODS

Full thickness skin specimens were sampled from the anteromedial, anterior, and anterolateral regions of the thigh of formaldehyde-fixed human cadavers (n=6) from the Department of Anatomy. Unsystematically sectioning the skin specimens introduces inaccuracy in the measured thickness of the specimen. However, slicing the skin specimens accurately at right angles avoids overestimating the thickness during sampling (Fig. 1). To ensure that the true epidermal and dermal thicknesses were sampled, a custom-made precision apparatus was designed and used in this study.

Fig. 1

Micrograph of stained skin specimens

Micrograph demonstrating that unsystematically sectioning the skin specimens at various angles (yellow arrows) introduces inaccuracy into the thickness measurement. Slicing the skin specimens accurately at right angles (red arrows) avoids overestimating the thickness during sampling.

This apparatus consists of a plastic base component and a metal top component that can be secured together (Fig. 2A). The skin specimen is placed between the two components and securely locked. The metal component is designed to incorporate parallel slits where scalpel blades can pass at right angles to section the specimen (Fig. 2B). These slits were set at widths of 1 mm, 2 mm, or 3 mm.

Fig. 2

Custom made skin-sectioning apparatus

(A) A skin specimen is placed between the plastic base component and the metal top component of a custom-made precision instrument that has predetermined slit thicknesses to allow skin sectioning at a right angle with a scalpel. (B) A 1-mm thick piece of cadaveric skin sectioned at a right angle was obtained.

The combined epidermal and dermal thicknesses were measured using a standard digital calliper. Sectioned skin samples were stained with a dilute solution of haematoxylin and toluidine blue (Fig. 3A). Microscopic images were captured with a digital camera at 10× magnification (Leica Camera AG, Wetzlar, Germany) (Fig. 3B). Subsequently, the epidermal thickness was determined by employing a stereological method as described by Jensen et al. [14] to overcome observer and measurement bias.

Fig. 3

Sections stained with haematoxylin and toluidine blue

(A) Images of stained skin sections were captured using a microscope mounted with a digital camera at 10× magnification. (B) Note the variable position of the basement membrane, which results in a variable epidermal thickness.

Briefly, a standard grid of 21×11 points was transposed onto each digital image of the skin section (Fig. 4A) using image analysis software (ImageJ version 1.43, National Institutes of Health, Bethesda, MD, USA). All points where the grid points coincided with the basement membrane on the image were noted. Since the epidermal thickness is variable across the section of skin, the grid provided random points on the image where epidermal thickness can be measured. The epidermal thickness was measured perpendicular to the surface of the epidermis at these pre-determined random points (Fig. 4B). At least six images were taken from each skin section and at least five sections were obtained from each region of each cadaver.

Fig. 4

Stereology method to overcome observer bias

(A) A uniform grid was transposed on the image (red crosses) and any points that coincided with the basement membrane (highlighted with white crosses) were noted for measurements. (B) The epidermal thicknesses were measured perpendicular to the surface of the epidermis using image analysis software (highlighted with white arrows).

The measurements were entered into a Microsoft Excel spread sheet (Microsoft Co., Redmond, WA, USA) and statistical analyses were performed using GraphPad InStat version 3 for Macintosh (GraphPad Software Inc., San Diego, CA, USA). We utilized one-way analysis of variance to test the differences in thickness measurements among the regions and subjects. Statistical significance was set at P<0.05.

RESULTS

Epidermal thickness

We found a statistically significant difference in epidermal thickness measurements between subjects (P<0.05). Epidermal thickness represented 2.5% to 9.9% of the overall skin thickness.

In addition, when different regions of the thigh were compared, there was a significant difference in epidermal thickness between regions (P<0.05). The anterolateral thigh region had the highest mean epidermal thickness and the most consistent epidermal thickness (60±3.2 µm) between subjects (Table 2).

Comparison of skin thicknesses for each region

Overall skin thickness

Similarly, there was a statistically significant difference in overall skin thickness between subjects (P<0.05). The overall skin thickness was measured as 1,032±435 µm in the anteromedial region compared to 1,220±257 µm in the anterolateral region (Table 2).

In five of the six subjects, there were statistically significant differences in skin thickness measurements (P<0.05) when different regions of the thigh were compared. Overall skin thickness increased as we moved laterally from the anteromedial region of the thigh to the anterior and anterolateral regions (Fig. 5).

Fig. 5

Overall skin thickness (combined epidermal and dermal)

In the majority of cases (except C6), there were statistically significant differences in skin thickness measurements (mean±standard deviation) when different regions of the thigh (anteromedial [AM], anterior [ANT] and anterolateral [AL]) were compared (P<0.05).

DISCUSSION

The choice of a split-thickness skin graft donor site can be influenced by the surgeon's preference or the patient's choice (Table 1). In addition, the defect size, technical limitations, potential morbidity, patient position, and ease of access to the donor site can also be relevant. While these considerations may be less important when resurfacing large surface areas, small- to moderate-sized wounds deserve a balanced debate about which donor site will optimize healing.

In this study, we compared the skin thickness in the anteromedial, anterior, and anterolateral aspects of the thigh, as they are the most common donor sites in clinical practice. The skin of the ventral, outer, and dorsal aspects of the thigh has been described as of intermediate thickness for the purposes of skin grafting [15]. The anterior and anterolateral aspects of the thigh are usually favoured because of their flat surfaces, while the anteromedial aspect may be preferred because of its relatively concealed location.

To optimize measurement accuracy, we developed a method to prepare skin sections using a custom-made apparatus. Random point selection using a grid was employed to eliminate observer bias when measuring epidermal thickness. Following these protocols to overcome potential sampling inaccuracy and observer bias, we found that the anterolateral thigh region was the optimal donor site. Despite subject-to-subject variation, the anterolateral thigh exhibited highest epidermal and overall skin thickness; moreover, the epidermal thickness measurements were relatively consistent across subjects.

We recognize that the number of cadavers used in this study was small and the use of fixed cadaveric skin specimens has the theoretical drawback of being susceptible to potential shrinkage. Although some controversy exists regarding the extent of shrinkage, previous published work dealing with tissue fixation can give an indication of the expected degree of tissue shrinkage. Using liver tissue, Fox et al. showed that a mere 3% of shrinkage occurred when tissue samples were fixed at room temperature, but that shrinkage was negligible when fixed at 37℃ [16]. Cutts [17] reported no significant loss in muscle length when muscle tissues were fixed in situ on the skeleton, compared with a small loss (2%) in length when fixed in isolation.

Data on the shrinkage of cutaneous tissue following tissue fixation are less conclusive. Hudson-Peacock et al. [18] demonstrated that skin specimens shrank by 31% after fixation, with most of the shrinkage (22%) occurring during the post-excision/pre-fixation phase. However, Golomb et al. [19] showed that 94% of shrinkage occurred after excision and before formalin fixation. Contrastingly, Gregory et al. [20] reported a 22% shrinkage of skin specimens with equal contributions from both post-excisional/pre-fixation shrinkage and post-fixation shrinkage, but their study size was small. Interestingly, Kerns et al. [21] reported that skin excision specimens shrunk immediately after excision due to their intrinsic contractile properties but re-expanded slightly when immersed in formalin. Another recent report by Dauendorffer et al. [22] similarly showed that shrinkage of skin specimens occurred immediately after excision but the specimens did not show significant changes following fixation. Thus, extrapolating from these reports, we could infer that the fixation-related shrinkage of skin specimens varies between 0% to a maximum of 10%. We believe that if this study were to be repeated in a clinical setting, the majority of shrinkage would occur immediately following excision, due to primary skin contraction, and before specimen preparation. Therefore, we believe that our present findings would not be markedly different from that of a study using fresh tissue.

Interestingly, a recent survey of the general female population showed a preference for posterior donor sites in the buttock, lower back, and thigh [23]. A previous study also found that the buttock was the donor site of choice amongst surgeons if they were to undergo skin grafting themselves [24]. In paediatric patients with burns, although there were no differences one year after grafting, posterior donor sites had a better cosmetic appearance compared to thigh donor sites at one year after grafting or earlier [25]. Future studies including the buttock, lower back, and the posterior thigh should be carried out to evaluate skin thickness at these sites. Furthermore, measurements of freshly frozen cadaveric tissues or clinical specimens could be performed to confirm our observations.

Our cadaveric study confirms that the anterolateral thigh is the optimal site for harvesting split-thickness skin grafts. Based on skin thickness measurements, the anterolateral thigh has the thickest epidermal and dermal layers. We suggest that the anterolateral thigh region should be the donor site of choice for split-skin graft harvests from the thigh.

Notes

The authors acknowledge Mr. John Fury, Senior Anatomy Technician from the Department of Anatomy, National University of Ireland, Galway for his kind support and assistance throughout this study. The authors also acknowledge the donors to the School of Medicine (Department of Anatomy), National University of Ireland, Galway for making this study possible.

No potential conflict of interest relevant to this article was reported.

References

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Article information Continued

Fig. 1

Micrograph of stained skin specimens

Micrograph demonstrating that unsystematically sectioning the skin specimens at various angles (yellow arrows) introduces inaccuracy into the thickness measurement. Slicing the skin specimens accurately at right angles (red arrows) avoids overestimating the thickness during sampling.

Fig. 2

Custom made skin-sectioning apparatus

(A) A skin specimen is placed between the plastic base component and the metal top component of a custom-made precision instrument that has predetermined slit thicknesses to allow skin sectioning at a right angle with a scalpel. (B) A 1-mm thick piece of cadaveric skin sectioned at a right angle was obtained.

Fig. 3

Sections stained with haematoxylin and toluidine blue

(A) Images of stained skin sections were captured using a microscope mounted with a digital camera at 10× magnification. (B) Note the variable position of the basement membrane, which results in a variable epidermal thickness.

Fig. 4

Stereology method to overcome observer bias

(A) A uniform grid was transposed on the image (red crosses) and any points that coincided with the basement membrane (highlighted with white crosses) were noted for measurements. (B) The epidermal thicknesses were measured perpendicular to the surface of the epidermis using image analysis software (highlighted with white arrows).

Fig. 5

Overall skin thickness (combined epidermal and dermal)

In the majority of cases (except C6), there were statistically significant differences in skin thickness measurements (mean±standard deviation) when different regions of the thigh (anteromedial [AM], anterior [ANT] and anterolateral [AL]) were compared (P<0.05).

Table 1.

Characteristics of the ideal donor site for split-thickness skin grafts

Characteristics
Ease of access during surgery
Ease of preparation
Ease of harvesting
Minimal bleeding
Minimal pain
Uncomplicated postoperative care
Low risk of infection
Rapid healing
Minimal scarring or pigmentation changes
Minimal disturbance with rehabilitation

Table 2.

Comparison of skin thicknesses for each region

Characteristic Overall skin thickness (epidermal and dermal) Epidermal thickness Comparison of epidermal thickness
Anteromedial 1,032 ± 435 55 ± 12.5 P < 0.05
Anterior 1,063 ± 301 57 ± 9.4 P < 0.05
Anterolateral 1,220 ± 257 60 ± 3.2 Not significant

Values are presented as mean (μm)±standard deviation.