Chapter 1
Anatomy and Physiology of the Skin

The skin or integumentary system functions as an important shield for the body, ensuring its survival using a range of protective mechanisms. Without skin and its protective mechanisms, the human being would not survive. The skin’s constant visibility allows it to reflect both our emotional and physiological states, such as blushing or cyanosis (Stephens 2021). Given its constant exposure, the skin is highly prone to diseases and infections, despite its near-complete waterproof nature.

Skin

Homeostasis

The skin has a multifaceted role in maintaining homeostasis and safeguarding overall health. Homeostasis refers to the body’s ability to maintain stability and balance amidst changing external and internal conditions (Evans 2022). Within the context of the skin, homeostasis manifests in various ways, notably in regulating body temperature. The body is constantly striving to keep its internal environment within a narrow range that is conducive to optimal function. When exposed to heat, such as on a hot day, the skin carefully works to dissipate excess heat through mechanisms such as sweating, thereby preventing overheating and maintaining equilibrium.

The skin appendages are specialised structures derived from the skin itself, each serving a unique purpose. They are integral to the skin’s function. Hair follicles, sweat glands and sebaceous glands are among the significant appendages, each contributing to the skin’s protective and regulatory functions. Sweat glands, for example, act as a coolant, secreting sweat to cool the body during physical exertion or exposure to high temperatures.

An adult possesses a skin surface area ranging from 1.5 to 2 m2, weighing roughly 4.1 kg, which surpasses the weight of the brain twofold. Within this vast expanse, an intricate network thrives. There are approximately 4.5 million blood vessels, 3.6 million nerves, 2.6 million sweat glands, 1500 sensory receptors and over 3 million cells undergoing continuous turnover (Peate 2020). Notably, the skin commands a significant portion of the body’s circulatory resources, receiving nearly one-third of the total blood flow (McLaughlin 2018).

Moving away from the numbers associated with the skin, the profound influence of the skin on human health and well-being is important. Much like the bricks and mortar of a sturdy house, the skin forms a resilient framework that shields the body from external attacks. The skin fends off environmental hazards and microbial invaders. Its protective competence reaches beyond mere physical barriers, incorporating complex immune mechanisms that safeguard against the harmful effects of pathogens and foreign substances.

The importance of the skin extends beyond safeguarding the body; it serves as a hub of sensory experiences, facilitating tactile sensations and emotional expressions. The delight of a gentle touch and the comfort of an affectionate hug are all facilitated by the skin’s intricate array of receptors. The skin has the ability to allow a person to experience pleasure, pain and other stimuli from the external environment (Peate 2019).

Any disruption in the skin’s integrity can bring on a cascade of physical and psychological repercussions, highlighting its indispensable role in preserving quality of life. Whether it is a minor cut or a long-standing skin condition, the repercussions extend well beyond the skin’s surface, impacting our overall well-being.

The skin transcends its superficial appearance; it represents a remarkable feat of biological engineering, intricately integrated into the essence of human existence. Exploring the skin’s intricacies further, our appreciation for this steadfast protector grows, as it diligently maintains the body’s well-being amid life’s constant flux. As we delve deeper into its complexities, we develop a heightened admiration for the skin’s resilience as it preserves the body’s integrity among life’s ever-changing circumstances.

The skin is one of the body’s most adaptable organs, comprised of two primary layers: the epidermis and the dermis. Beneath the dermis lies the subcutaneous fascia, also known as the hypodermis. This layer, consisting of loose connective and adipose tissue, attaches to the skin and underlying organs; however, it is distinct from the skin itself (see Figure 1.1).

Figure 1.1 The skin and associated structures

Epidermis

The outermost layer of the skin is known as the epidermis. It is both superficial and thin, making it the most visible part of the skin. Although the skin envelops the entire body, there are notable regional differences that are associated with flexibility, hair distribution and type, gland density and type, pigmentation, vascularity, innervation and thickness. The thinnest section of skin, for example, is found on the eyelids. This measures just 0.5 mm in thickness, while the thickest aspect is found at the heel, where it reaches 4.0 mm. The epidermis is made up of epithelium called keratinised stratified squamous epithelium and contains four key cell types. These are:

1. Keratinocytes
2. Melanocytes
3. Langerhans cells
4. Merkel cells.

See Figure 1.2.

Figure 1.2 (a–d). The types of cells in the epidermis

Keratinocytes

Arranged into four layers, these cells play a vital role in synthesising keratin, a durable, fibrous protein that is necessary for shielding the skin and underlying tissues from heat, microorganisms and chemicals. Additionally, the keratinocytes contribute to the skin’s water-resistant qualities, serving as a protective barrier that minimises both water ingress and egress. Furthermore, these cells function as a sealant, preventing the infiltration of foreign substances.

Melanocytes

During embryonic development, melanocytes produce the pigment melanin, which contributes to the natural colouration of the skin. Melanocytes are most abundant in specific areas of the epidermis, such as the penis, nipples, areola, face and limbs. These cells feature elongated projections that interweave with keratinocytes, facilitating the transfer of melanin granules. Melanin serves a crucial role in shielding the skin from the harmful effects of sunlight.

Exposure to excessive sunlight prompts melanocytes to increase melanin production, absorbing more ultraviolet (UV) rays. Consequently, the skin darkens, resulting in a suntanned appearance – an indication of the skin’s attempt to protect itself from damage. Although all individuals possess a similar number of melanocytes, those with brown or black skin produce more melanin, accounting for variations in skin colour. This increased melanin production and distribution provides greater natural protection against harmful UV radiation from the sun. Moles, also known as naevi, are clusters of melanocytes closely situated together. Figure 1.3 illustrates variations in skin colour and sensitivity to UV-induced burning.

Figure 1.3 Skin colour and sensitivity to ultraviolet (UV)-induced burning

Langerhans Cells

Langerhans cells are integral to the immune system, originating from the red bone marrow. After migrating from the bone marrow to the epidermis, they constitute a small portion of epidermal cells. These cells play a crucial role in regulating immune responses within the skin, serving as a defence against invading microorganisms. However, when exposed to sunlight, the Langerhans cells become delicate, impacting their function. Primarily, Langerhans cells are responsible for processing microbial antigens, which aids in stimulating lymphocytes. Their primary function is to support other immune cells in identifying and responding to microorganisms, ultimately facilitating the destruction of invading pathogens.

Merkel Cells

Merkel cells possess the capacity to establish contact with a flattened process of a sensory neurone, forming a synaptic connection known as a tactile disc or Merkel disc. These Merkel cells, along with the tactile discs, are not very common in the epidermis but are highly skilled at detecting sensations of touch. These cells, along with the tactile discs, which are the least abundant cells in the epidermis, are adept at detecting sensations of touch.

Layers of the Epidermis

Similar to the two distinct layers of skin, the dermis and epidermis, there are several other layers. These layers gradually form over time and comprise the epidermis. Known as strata, these layers are observable under a microscope (see Figure 1.4).

Figure 1.4 The layers of the epidermis

The superficial and deeper levels of the skin are:

• The stratum basale
• The stratum spinosum
• The stratum granulosum
• The stratum lucidum
• The stratum corneum.

Table 1.1 summarises the layers of the epidermis.

Table 1.1 Layers of the epidermis