A hair follicle is a tiny skin structure that produces and anchors a hair. It contains the hair root and interacts with oil glands, nerves, and small blood vessels. In cosmetic and plastic care, the hair follicle is central to hair restoration and hair removal procedures. It is also relevant in reconstructive settings where hair-bearing skin helps restore natural appearance.
An apocrine gland is a type of sweat gland found in specific body areas, most notably the underarms and groin. It releases a thicker secretion into hair follicles that can contribute to body odor after skin bacteria break it down. In cosmetic and plastic settings, apocrine gland concerns are most often discussed in relation to underarm odor, sweating patterns, and scar-minimizing treatment options. In reconstructive care, apocrine gland–bearing skin can be relevant when planning excisions and closures in high-friction regions.
An eccrine gland is a sweat-producing gland found in the skin. It helps cool the body by releasing watery sweat onto the skin surface. It is most dense on the palms, soles, forehead, and underarms. It is clinically relevant in both cosmetic care (sweating control) and reconstructive surgery (skin function after repair).
sebum is an oily, lipid-rich substance made by sebaceous glands in the skin. It helps lubricate and protect the skin surface and hair. In cosmetic care, sebum is often discussed because it affects shine, pores, and acne. In clinical care (including peri-procedural skincare), sebum matters because it influences the skin barrier and how products sit on the skin.
A sebaceous gland is a tiny oil-producing gland in the skin. It usually sits next to a hair follicle and releases sebum (skin oil) onto the skin surface. It is clinically important in both cosmetic dermatology and plastic surgery because it affects oiliness, pores, and certain benign growths. It can also be relevant in reconstructive planning when surgeons consider skin quality, thickness, and surface texture.
The extracellular matrix is the natural “support framework” that surrounds cells in tissues like skin, fat, and muscle. It is made of proteins and structural molecules that help tissues hold shape and heal after injury. In clinical care, extracellular matrix–based materials are processed into implants or dressings that act as a scaffold for repair. It is used in both cosmetic and reconstructive surgery, especially where soft-tissue support or coverage is needed.
A glycosaminoglycan is a long-chain sugar molecule found naturally in human connective tissues. It helps hold water and supports the structure and “cushioning” of skin, cartilage, and other soft tissues. In cosmetic and plastic settings, glycosaminoglycan-based materials are most commonly discussed in relation to hyaluronic acid products. They are used in both cosmetic care (appearance-focused) and reconstructive care (function and tissue repair).
hyaluronic acid is a naturally occurring sugar-based molecule found in skin, joints, and connective tissue. It helps tissues retain water and contributes to lubrication and cushioning. In cosmetic and plastic medicine, it is commonly used as an injectable dermal filler and in some skin-care formulations. In reconstructive and other clinical settings, it is also used in ophthalmology, orthopedics, and wound-care materials.
Elastin is a structural protein in connective tissue that helps skin and other organs stretch and recoil. In skin, elastin fibers work alongside collagen to support firmness and elasticity. In cosmetic and plastic surgery, elastin is a key concept when discussing skin laxity, aging, and scar quality. It is relevant in both cosmetic care (appearance-focused) and reconstructive care (function and tissue repair).
collagen is the body’s main structural protein in skin, tendons, ligaments, cartilage, and bone. It provides strength and a “scaffold” that helps tissues keep shape and resilience. In aesthetic medicine, collagen is discussed in skin aging, scar behavior, and some injectable or topical products. In reconstructive care, collagen-based materials may be used for wound support or tissue repair.
A fibroblast is a common connective-tissue cell found throughout the body, especially in skin and soft tissue. It helps build and maintain the extracellular matrix (the “scaffold” around cells), including collagen and elastin-related structures. It is central to wound healing and scar formation after surgery, injury, or inflammation. In cosmetic and reconstructive care, clinicians often aim to protect, modulate, or stimulate fibroblast activity to improve tissue quality and healing.
A Merkel cell is a specialized cell in the skin involved in fine touch sensation. It sits near nerve endings, mainly in the basal layer of the epidermis and around hair follicles. In clinical care, it is most commonly discussed in dermatopathology because of Merkel cell carcinoma. It can also be relevant in reconstructive surgery discussions about skin sensation after repair.
Langerhans cell is a specialized immune cell found mainly in the outer skin (epidermis) and some mucosal surfaces. It helps the body detect external substances and coordinate immune responses in the skin. In cosmetic and plastic settings, it is discussed when explaining inflammation, allergic reactions, wound healing, and skin-device interactions. It is relevant to both cosmetic and reconstructive care because skin integrity and immune balance affect many procedures.
A melanocyte is a specialized skin cell that produces melanin, the pigment that contributes to skin, hair, and eye color. melanocyte activity helps determine how skin responds to sun exposure, including tanning and some types of discoloration. In cosmetic and plastic medicine, melanocyte-related care is discussed in hyperpigmentation, hypopigmentation, and scar color matching. It is relevant to both cosmetic concerns (uneven tone) and reconstructive goals (repigmentation after injury or disease).
A keratinocyte is the main type of cell in the outer layer of skin (the epidermis). It produces keratin, a structural protein that helps form the skin’s protective barrier. In clinical care, keratinocyte-based methods are used in both reconstructive and, indirectly, cosmetic dermatology. It is also a key cell type studied in wound healing, scarring, pigmentation, and skin resurfacing.
The basement membrane is a thin, supportive layer of extracellular matrix that sits between an epithelium (like the epidermis) and the tissue beneath it. It acts as a structural “interface” that helps cells attach, organize, and communicate with underlying connective tissue. In skin, it is part of the dermal–epidermal junction and plays a central role in barrier integrity and wound healing. It matters in both cosmetic and reconstructive care because many procedures and scars involve how skin layers separate, heal, and remodel.
The stratum basale is the deepest layer of the epidermis (the outer skin layer). It contains actively dividing cells that help renew the skin surface over time. It also includes melanocytes, which contribute to skin pigment and respond to injury and light. In cosmetic and reconstructive medicine, it is commonly referenced when planning resurfacing, pigment-focused treatments, and wound-healing strategies.
The stratum spinosum is a living layer of the epidermis (the outer skin covering) located just beneath the stratum granulosum and above the stratum basale. It is made mostly of keratinocytes linked together by strong cell-to-cell connections, giving a “spiny” look under the microscope. Clinicians reference the stratum spinosum in both cosmetic and reconstructive settings to describe skin depth, healing behavior, and biopsy findings. It is not a procedure or product, but an anatomical layer that many treatments interact with.
The stratum granulosum is a thin layer of the epidermis (the outer part of the skin). It sits between the stratum spinosum and the stratum corneum and helps form the skin barrier. It is most often discussed in dermatology, cosmetic skin resurfacing, and reconstructive wound healing. In cosmetic and plastic care, it matters because it influences texture, hydration, and how skin recovers after procedures.
The stratum corneum is the outermost layer of the epidermis (the surface part of the skin). It is made of flattened, dead skin cells (corneocytes) held together by skin lipids, forming a barrier. It helps keep water in and irritants, microbes, and allergens out. In cosmetic and reconstructive care, it matters because many treatments work by interacting with or passing through this layer.