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Human biology
Human biology
Human biology
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Human biology is an interdisciplinary area of academic study that examines humans through the influences and interplay of many diverse fields such as genetics, evolution, physiology, anatomy, epidemiology, anthropology, ecology, nutrition, population genetics, and sociocultural influences.[1][2] It is closely related to the biomedical sciences, biological anthropology and other biological fields tying in various aspects of human functionality. It wasn't until the 20th century when biogerontologist, Raymond Pearl, founder of the journal Human Biology, phrased the term "human biology" in a way to describe a separate subsection apart from biology.[3]

It is also a portmanteau term that describes all biological aspects of the human body, typically using the human body as a type organism for Mammalia, and in that context it is the basis for many undergraduate University degrees and modules.[4][5]

Most aspects of human biology are identical or very similar to general mammalian biology. In particular, and as examples, humans :

History

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The study of integrated human biology started in the 1920s, sparked by Charles Darwin's theories which were re-conceptualized by many scientists. Human attributes, such as child growth and genetics, were put into question and thus human biology was created.

Typical human attributes

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The key aspects of human biology are those ways in which humans are substantially different from other mammals.[6]

Humans have a very large brain in a head that is very large for the size of the animal. This large brain has enabled a range of unique attributes including the development of complex languages and the ability to make and use a complex range of tools.[7][8]

The upright stance and bipedal locomotion is not unique to humans but humans are the only species to rely almost exclusively on this mode of locomotion.[9] This has resulted in significant changes in the structure of the skeleton including the articulation of the pelvis and the femur and in the articulation of the head.

In comparison with most other mammals, humans are very long lived[10] with an average age at death in the developed world of nearly 80 years old.[11] Humans also have the longest childhood of any mammal with sexual maturity taking 12 to 16 years on average to be completed.

Humans lack fur. Although there is a residual covering of fine hair, which may be more developed in some people, and localised hair covering on the head, axillary and pubic regions, in terms of protection from cold, humans are almost naked. The reason for this development is still much debated.

The human eye can see objects in colour but is not well adapted to low light conditions. The sense of smell and of taste are present but are relatively inferior to a wide range of other mammals. Human hearing is efficient but lacks the acuity of some other mammals. Similarly human sense of touch is well developed especially in the hands where dextrous tasks are performed but the sensitivity is still significantly less than in other animals, particularly those equipped with sensory bristles such as cats.

Scientific investigation

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Human biology tries to understand and promotes research on humans as living beings as a scientific discipline. It makes use of various scientific methods, such as experiments and observations, to detail the biochemical and biophysical foundations of human life describe and formulate the underlying processes using models. As a basic science, it provides the knowledge base for medicine. A number of sub-disciplines include anatomy, cytology, histology and morphology.

Medicine

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The capabilities of the human brain and the human dexterity in making and using tools, has enabled humans to understand their own biology through scientific experiment, including dissection, autopsy, prophylactic medicine which has, in turn, enable humans to extend their life-span by understanding and mitigating the effects of diseases.

Understanding human biology has enabled and fostered a wider understanding of mammalian biology and by extension, the biology of all living organisms.

Nutrition

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Main article: Human nutrition

Human nutrition is typical of mammalian omnivorous nutrition requiring a balanced input of carbohydrates, fats, proteins, vitamins, and minerals. However, the human diet has a few very specific requirements. These include two specific amino acids, alpha-linolenic acid and linoleic acid without which life is not sustainable in the medium to long term. All other fatty acids can be synthesized from dietary fats. Similarly, human life requires a range of vitamins to be present in food and if these are missing or are supplied at unacceptably low levels, metabolic disorders result which can end in death. The human metabolism is similar to most other mammals except for the need to have an intake of Vitamin C to prevent scurvy and other deficiency diseases. Unusually amongst mammals, a human can synthesize Vitamin D3 using natural UV light from the sun on the skin. This capability may be widespread in the mammalian world but few other mammals share the almost naked skin of humans. The darker the human's skin, the less it can manufacture Vitamin D3.

Other organisms

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Human biology also encompasses all those organisms that live on or in the human body. Such organisms range from parasitic insects such as fleas and ticks, parasitic helminths such as liver flukes through to bacterial and viral pathogens. Many of the organisms associated with human biology are the specialised biome in the large intestine and the biotic flora of the skin and pharyngeal and nasal region. Many of these biotic assemblages help protect humans from harm and assist in digestion, and are now known to have complex effects on mood, and well-being.

Social behaviour

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Humans in all civilizations are social animals and use their language skills and tool making skills to communicate.

These communication skills enable civilizations to grow and allow for the production of art, literature and music, and for the development of technology. All of these are wholly dependent on the human biological specialisms.

The deployment of these skills has allowed the human race to dominate the terrestrial biome[12] to the detriment of most of the other species.

References

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Human biology

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Human biology is the of the human in its entirety, encompassing the and function of the body, genetic makeup, evolutionary origins, developmental processes, and interactions with the environment. This field integrates principles from , , , , , and to understand how humans function as biological entities and adapt to diverse conditions. At the core of human biology lies the of the body, beginning with trillions of cells that form the basic units of life, grouping into tissues of similar cell types, combining into organs with specialized functions, and ultimately forming organ systems that coordinate complex activities. The major organ systems include the skeletal system for support and protection, the for movement, the for coordination and response, the endocrine system for hormonal regulation, the cardiovascular system for circulation, the lymphatic and immune systems for defense, the for gas exchange, the digestive system for nutrient processing, the for waste elimination, and the for propagation. These systems work interdependently to maintain , the dynamic balance of internal conditions essential for survival, through mechanisms that detect and respond to environmental changes. Human physiology examines the functional processes that enable these systems to operate, such as the transport of oxygen and nutrients via the bloodstream, neural signaling for sensory perception and , and metabolic pathways that convert food into energy. within this discipline reveals how human anatomy and physiology have been shaped by over millions of years, tracing origins from apelike ancestors to modern Homo sapiens through adaptations in , brain size, and immune responses. Genetics plays a pivotal role in human biology, investigating how DNA sequences influence traits, heredity, and disease susceptibility, with the human genome comprising approximately 19,000–20,000 protein-coding genes that direct cellular functions and developmental trajectories. Developmental biology explores how these genetic instructions guide growth from embryo to adult, incorporating environmental factors that affect morphology and physiology. Overall, human biology highlights the interplay between inherited traits and ecological influences, informing advancements in medicine, public health, and biotechnology.

Historical and methodological foundations

Historical development

The study of human biology traces its origins to ancient civilizations, where early thinkers sought to understand the human body through observation and philosophical inquiry. Around 400 BCE, , often regarded as the father of Western medicine, proposed the humoral theory, positing that health resulted from a balance of four bodily fluids—, , yellow bile, and black bile—while imbalances caused disease. This framework dominated medical thought for over two millennia, shifting explanations of illness from supernatural causes to natural, physiological ones and influencing both diagnostic practices and treatments across Western and Eastern traditions. Complementing this, (384–322 BCE) advanced by dissecting animals to infer human structures, as direct human dissection was restricted; his systematic classification of organisms based on shared traits laid foundational principles for biological and emphasized teleological explanations of bodily functions. The marked a pivotal shift toward empirical , driven by renewed interest in classical texts and technological advances in . In 1543, published De humani corporis fabrica libri septem, a groundbreaking atlas based on meticulous dissections that corrected centuries-old errors in Galen's ancient descriptions, such as the number of bones and muscle attachments. 's work, featuring detailed illustrations by artists like Jan van Calcar, revolutionized anatomical education by prioritizing direct observation over textual authority, establishing modern standards for precision and visual representation in biology. This text not only transformed surgical training but also fostered a culture of and hands-on experimentation that permeated subsequent biological inquiry. The 19th century brought paradigm-shifting insights into human origins and cellular foundations, integrating evolutionary and microscopic perspectives. Charles Darwin's (1859) introduced as the mechanism driving species change, profoundly influencing studies by suggesting humans shared a common ancestry with other and challenging creationist views of biological diversity. Concurrently, in 1858, extended to human in Die Cellularpathologie, asserting that "omnis cellula e cellula" (every cell arises from a pre-existing cell) and that diseases originate from cellular alterations rather than humoral imbalances, thereby founding cellular as a cornerstone of human biology. These ideas unified with evolutionary and microscopic scales, paving the way for a holistic understanding of human development and disease. The 20th century witnessed molecular breakthroughs that redefined human biology at the genetic level. In 1953, and , building on X-ray diffraction data from and , elucidated the double-helix structure of , revealing how genetic information is stored and replicated in a twisted ladder of nucleotide base pairs. This discovery provided the molecular basis for , enabling subsequent advances in and transforming human biology from descriptive to mechanistic biochemistry. Culminating these efforts, the , an international collaboration launched in 1990, achieved a working draft sequence of the in 2000 and a completed reference sequence in 2003, mapping approximately 3 billion base pairs and identifying key genes, which accelerated research into and . The project's completion represented a monumental leap in scale, democratizing genomic data and fostering interdisciplinary approaches to human health. In 2022, the Telomere-to-Telomere (T2T) consortium published the first complete, end-to-end sequence, filling gaps in complex repetitive regions and enhancing understanding of genomic variation. Since 2010, human biology has increasingly integrated computational tools, with CRISPR-Cas9 gene editing emerging as a transformative technology. In 2012, and demonstrated CRISPR-Cas9's potential as a precise, RNA-guided system for targeted DNA modifications, adapting bacterial immune mechanisms to edit eukaryotic genomes efficiently. This innovation has enabled rapid advancements in modeling human diseases and therapeutic interventions, such as correcting genetic mutations . Paralleling this, bioinformatics has become indispensable post-2010, leveraging algorithms and big data to analyze vast genomic datasets from projects like the , thus integrating high-throughput sequencing with evolutionary and physiological models to uncover complex human traits. These developments underscore a shift toward precision biology, where computational and genetic tools converge to address longstanding questions in human variation and adaptation.

Research methods

Research in human biology relies on a variety of observational methods to study populations and physiological processes over time without direct intervention. Longitudinal studies, such as the initiated in 1948, have been instrumental in identifying risk factors for cardiovascular diseases by tracking participants across generations. Non-invasive imaging techniques, including computed tomography (CT) scans developed in the early 1970s and (MRI) introduced in the late 1970s and early 1980s, enable detailed visualization of internal structures and functions, revolutionizing the diagnosis and study of anatomical and pathological conditions. Experimental approaches in human biology encompass controlled interventions to test hypotheses about biological mechanisms. Clinical trials involve participants to evaluate the safety and efficacy of treatments, progressing through phases that ensure ethical oversight and scientific rigor. In vitro cell cultures provide a controlled environment for studying cellular behaviors, allowing researchers to manipulate variables like nutrients and drugs to mimic physiological conditions. Animal models, such as , serve as analogs for developmental biology due to their genetic similarities and transparent embryos, facilitating the observation of genetic and environmental influences on growth. At the molecular level, techniques like polymerase chain reaction (PCR), invented by Kary Mullis in 1983, enable the amplification of specific DNA segments for analysis, underpinning genetic research and diagnostics. Next-generation sequencing (NGS), emerging in the 2000s with the first commercial platforms around 2005, allows high-throughput analysis of genomes, transcriptomes, and epigenomes, accelerating discoveries in human variation and disease susceptibility. Ethical frameworks are essential to protect participants in human biology research. The Declaration of Helsinki, adopted by the in 1964, establishes principles for medical research involving human subjects, emphasizing and risk minimization. Institutional Review Boards (IRBs) oversee protocols to ensure compliance, reviewing studies for potential harms and benefits, a practice strengthened by responses to historical ethical lapses like the (1932-1972). Emerging technologies are expanding the toolkit for human biology investigations. AI-driven predictive modeling, advanced since 2020, integrates with biological data to forecast progression and drug responses, enhancing precision in . Organoids, three-dimensional cell-derived structures, offer human-specific models for simulation, replicating organ complexity to study pathologies like cancer and infections without relying on animal systems.

Cellular and molecular foundations

Cell structure and function

Human cells are the fundamental units of life, exhibiting eukaryotic characteristics that distinguish them from prokaryotic cells. Eukaryotic cells, including those in humans, contain a membrane-bound nucleus and various organelles, enabling complex compartmentalization and specialized functions, whereas prokaryotic cells lack a nucleus and are typically simpler, unicellular structures found in and . In humans, cells are broadly classified into somatic cells, which form the body's tissues and organs and are diploid (containing two sets of chromosomes), and germ cells, which are precursors to gametes ( and eggs) and undergo specialized division to produce haploid cells for . The , or plasma membrane, forms a selective barrier around the cell, composed of a bilayer with hydrophilic heads facing outward and hydrophobic tails inward, embedded with proteins that facilitate communication and transport. This structure enables mechanisms, such as simple diffusion and through channels, allowing small nonpolar molecules like oxygen to cross without energy input, while uses ATP to move ions and larger molecules against concentration gradients via pumps like the sodium-potassium pump. Within the eukaryotic cell, organelles perform essential functions; the nucleus serves as the primary site for DNA storage and gene expression control, housing the genome in chromatin organized into chromosomes. The mitochondria, often called the powerhouse of the cell, generate ATP through oxidative phosphorylation, a process involving the electron transport chain in the inner mitochondrial membrane to produce approximately 30–32 ATP molecules per glucose molecule oxidized. The endoplasmic reticulum (ER), particularly the rough ER studded with ribosomes, is crucial for protein synthesis, where nascent polypeptides are translocated into the ER lumen for folding and modification before transport to other cellular destinations. The cell cycle regulates growth and division, with enabling somatic cells to produce identical daughter cells through phases including (chromosome condensation and nuclear envelope breakdown), (chromosomes align at the equator), (sister chromatids separate), and (nuclear envelopes reform around daughter nuclei), followed by . In contrast, occurs in germ cells to form gametes, involving two divisions that reduce chromosome number by half, introducing genetic variation through crossing over and independent assortment. Stem cells play a key role in development and regeneration, with totipotent stem cells, such as the , capable of differentiating into all cell types including extraembryonic tissues, and pluripotent stem cells, like embryonic stem cells, able to form any of the three germ layers (, , ) but not extraembryonic structures. These cells contribute to tissue repair and regeneration, for instance, hematopoietic stem cells replenishing cells throughout life, highlighting their potential in therapeutic applications.

Molecular biology and biochemistry

Molecular biology and biochemistry form the chemical foundation of human life, encompassing the study of biomolecules, enzymatic reactions, metabolic pathways, and processes like protein synthesis that underpin cellular function. In humans, these elements enable the storage, transmission, and utilization of genetic information, energy production, and structural integrity. Key biomolecules include nucleic acids, proteins, carbohydrates, and , each with distinct structures and roles in maintaining physiological balance. Nucleic acids are essential for genetic information storage and expression. Deoxyribonucleic acid (DNA) consists of two helical chains coiled around a common axis, forming a double helix structure, where adenine (A) pairs with thymine (T) and guanine (G) pairs with cytosine (C) through hydrogen bonds, ensuring the faithful replication and transmission of genetic data. Ribonucleic acid (RNA) exists in several forms: messenger RNA (mRNA) carries genetic instructions from DNA to ribosomes for protein synthesis; transfer RNA (tRNA) delivers amino acids to the ribosome during translation; and ribosomal RNA (rRNA) forms the core of ribosomes, catalyzing peptide bond formation and comprising 80-90% of cellular RNA. Proteins, composed of amino acid chains, exhibit four levels of structural organization critical to their function. The primary structure is the linear sequence of amino acids linked by peptide bonds, determining the protein's identity and stability, often including disulfide bonds between cysteine residues. The secondary structure involves local folding patterns such as α-helices (right-handed coils with 3.6 residues per turn) and β-sheets (parallel or antiparallel strands), stabilized by hydrogen bonds between backbone atoms. The tertiary structure represents the overall three-dimensional folding of a single polypeptide, driven by hydrophobic interactions, hydrogen bonds, and side-chain attractions, enabling functional shapes like enzyme active sites. The quaternary structure assembles multiple polypeptide subunits into a complex, as in hemoglobin's tetrameric form, stabilized by non-covalent interactions. Carbohydrates serve as primary energy sources and structural components in human biology, classified by complexity. Monosaccharides, the simplest units with the formula C₆H₁₂O₆, include glucose, , and , providing rapid energy via breakdown. Disaccharides, formed by linking two monosaccharides (e.g., from glucose and ), yield energy upon . Polysaccharides are long chains of monosaccharides connected by glycosidic bonds; and store energy in plants and animals, respectively, while and provide for gut health, with insoluble forms like softening stool and soluble ones like oats lowering . Lipids contribute to , formation, and signaling. Triglycerides, esters of and three s (14-24 carbons long, varying in saturation), represent the main energy reserve, providing insulation and aiding absorption of fat-soluble vitamins, transported via lipoproteins like chylomicrons. Phospholipids, amphipathic molecules with a backbone, two hydrophobic tails, and a hydrophilic head, form the bilayer structure of cell membranes, allowing selective permeability for molecules like oxygen while restricting larger polar ones such as glucose without transport proteins. Enzymes, predominantly proteins, accelerate biochemical reactions with high specificity. The lock-and-key model, proposed by , posits that the enzyme's rigidly complements the substrate's shape and charge, akin to a key fitting a lock, ensuring precise binding and before structural knowledge confirmed enzymes as proteins. are often described by the Michaelis-Menten equation: v=Vmax[S]Km+[S]v = \frac{V_{\max} [S]}{K_m + [S]} where vv is the , VmaxV_{\max} the maximum rate, [S][S] the substrate concentration, and KmK_m (the Michaelis constant) the [S][S] at half VmaxV_{\max}, reflecting enzyme-substrate affinity (lower KmK_m indicates higher affinity). This model assumes reversible enzyme-substrate complex formation, foundational to understanding reaction efficiencies. Biochemical pathways integrate these biomolecules for energy production. , occurring in the , breaks down glucose into two pyruvate molecules across 10 enzymatic steps, consuming 2 ATP in the investment phase (steps 1-5, including and ) and yielding 4 ATP plus 2 NADH in the payoff phase (steps 6-10, including glyceraldehyde-3-phosphate dehydrogenase and ), resulting in a net gain of 2 ATP per glucose. The Krebs cycle (tricarboxylic acid or TCA cycle), in the , processes through 8 steps: citrate synthesis, isomerization to isocitrate, oxidative decarboxylations yielding NADH and CO₂, succinyl-CoA cleavage producing GTP, succinate oxidation to FADH₂, fumarate hydration, and malate oxidation to NADH, generating electron carriers (3 NADH and 1 FADH₂ per ) for while releasing 2 CO₂. These pathways produce ATP, which powers cellular processes including and . Protein synthesis involves transcription and translation to convert genetic information into functional proteins. In transcription, RNA polymerase II binds promoter regions—such as the TATA box 25 nucleotides upstream of the start site in eukaryotes, recognized by transcription factors—to unwind DNA and synthesize complementary mRNA from the template strand in a 5' to 3' direction, followed by processing like 5' capping and poly-A tail addition. Translation occurs at ribosomes, ribonucleoprotein complexes of rRNA and proteins, where mRNA codons (triplet nucleotide sequences) are decoded using the genetic code: each of the 64 codons specifies one of 20 amino acids or a stop signal, with tRNA anticodons matching codons to deliver amino acids for peptide bond formation, building the polypeptide chain. This process ensures precise protein assembly, with rRNA catalyzing the reactions.

Anatomical structure

Gross anatomy

Gross anatomy encompasses the macroscopic structure of the , focusing on its overall organization into regions, systems, and supportive frameworks visible to the . This level of provides the foundational layout for understanding how the body's components are positioned and interconnected, without delving into microscopic details. The is typically described in the anatomical position—standing upright, facing forward, with arms at the sides and palms facing forward—to standardize descriptions of location and orientation. To facilitate precise descriptions, anatomists use standardized body planes that divide the body into sections for study and imaging. The sagittal plane (or median plane) divides the body into left and right halves, while parasagittal planes create unequal divisions parallel to it; the frontal plane (or coronal plane) separates anterior and posterior portions; and the transverse plane (or horizontal plane) cuts the body into superior and inferior parts. These planes are essential in medical imaging and surgical planning. The body is also organized into major cavities that house and protect internal organs: the dorsal cavity, subdivided into the cranial cavity (containing the brain) and vertebral cavity (enclosing the spinal cord), lies posterior; the ventral cavity, divided by the diaphragm into the thoracic cavity (housing the heart and lungs) and abdominopelvic cavity (further split into abdominal and pelvic regions for digestive and reproductive organs), occupies the anterior space. The skeletal system forms the rigid framework of the body, consisting of 206 bones in the typical adult, which provide support, protection, and leverage for movement. These bones are classified into the axial skeleton, comprising 80 bones including the (which encases the ), vertebral column (supporting the trunk and protecting the ), and (guarding thoracic organs); and the appendicular skeleton, with 126 bones forming the pectoral and pelvic girdles plus the upper and lower limbs for mobility and manipulation. Bone development and fusion during growth result in this adult count, though variations like sesamoid bones can occur. Complementing the skeleton, the muscular system enables movement and maintains posture through three distinct types of muscle tissue. , which is voluntary and striated, attaches to bones via tendons and numbers over 600 in the body, accounting for about 40% of body weight and facilitating locomotion and fine motor control. In contrast, smooth muscle is involuntary and non-striated, found in walls of hollow organs like blood vessels and the digestive tract for peristalsis and regulation; cardiac muscle, also involuntary and striated, forms the heart's myocardium for rhythmic contractions. These muscle types differ in structure and control but share contractile proteins like and . The serves as the body's outermost barrier, comprising the skin and its appendages: and . The skin consists of three layers: the , the outermost avascular layer of that provides a protective barrier against pathogens and UV ; the , a thicker layer of containing blood vessels, nerves, and glands for nourishment and sensation; and the hypodermis (or subcutaneous layer), composed of adipose and that anchors the skin to underlying structures and insulates the body. , produced by follicles in the , covers most of the body except palms and soles, aiding in and sensory functions; , hardened plates at digit tips, protect fingertips and aid in manipulation. Together, these components form the largest , covering approximately 2 square meters in adults. For regional organization, the body is divided into major areas to localize structures and pathologies. The head and neck house sensory organs, the brain, and major vessels; the thorax (chest) contains the heart, lungs, and great vessels within the rib cage; the abdomen accommodates digestive organs like the stomach and liver; the pelvis supports reproductive and excretory structures; and the extremities include the upper limbs (arms, forearms, hands) for reaching and grasping, and lower limbs (thighs, legs, feet) for locomotion. This topographic division aids in clinical examination and surgical approaches.

Tissue and organ systems

Human tissues are classified into four primary types based on their structure and function: epithelial, connective, muscle, and . Epithelial tissues form continuous sheets of cells that cover body surfaces, line cavities, and form glands, serving as barriers and facilitators of selective exchange. They are categorized by cell shape and layering: squamous (flat, scale-like cells), cuboidal (cube-shaped), and columnar (tall, column-like); these can be simple (single layer) for absorption and filtration, as in the lungs' alveoli, or stratified (multiple layers) for protection, as in the skin. Connective tissues support and connect other tissues, characterized by an rich in fibers and , with varied cell types like fibroblasts and macrophages. Subtypes include (areolar, with flexible and elastic fibers for cushioning organs), (regular or irregular, with tightly packed for strength in tendons and ligaments), (avascular, gel-like matrix with chondrocytes for flexible support in joints), (mineralized matrix with osteocytes for rigid support), and (fluid matrix with erythrocytes, leukocytes, and platelets for ). Muscle tissues enable movement through contraction, divided into skeletal (striated, voluntary, multinucleated fibers attached to bones), cardiac (striated, involuntary, branched fibers with intercalated discs in the heart), and smooth (non-striated, involuntary, spindle-shaped cells in vessel walls and viscera). Nervous tissue transmits signals via specialized cells, comprising neurons (with dendrites, axons, and cell bodies for impulse conduction) and neuroglia (support cells like , , and Schwann cells that insulate and nourish neurons). Major organs consist of these tissues organized into functional units. The brain, the central organ of the nervous system, features the cerebrum (outer gray matter cortex of folded gyri and sulci with neuronal layers for higher processing) and cerebellum (inner folded folia with Purkinje cells and granule cells for coordination). The heart, a muscular pump, has four chambers—two atria and two ventricles—separated by septa, with atrioventricular and semilunar valves (tricuspid, mitral, pulmonary, aortic) composed of fibrous connective tissue and endocardial lining to prevent backflow. Lungs facilitate gas exchange through branching bronchioles ending in alveolar sacs; alveoli are thin-walled sacs lined by type I pneumocytes (squamous epithelial for diffusion) and type II pneumocytes (cuboidal, producing surfactant). The liver, essential for metabolic processing, is structured into hexagonal lobules centered on a central vein, with portal triads (hepatic artery, portal vein, bile duct) at corners and plates of hepatocytes (polygonal epithelial cells) radiating outward, separated by sinusoids (lined by endothelial cells). Kidneys filter blood via nephrons, the functional units; each nephron includes a renal corpuscle (glomerulus of capillaries within Bowman's capsule) and tubules (proximal convoluted, loop of Henle, distal convoluted, collecting duct) lined by epithelial cells specialized for reabsorption and secretion. Organ specialization extends to endocrine glands, which produce hormones via epithelial-derived cells. The pituitary gland, at the base of the brain, has an anterior lobe (adenohypophysis) of glandular epithelial cells in cords and follicles secreting tropic hormones, and a posterior lobe (neurohypophysis) of nervous tissue with axonal projections storing hormones like oxytocin. The thyroid gland consists of follicles lined by cuboidal epithelial cells (thyrocytes) filled with colloid for thyroxine storage, plus parafollicular C cells for calcitonin. The digestive tract forms a continuous tube from esophagus to intestines, with layered walls: mucosa (epithelial lining on lamina propria), submucosa (connective), muscularis (smooth muscle), and serosa (mesothelium). The esophagus features stratified squamous epithelium for abrasion resistance; the stomach has simple columnar epithelium in rugae-folded pits and glands; small intestines (duodenum, jejunum, ileum) include villi and microvilli on absorptive enterocytes; large intestines feature columnar epithelium with goblet cells for mucus. Histology, the microscopic study of tissues, relies on staining techniques to visualize structures. The hematoxylin and eosin (H&E) stain is the standard, where hematoxylin binds nucleic acids in nuclei for blue-purple coloration, and stains cytoplasmic proteins and pink, enabling differentiation of cellular components across all tissue types. These methods reveal tissue architecture under light , aiding identification of epithelial layering, connective matrix density, muscle striations, and nervous myelination.

Physiological processes

Homeostasis and regulation

is the process by which the human body maintains a stable internal environment despite fluctuations in external conditions, ensuring optimal conditions for cellular function and survival. This dynamic equilibrium is achieved through integrated regulatory mechanisms involving the nervous, endocrine, and other systems, which detect deviations from set points and initiate corrective responses. Key physiological variables, such as , , glucose levels, and , are tightly controlled to prevent disruptions that could lead to disease. Central to homeostasis are feedback loops that amplify or dampen physiological changes. Negative feedback loops predominate, acting to counteract deviations and restore balance; for instance, in blood glucose regulation, elevated levels trigger pancreatic beta cells to release insulin, which promotes by cells and inhibits hepatic glucose production, thereby lowering blood sugar. Conversely, low glucose stimulates alpha cells to secrete , which raises blood sugar by promoting and in the liver. Positive feedback loops, though less common, intensify a process until a specific endpoint is reached; a classic example is the role of oxytocin during labor, where stimulate further oxytocin release from the , escalating contractions to facilitate delivery. Nervous regulation contributes to homeostasis via the autonomic nervous system, which operates largely involuntarily to modulate organ functions. The sympathetic division activates during stress or activity, increasing heart rate, dilating pupils, and redirecting blood flow to muscles via norepinephrine release, preparing the body for "fight or flight." In contrast, the parasympathetic division promotes "rest and digest" states through acetylcholine, slowing heart rate, enhancing digestion, and conserving energy. Reflex arcs provide rapid, localized responses; these neural pathways, involving sensory neurons, interneurons in the spinal cord, and motor neurons, bypass higher brain centers to maintain balance, such as in the knee-jerk reflex that adjusts posture or baroreceptor reflexes that stabilize blood pressure. Hormonal control integrates long-term regulation through the endocrine system, with the hypothalamus-pituitary axis serving as a master coordinator. The releases (CRH) in response to stress, stimulating the to secrete (ACTH), which prompts adrenal production; mobilizes energy reserves, suppresses inflammation, and restores post-stress via on the axis. This axis exemplifies how hormones fine-tune responses across multiple systems. Thermoregulation maintains core body temperature near a hypothalamic set point of approximately 37°C, balancing heat production and loss. When temperature rises, the hypothalamus activates heat-loss mechanisms like sweating, which evaporates from the skin to dissipate heat, and cutaneous to increase blood flow to the surface. In cold conditions, generates heat through rapid muscle contractions, while conserves warmth by reducing peripheral blood flow; these responses prevent hypo- or . pH balance is crucial for enzymatic activity and is maintained around 7.35–7.45 in via buffer systems, respiratory adjustments, and renal compensation. The is primary, where (H₂CO₃) dissociates into ions and (HCO₃⁻), neutralizing excess acids or bases:
\ceCO2+H2OH2CO3H++HCO3\ce{CO2 + H2O ⇌ H2CO3 ⇌ H+ + HCO3-}
This equilibrium, catalyzed by , rapidly stabilizes changes in blood and tissues. Kidneys excrete ions and reabsorb for longer-term control. Fluid balance, or osmoregulation, prevents cellular swelling or shrinkage by regulating water and levels, primarily through antidiuretic hormone (ADH, or ). Osmoreceptors in the detect increased plasma osmolality, triggering ADH release from the , which enhances water reabsorption in collecting ducts via channels, concentrating urine and diluting plasma. Thirst mechanisms complement this, prompting water intake to restore volume. Disruptions, such as , elevate ADH to maintain .

Organ system functions

The human body relies on the integrated functions of major organ systems to sustain , with each system performing specialized roles in , exchange, processing, elimination, and . These systems operate coordinately to maintain essential physiological processes, such as nutrient delivery, waste removal, and genetic propagation, through mechanisms like , enzymatic reactions, and . The circulatory system, comprising the heart, blood vessels, and blood, facilitates the transport of oxygen, nutrients, hormones, and waste products throughout the body. The heart acts as a muscular pump, propelling blood via the cardiac cycle, which consists of systole—the contraction phase that ejects blood into the arteries—and diastole—the relaxation phase that allows ventricular filling. Blood vessels include arteries, which carry oxygenated blood away from the heart under high pressure; veins, which return deoxygenated blood to the heart; and capillaries, where exchange of gases and nutrients occurs across thin walls. Oxygen transport primarily occurs through hemoglobin in red blood cells, which binds oxygen in the lungs and releases it to tissues. The respiratory system enables gas exchange and ventilation to support cellular respiration. Gas exchange in the alveoli relies on partial pressure gradients, where oxygen diffuses from higher concentration in inhaled air (about 100 mmHg) to lower in blood (about 40 mmHg), while carbon dioxide moves in the opposite direction. Ventilation involves the diaphragm's contraction to expand the thoracic cavity, drawing air into the lungs, with a typical tidal volume of approximately 500 mL per breath at rest. This process ensures continuous oxygen supply and carbon dioxide removal. The digestive system breaks down ingested food into absorbable nutrients through mechanical and chemical processes. , rhythmic contractions of in the , propels food from the through the intestines. Enzymatic begins with salivary , which hydrolyzes starches into in the , and continues in the with , which cleaves proteins into peptides under acidic conditions. The majority of absorption occurs in the , where villi and microvilli increase surface area for uptake of carbohydrates, proteins, fats, vitamins, and minerals into the bloodstream. The , primarily the kidneys, regulates fluid and balance while removing metabolic wastes via formation. begins in the glomeruli, tufts in nephrons, where is forced through a filtration barrier at a (GFR) of approximately 125 mL/min in healthy adults. formation proceeds through three steps: glomerular of , ions, and small solutes; tubular reabsorption of essential substances like glucose and most back into the ; and secretion of additional wastes into the filtrate, resulting in concentrated excreted by the . The ensures species continuity through production and fertilization. In males, occurs in the seminiferous tubules of the testes, where diploid spermatogonia undergo to produce haploid spermatozoa, a process that begins at and continues throughout life. In females, takes place in the ovaries, producing one mature ovum per cycle from oogonia via , arrested until . The , averaging 28 days, includes the (days 1–14), dominated by for endometrial proliferation; around day 14, releasing the ovum; and the (days 15–28), where progesterone prepares the for implantation, followed by if no fertilization occurs.

Genetics and heredity

Human genome

The human genome consists of the complete set of genetic material in humans, primarily comprising deoxyribonucleic acid (DNA) organized into chromosomes within the nucleus of cells. It contains approximately 3.055 billion base pairs in a haploid reference sequence, encompassing both coding and non-coding regions that encode instructions for biological development and function. This genetic material includes an estimated 19,000–20,000 protein-coding genes, which represent about 1-2% of the total genome and direct the synthesis of proteins essential for cellular processes. The genome's vast non-coding portions play critical roles in regulation, structural integrity, and evolutionary adaptability. Humans possess 46 chromosomes arranged in 23 pairs, with 22 pairs of autosomes and one pair of sex chromosomes (XX in females and XY in males). Karyotype analysis, a technique visualizing these chromosomes under a microscope after staining, reveals their characteristic sizes, shapes, and banding patterns, aiding in the detection of structural abnormalities. Each chromosome is a linear DNA molecule associated with proteins, forming chromatin that compacts the genome to fit within the cell nucleus while allowing access for replication and transcription. During cellular DNA replication, the genome is duplicated semiconservatively to ensure genetic continuity in daughter cells. Individual genes within the typically consist of coding sequences known as exons interspersed with non-coding introns, which are removed during to produce (mRNA). Promoters, located upstream of , serve as binding sites for and transcription factors to initiate transcription, while enhancers—distal regulatory elements—can loop to interact with promoters, modulating in a tissue-specific manner through open and marks like H3K27ac. These structural and regulatory features enable precise control over activity, with of exons further diversifying protein isoforms from a single . Epigenetic modifications overlay the genomic sequence to influence without altering the DNA bases themselves. , primarily at residues in CpG dinucleotides, typically represses transcription by compacting and inhibiting binding. modifications, such as acetylation and methylation on histone tails, alter structure to either promote or inhibit access to DNA; for instance, H3K4 methylation activates genes, while H3K27 methylation silences them. These dynamic marks, interconnected with , respond to environmental cues and developmental signals, contributing to and disease susceptibility. Key milestones in human genome sequencing began with the development of the in 1977, which enabled efficient reading of DNA sequences up to several hundred bases. The (HGP), launched in 1990, achieved a draft sequence by 2001 and a complete reference by 2003 through international collaboration using , marking a foundational advance in . In 2022, the Telomere-to-Telomere Consortium achieved the first complete, gap-free sequence of a (T2T-CHM13), filling long-unresolved regions such as centromeres and telomeres. Subsequent next-generation sequencing technologies dramatically reduced costs; as of 2025, whole-genome sequencing costs approximately $200–$500 per genome, facilitating widespread clinical and research applications.

Inheritance patterns

Inheritance patterns in human biology describe the mechanisms by which genetic traits are passed from parents to offspring, primarily through the transmission of alleles on chromosomes. These patterns follow principles established by and extended by modern , encompassing both simple and complex forms of trait expression. Understanding these patterns is crucial for predicting the likelihood of inheriting specific traits or disorders, as they reveal how is maintained and expressed across generations. Mendelian genetics forms the foundation of patterns, where traits are determined by discrete units called s, with one allele often dominant over a recessive counterpart. In a involving heterozygous parents (each carrying one dominant and one recessive ), the phenotypic ratio among offspring is typically 3:1, with three individuals expressing the dominant trait and one the recessive. This outcome can be visualized using a , a grid that illustrates all possible combinations from parental gametes; for example, crossing Aa (heterozygous) individuals yields genotypes AA, Aa, Aa, and aa, resulting in the 3:1 ratio. Non-Mendelian inheritance deviates from strict dominant-recessive relationships, introducing variations in allele expression. Codominance occurs when both alleles in a heterozygote are fully expressed, as seen in ABO blood types, where the A and B alleles produce distinct antigens on red blood cells, leading to type AB blood in individuals inheriting both. Incomplete dominance results in a blended , such as intermediate flower color in plants, though examples are less straightforward. Polygenic traits, like color, arise from the additive effects of multiple genes, producing a continuous range of phenotypes rather than discrete categories, influenced by several loci each contributing small variations in production. Sex-linked inheritance involves genes on the , predominantly the , leading to different expression patterns between males (XY) and females (XX). X-linked recessive disorders, such as hemophilia A—a condition impairing blood clotting due to mutations in the F8 gene—and red-green , caused by mutations in genes on the , primarily affect males because they inherit only one X chromosome and thus express the recessive trait if mutated. Females require two mutated alleles to be affected, though they can be carriers. Certain genetic disorders exemplify these inheritance patterns. follows an autosomal recessive pattern, requiring two mutated copies of the CFTR gene—one from each parent—to cause defective transport, leading to thick buildup in organs like the lungs and . , in contrast, results from during , producing trisomy 21, where cells contain three copies of instead of two, causing and characteristic physical features; this is not strictly allelic but a chromosomal anomaly affecting about 95% of cases. Population genetics provides a framework for understanding allele frequencies across generations, assuming no evolutionary forces like selection or migration. The Hardy-Weinberg equilibrium models this stability in a large, randomly mating population, where genotype frequencies are given by the equation p2+2pq+q2=1p^2 + 2pq + q^2 = 1, with pp as the frequency of the dominant and qq the recessive (p+q=1p + q = 1). Deviations from this equilibrium indicate factors altering , such as those seen in disorder prevalence.

Evolutionary and developmental biology

Human evolution

Human evolution traces the phylogenetic history of the genus Homo and its ancestors within the hominin lineage, diverging from other primates millions of years ago. The last common ancestor shared between humans and chimpanzees, our closest living relatives, is estimated to have lived approximately 6-7 million years ago in Africa, based on molecular clock analyses and fossil evidence from late Miocene sites. This divergence marked the beginning of distinct evolutionary paths, with hominins adapting to varied ecological niches in Africa. Early hominins, such as those in the genus Australopithecus, represent transitional forms; for instance, Australopithecus afarensis, dated to about 3.2 million years ago, is exemplified by the partial skeleton known as "Lucy" (AL 288-1), discovered in Hadar, Ethiopia, which preserves evidence of both arboreal and bipedal traits. Further along the lineage, Homo habilis, emerging around 2.4 million years ago, is credited with the earliest systematic tool use, including the Oldowan industry of simple stone choppers and flakes used for processing food, as evidenced by assemblages from East African sites. The emergence of anatomically modern Homo sapiens occurred in around 300,000 years ago, with the species characterized by a high forehead, rounded skull, and reduced brow ridges, as seen in fossils from , . According to the Out-of-Africa model, supported by genetic and archaeological data, modern humans dispersed from in multiple waves starting approximately 70,000 years ago, eventually populating and beyond while largely replacing or interbreeding with archaic populations. During these migrations, interbreeding with Neanderthals (Homo neanderthalensis) introduced 1-2% Neanderthal-derived into the genomes of non-African populations, influencing traits such as and skin pigmentation, as revealed by comparative genomic analyses. This admixture occurred primarily between 50,000 and 60,000 years ago in the or . Several key adaptations distinguish , including , which arose early in the hominin lineage and involved significant reconfiguration. In modern humans, the features a shortened, bowl-shaped ilium and a broader to stabilize the trunk and support abdominal organs during upright locomotion, contrasting with the elongated, plate-like pelvis of quadrupedal apes; these changes likely originated around 4-6 million years ago and were refined in species like A. afarensis. enlargement, quantified by the (EQ)—the ratio of actual to expected brain mass for a given body size—reached 7.4-7.8 in H. sapiens, compared to about 2.5 in chimpanzees, enabling advanced , , and tool complexity through expansions in the over the past 2 million years. Another adaptation, in adults, evolved independently in multiple populations as a response to dairying practices; for example, the -13910*T in the LCT gene enhancer allows continued lactase production post-weaning, providing a nutritional advantage in pastoralist societies and rising to high frequencies in Northern Europeans within the last 10,000 years. Fossil evidence has been pivotal in reconstructing this history, with major discoveries at in during the 1950s by Louis and illuminating the transition; their 1959 find of the 1.75-million-year-old Paranthropus boisei skull (OH 5, "Zinjanthropus") and associated tools underscored East Africa's role as a cradle of hominin . In a more recent breakthrough, the 2010 sequencing of the genome from a ~40,000-year-old finger bone in , , identified another archaic group closely related to Neanderthals, with evidence of interbreeding contributing 3-6% Denisovan DNA to modern populations in and parts of , such as . These genomic insights, combined with fossils, highlight the reticulated nature of human ancestry through multiple admixture events. Recent discoveries as of 2025 continue to refine our understanding of . In late 2024, researchers proposed Homo juluensis ("big head"), a new species of archaic human that lived in eastern from approximately 300,000 to 50,000 years ago, potentially encompassing Denisovans and other groups based on reanalysis of fossils and . Additionally, in 2025, a 1-million-year-old from Yunxian, , was reclassified as an early representative of Homo longi, a sister species to H. sapiens and Neanderthals, suggesting large-brained hominins emerged at least 500,000 years earlier than previously thought and coexisted for up to 800,000 years, with possible interbreeding. New fossils from Ledi-Geraru, , dated around 2.5 million years ago, further illustrate the diversity of early hominins during this transitional period.

Growth and development

Human growth and development encompasses the series of biological processes that transform a single fertilized cell into a mature adult, involving cellular proliferation, differentiation, and maturation across prenatal and postnatal stages. This progression is tightly regulated by genetic and hormonal mechanisms, ensuring the formation of complex organ systems and adaptation to environmental demands. Key milestones include rapid embryonic patterning, fetal organ maturation, explosive postnatal neural expansion, pubertal restructuring, and eventual . Embryogenesis begins with fertilization, where a penetrates the , forming a that undergoes cleavage divisions to create a multicellular . By day 5-6 post-fertilization, the implants into the uterine wall, initiating the embryonic period. follows around week 3, reorganizing the blastula into three primary germ layers—, , and —which serve as precursors for all tissues and organs. then occurs primarily from weeks 3 to 8, during which critical structures like the , heart, and limb buds form through inductive signaling and . This phase is highly sensitive to teratogens, as disruptions can lead to congenital anomalies. Fetal development spans from week 9 until birth, marked by substantial growth and functional maturation of organs. A detectable heartbeat emerges around week 6 via , signaling early cardiovascular function. By approximately 24 weeks, outside the womb becomes possible with intensive medical support, though survival rates improve significantly after 28 weeks. The , formed from and maternal tissues, plays a vital by facilitating nutrient and oxygen exchange while producing hormones like to maintain . Postnatally, infancy represents a period of accelerated physical and cognitive expansion, particularly in the , which triples in size during the first year due to synaptic proliferation and myelination. This rapid neural growth supports sensory integration and acquisition, reaching about 80% of adult volume by age 3. , typically initiating between ages 10 and 14, is triggered by a surge in from the , stimulating pituitary secretion of luteinizing and follicle-stimulating hormones. This hormonal cascade induces gonadal maturation and the development of secondary sex characteristics, such as in females and in males. Aging involves progressive physiological decline, influenced by mechanisms like telomere shortening, where protective chromosomal caps erode with each , limiting replicative potential and contributing to tissue dysfunction. Senescence theories include the wear-and-tear model, positing cumulative cellular damage from metabolic stress and environmental factors, and the programmed theory, suggesting genetically timed declines in repair processes. These processes culminate in reduced regenerative capacity and increased vulnerability to disease. Throughout development, growth factors such as growth hormone (GH) and insulin-like growth factor-1 (IGF-1) are central regulators; GH, secreted by the anterior pituitary, stimulates IGF-1 production in the liver, which in turn promotes chondrocyte proliferation in growth plates and overall linear growth. Disruptions in the GH-IGF-1 axis can result in growth disorders, underscoring their essential role from fetal stages through adolescence. Evolutionary conserved genes, like Hox clusters, briefly guide spatial patterning during embryogenesis, as explored in human evolution contexts.

Nutrition and metabolism

Nutritional requirements

Humans require a balanced of essential to support survival, growth, maintenance, and physiological functions. These are categorized into macronutrients, which provide energy and structural components; micronutrients, which facilitate biochemical processes; and , which is vital for hydration and metabolic reactions. The Recommended Dietary Allowances (RDAs) and Acceptable Macronutrient Distribution Ranges (AMDRs), established by the Food and Nutrition Board of the National Academies of Sciences, Engineering, and Medicine (formerly the Institute of Medicine), serve as evidence-based guidelines for to meet the needs of nearly all healthy individuals. Macronutrients include carbohydrates, proteins, and fats, each contributing calories and playing key roles in energy provision and tissue repair. Carbohydrates, the source, yield 4 kcal per gram and should comprise 45-65% of total daily caloric intake according to the AMDR, with sources like whole grains and fruits preferred for their content. Proteins, essential for building and repairing tissues, have an RDA of 0.8 g per kg of body weight for adults, providing 4 kcal per gram and sourced from lean meats, , and . Fats supply 9 kcal per gram and should account for 20-35% of calories, including essential fatty acids like linoleic and alpha-linolenic acids, which the body cannot synthesize and must obtain from foods such as nuts, seeds, and fish. Micronutrients encompass vitamins and minerals required in smaller amounts for enzymatic functions and structural integrity. Vitamins, organic compounds, include water-soluble ones like , which is crucial for synthesis in connective tissues, with an RDA of 90 mg for adult males and 75 mg for females. Minerals, inorganic elements, include calcium at an RDA of 1,000 mg per day for most adults to support , and iron at 8 mg for men and 18 mg for premenopausal women to aid formation in red blood cells. These values are derived from Dietary Reference Intakes (DRIs) that consider from food sources like leafy greens for iron and for calcium. Water is an essential , with total daily recommendations of 3.7 liters for males and 2.7 liters for females, including fluids from beverages and , to maintain hydration and support cellular processes. These guidelines account for variations due to and activity but emphasize plain as the optimal source. Dietary guidelines promote a balanced through visual aids like the model from the U.S. Department of , which illustrates proportions of fruits, , grains, proteins, and to align with DRIs and prevent shortfalls. The RDAs, last comprehensively updated in the by the National Academies, provide specific targets tailored to age, sex, and life stage. Special nutritional needs arise during certain life stages or conditions. For , the RDA for increases to 600 mcg per day in dietary folate equivalents to support fetal development, obtainable from fortified cereals and supplements alongside natural sources like . Athletes require elevated protein intake, typically 1.2-2.0 g per kg of body weight daily, to facilitate muscle repair and adaptation following exercise, exceeding the standard RDA for sedentary individuals.

Metabolic pathways

Metabolic pathways in human biology encompass the interconnected biochemical reactions that facilitate production, storage, and utilization, primarily through processes that break down macromolecules and processes that synthesize them. These pathways occur mainly in the liver, muscles, and other tissues, integrating carbohydrates, fats, and proteins to maintain . generates ATP by degrading nutrients into simpler molecules, while builds complex structures using energy from ATP, with both regulated to match physiological demands such as or feeding states. Catabolism includes the breakdown of fats via beta-oxidation, which occurs in the and converts s into for entry into the . The process begins with activation of s to using ATP at the outer mitochondrial membrane, followed by transport into the matrix via the carnitine shuttle involving and II. Inside the matrix, repeated cycles of dehydrogenation (producing FADH₂), hydration, oxidation (producing NADH), and thiolysis cleave two-carbon units as , yielding 1 NADH, 1 FADH₂, and 1 per cycle. For a typical 16-carbon like palmitate, this produces 8 molecules, along with reducing equivalents for additional ATP generation. involves the degradation of proteins into , primarily through lysosomal and ubiquitin-proteasome pathways, followed by where the amino group is removed as (converted to via the hepatic ) and the carbon skeleton enters central pathways. are classified as glucogenic (e.g., , yielding pyruvate or intermediates) or ketogenic (e.g., , yielding ), supporting energy production during . Anabolism counters catabolism by synthesizing essential molecules; gluconeogenesis, for instance, generates glucose from non-carbohydrate precursors like lactate (via the ), glycerol from triglycerides, and glucogenic amino acids such as , primarily in the liver and kidneys during . Key steps include pyruvate carboxylation to oxaloacetate (catalyzed by , ATP-dependent), conversion to phosphoenolpyruvate (via PEPCK, GTP-dependent), reversal of glycolytic steps with bypass enzymes like fructose-1,6-bisphosphatase (rate-limiting), and dephosphorylation to free glucose by glucose-6-phosphatase. This pathway ensures blood glucose maintenance, consuming 6 ATP equivalents per glucose molecule produced. synthesizes fatty acids from excess derived from carbohydrates, mainly in the liver's during the fed state. from mitochondrial citrate is cleaved by ATP-citrate lyase, carboxylated to by (rate-limiting, inhibited by ), and polymerized into palmitate by using NADPH; subsequent elongation by elongases and desaturation by stearoyl-CoA desaturase produce longer-chain fatty acids for storage. The energy yield from these pathways culminates in the , embedded in the , where NADH and FADH₂ donate electrons to complexes I-IV, pumping protons to create a gradient that drives ATP synthesis. Electrons reduce oxygen to water at complex IV, with complex I oxidizing NADH (pumping 4 H⁺), complex III transferring from ubiquinone (4 H⁺), and complex II from FADH₂ (no pumping). (F₀F₁ complex) harnesses the proton motive force: protons flow through F₀, rotating the c-ring to induce conformational changes in F₁, catalyzing ADP + Pᵢ to ATP (approximately 1 ATP per 4 H⁺). Complete oxidation of one glucose molecule yields about 30-32 ATP: 2 from , 2 from the , and 26-28 from (2.5 ATP per NADH, 1.5 per FADH₂), though estimates vary up to 34 based on shuttle efficiencies. Hormonal regulation fine-tunes these pathways; insulin, secreted postprandially, promotes anabolism by stimulating (via GLUT4 translocation), synthesis, , and protein synthesis while inhibiting , , and . Conversely, , released during , drives by activating hepatic , , and fatty acid oxidation (via increased carnitine palmitoyltransferase activity), while suppressing insulin secretion and promoting to elevate blood glucose. These opposing actions maintain euglycemia, with insulin dominating in fed states and in . The (BMR) quantifies the minimum energy expended at rest to sustain vital functions, accounting for 60-75% of daily expenditure and influenced by age, sex, and . The revised Harris-Benedict estimates BMR for men as: BMR (kcal/day)=88.362+(13.397×weight in kg)+(4.799×height in cm)(5.677×age in years)\text{BMR (kcal/day)} = 88.362 + (13.397 \times \text{weight in kg}) + (4.799 \times \text{height in cm}) - (5.677 \times \text{age in years}) This formula, derived from data, predicts energy needs for core processes like circulation and respiration, decreasing 1-2% per decade after age 20 due to muscle loss.

Health and pathology

Disease mechanisms

Human diseases arise from disruptions in normal biological processes at cellular, tissue, and systemic levels, often involving interactions between genetic predispositions, environmental factors, and pathogens. These mechanisms can lead to acute or chronic pathologies by altering , such as through impaired signaling pathways, uncontrolled , or protein misfolding. Understanding these origins is crucial for elucidating disease progression, as they manifest differently across categories like infectious, genetic, lifestyle-related, neoplastic, and degenerative conditions. Infectious diseases primarily result from and exploitation of host mechanisms. and viruses enter the body through portals like the or breaches, adhering to host cells via surface proteins or toxins that facilitate attachment and . For instance, , the virus responsible for , binds to the ACE2 receptor on respiratory epithelial cells using its , triggering and replication within the host cell, which leads to cytopathic effects and . factors, such as bacterial exotoxins that disrupt cell membranes or viral proteins that evade immune detection, amplify damage by promoting tissue destruction and systemic spread. Genetic diseases stem from alterations in DNA that impair protein function or regulation. Point mutations involve single nucleotide substitutions, potentially changing an amino acid in the protein sequence (missense) or creating premature stop codons (nonsense), while frameshift mutations arise from insertions or deletions not divisible by three, shifting the and often producing truncated or nonfunctional proteins. A classic example is sickle cell anemia, caused by a in the () on , substituting for at position 6 of the β-globin chain, leading to polymerization under low oxygen conditions, red blood cell sickling, and vascular occlusion. These mutations disrupt and oxygen transport, resulting in and organ damage. Lifestyle-related diseases often involve chronic environmental stressors that perturb metabolic balance. develops through in arterial walls, where (LDL) particles infiltrate the intima, undergo oxidation, and trigger an inflammatory response; monocytes differentiate into macrophages that engulf oxidized LDL, forming foam cells and initiating plaque buildup with a lipid core, fibrous cap, and proliferation. This progressive narrowing and hardening of arteries increases cardiovascular risk. Similarly, arises from in peripheral tissues like muscle and adipose, where impaired signaling reduces glucose uptake via transporters, leading to ; chronic and further exacerbate β-cell dysfunction and . Cancer mechanisms center on dysregulated and survival, driven by genetic alterations in oncogenes and tumor suppressor genes. Oncogenes, such as mutated RAS, promote uncontrolled growth signaling through pathways like MAPK, while tumor suppressors like normally halt the or induce in response to DNA damage; loss-of-function mutations in TP53, occurring in over 50% of cancers, abolish this checkpoint, allowing genomic instability and tumor progression. involves sequential stages: local invasion via degradation by matrix metalloproteinases, intravasation into blood or lymph vessels, survival in circulation as circulating tumor cells, at distant sites, and through and microenvironment adaptation, ultimately forming secondary tumors. Degenerative diseases feature progressive neuronal loss due to . In , amyloid-β (Aβ) peptides aggregate extracellularly into plaques that disrupt synaptic function and trigger , while hyperphosphorylated proteins form intracellular neurofibrillary tangles that impair stability, axonal , and neuronal integrity. These pathologies correlate with cognitive decline, as plaques and tangles accumulate in regions like the hippocampus, leading to synaptic degeneration and circuit dysfunction over decades.

Immunology and defense

The human immune system serves as a multifaceted defense mechanism against pathogens and other threats, comprising innate and adaptive components that work in concert to maintain . Innate immunity provides immediate, non-specific protection through physical and chemical barriers, while adaptive immunity offers targeted, memory-based responses that improve upon repeated exposures. This dual system ensures rapid containment of invaders followed by long-term vigilance, with dysregulation potentially leading to disorders like or . Innate immunity acts as the first line of defense, relying on anatomical barriers such as the skin and mucous membranes to prevent entry. These barriers are reinforced by chemical defenses like and low pH environments in secretions. Upon breach, cellular components including —such as macrophages and neutrophils—engulf and destroy invaders through . is a key process in innate responses, orchestrated by cytokines like interleukin-1 and tumor necrosis factor-alpha, which recruit immune cells and increase to facilitate clearance. Adaptive immunity, in contrast, is antigen-specific and involves lymphocytes: B cells produce antibodies to neutralize extracellular threats, while T cells mediate cellular immunity against infected or abnormal cells. B cells differentiate into plasma cells upon recognition, secreting immunoglobulins that bind pathogens for opsonization or complement activation. T cells, including cytotoxic CD8+ and helper + subsets, recognize antigens presented by (MHC) molecules on cell surfaces; MHC class I displays intracellular peptides to cytotoxic T cells, and presents extracellular antigens to helper T cells, which then amplify the response. This process generates immunological memory, enabling faster and stronger reactions to subsequent encounters. Vaccination harnesses adaptive immunity by introducing harmless mimics to prime B and T cell responses without causing . For highly contagious pathogens like , achieving requires approximately 95% population coverage to prevent outbreaks, as unvaccinated individuals are shielded by collective immunity. mRNA vaccines, exemplified by those developed for in 2020, encode viral spike proteins to stimulate production and T cell activation, demonstrating in eliciting robust, durable protection. Autoimmunity arises when adaptive responses erroneously target self-antigens, leading to chronic and tissue damage. In , autoantibodies against citrullinated proteins—modified self-antigens in joint tissues—drive synovial and joint erosion, often linked to genetic factors like alleles. Such breakdowns in self-tolerance mechanisms, including dysfunction, underscore the immune system's potential for self-harm. Hypersensitivity reactions represent exaggerated immune responses, classified into four types based on mechanisms and timing. Type I involves IgE-mediated immediate reactions, such as triggered by allergens like , causing rapid release and symptoms from to shock. Type II features antibody-mediated against cell-bound antigens, as in hemolytic anemias. Type III results from immune complex deposition leading to , seen in . Type IV is delayed, T cell-driven, manifesting 48-72 hours post-exposure in conditions like from nickel.

Behavioral biology

Neurobiology and senses

The human nervous system comprises the (CNS) and the peripheral nervous system (PNS), enabling the integration of sensory input, processing of information, and coordination of motor outputs for behavioral responses. The CNS, consisting of the and , serves as the primary site for information processing and reflex control. The PNS connects the CNS to the rest of the body, transmitting sensory and motor signals. The brain is divided into four main lobes, each contributing to sensory processing and behavioral functions. The frontal lobe, located anterior to the , governs voluntary motor function, problem-solving, attention, memory, and through the and . The parietal lobe, posterior to the and separated by the , processes sensory information via the somatosensory cortex, integrating touch, temperature, and spatial awareness for environmental navigation. The occipital lobe functions as the primary visual processing center, with the interpreting visual stimuli by incorporating past experiences to guide . The temporal lobe handles auditory stimuli through the and includes for speech comprehension, supporting communication behaviors. The brain's two hemispheres exhibit lateralization, with the left typically associated with and logic, and the right with and intuition. The , a cylindrical structure approximately 45 cm long in adult males and 42-43 cm in adult females, extends from the to the L1-L2 vertebral level, protected by the vertebral column and . It features an H-shaped gray matter core surrounded by containing tracts. Ascending tracts, such as the spinothalamic and spinocerebellar pathways, relay sensory information—including pain, temperature, touch, and —from peripheral receptors to the via sequential neurons: first-order from receptors to the dorsal horn, second-order to the or , and third-order to the somatosensory cortex. Descending tracts, including the corticospinal and vestibulospinal pathways, transmit motor commands from the to lower motor neurons, coordinating voluntary and involuntary movements. The peripheral nervous system divides into the somatic and autonomic divisions. The includes sensory neurons that detect environmental stimuli and motor neurons that control voluntary movements. The regulates involuntary functions and comprises three branches: the sympathetic (, increasing and via norepinephrine), parasympathetic (rest-and-digest, slowing and promoting via ), and enteric (governing gastrointestinal motility and secretion using neurotransmitters like and serotonin). Neurons, the fundamental units of the nervous system, consist of a cell body, dendrites, axon, and synaptic terminals that support neural communication underlying . Dendrites are branched projections that receive incoming signals from other neurons and relay them to the cell body for integration. The axon is a long, cylindrical extension covered by the axolemma, conducting electrical impulses away from the cell body to the presynaptic terminal, where neurotransmitters are released. Synapses form junctions between the presynaptic and postsynaptic dendrites or cell bodies, separated by a synaptic cleft less than 50 nm wide, facilitating chemical transmission. Key neurotransmitters include , an excitatory mediator at neuromuscular junctions and autonomic ganglia, synthesized in the basal nucleus of Meynert, and , generally inhibitory, involved in and reward pathways like the nigrostriatal and mesolimbic systems. Neural signaling occurs through action potentials, rapid voltage changes across the neuronal membrane triggered by stimuli reaching threshold, enabling quick behavioral responses. Voltage-gated sodium channels open, allowing sodium influx and depolarization in a positive-feedback loop, while voltage-gated potassium channels subsequently open for repolarization via potassium efflux. The sodium-potassium pump (Na+/K+-ATPase) maintains resting potential by actively transporting sodium out and potassium into the cell using ATP, restoring ion gradients after signaling. Action potentials peak at approximately +40 mV before repolarizing. Human senses rely on specialized receptors to transduce environmental stimuli into neural signals that inform behavior. Vision begins in the retina, the innermost layer of the eye containing photoreceptors: rods and cones. Rods, numbering about 125 million and containing rhodopsin, enable scotopic (low-light) vision with high sensitivity but no color discrimination, predominating in the peripheral retina. Cones, fewer in number and concentrated in the fovea, possess photopigments sensitive to red, green, or blue wavelengths, supporting photopic (bright-light) color vision and high acuity in the central field. Photoreceptors synapse with bipolar and horizontal cells, converging signals through amacrine and ganglion cells to the optic nerve. Hearing involves the , a coiled structure with three fluid-filled scalae: vestibuli, media, and tympani. Sound waves cause vibrations that deflect the basilar membrane, where the houses cells. Inner cells, in one row, transduce most auditory signals by bending , which opens potassium channels via tip links, leading to , calcium influx, and glutamate release to afferent neurons. Outer cells, in three rows, amplify vibrations for enhanced sensitivity and frequency selectivity, exhibiting tonotopic organization with high frequencies at the base and low at the apex. Taste and smell detect chemicals via chemoreceptors. Gustation occurs through in the mouth, where receptor cells transduce water-soluble tastants (e.g., sweet, sour, salty, bitter, ) into action potentials, signaling food quality and safety to the CNS. Olfaction involves neurons in the , which bind airborne odor molecules, generating receptor potentials that trigger action potentials relayed to the . Both systems integrate with trigeminal chemoreception for detecting irritants.

Social and ecological adaptations

Humans exhibit a profound biological basis for that enhances cooperation and group cohesion essential for survival. The oxytocin plays a central role in facilitating social bonding, promoting trust, , and attachment in interpersonal relationships. Intranasal administration of oxytocin has been shown to increase perceptions of romantic bonds and in human studies. Complementing this, mirror neurons, identified in monkeys and inferred in humans via brain imaging, activate during both action execution and and are hypothesized to contribute to by simulating others' actions, though their role in emotional simulation remains debated. This mechanism may underpin social learning and , fostering synchronized behaviors in groups. Reproductive strategies in humans emphasize long-term pair bonding to support biparental care and offspring survival, distinguishing them from many other . Neurobiological pathways involving oxytocin and reinforce partner preferences, with pair bonds forming through initial attraction and consolidating via shared experiences and proximity. This monogamous tendency likely evolved to mitigate risks and ensure paternal investment in resource-scarce environments. further shapes reproductive altruism, where individuals favor relatives to propagate shared genes, as quantified by Hamilton's rule (rB > C, where r is relatedness, B the benefit to the recipient, and C the cost to the actor). Ecological adaptations enable humans to thrive in diverse environments, from high altitudes to varying solar exposures. In Tibetan populations, variants in the EPAS1 gene, inherited partly from Denisovan ancestors, regulate hypoxia-inducible factors to maintain efficient oxygen use without excessive red blood cell production, reducing risks of chronic mountain sickness. This adaptation supports reproduction and survival above 4,000 meters. Similarly, skin pigmentation evolves as a melanin-based shield against ultraviolet radiation; darker eumelanin-rich skin in equatorial regions protects folate reserves and DNA from UV damage, while lighter pigmentation in higher latitudes facilitates vitamin D synthesis. These traits balance photoprotection and nutritional needs across latitudes. The human gut microbiome, comprising approximately 10^14 microbial cells, profoundly influences social and ecological fitness through bidirectional interactions with the host. Gut bacteria modulate immunity by training adaptive responses and maintaining barrier integrity, preventing pathogen invasion and autoimmune disorders. They also shape mood via the gut-brain axis, producing neurotransmitters like serotonin that affect emotional regulation and social behavior; correlates with heightened anxiety and reduced sociability. Anthropogenic pressures, such as , disrupt these adaptations by introducing endocrine disruptors like (BPA). BPA, leaching from plastics, mimics and interferes with and reproductive hormones, leading to altered fertility, metabolic disorders, and developmental delays in exposed populations. Chronic low-level exposure via and water exacerbates hormonal imbalances, compounding ecological challenges to human biology.

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