Blood cell
Blood cells, also known as the formed elements of blood, are the cellular components suspended in blood plasma that perform critical physiological functions in the human body.[1] These cells include erythrocytes (red blood cells), leukocytes (white blood cells), and thrombocytes (platelets), which together make up about 45% of blood volume and are produced through a process called hematopoiesis in the bone marrow.[2] Erythrocytes constitute the majority (approximately 99%) of blood cells and are responsible for transporting oxygen from the lungs to tissues and carbon dioxide back to the lungs for exhalation.[3] Leukocytes, present in much smaller numbers, are key components of the immune system, defending against infections and pathogens through phagocytosis, antibody production, and inflammation modulation.[4] Platelets, the smallest blood cells, initiate blood clotting to prevent excessive bleeding and support wound healing by aggregating at injury sites.[5] Hematopoiesis, the formation of blood cells, begins with multipotent hematopoietic stem cells in the bone marrow that differentiate into committed progenitors under the influence of growth factors like colony-stimulating factors.[2] These progenitors give rise to myeloid lineages (erythrocytes, granulocytes, monocytes, and platelets) and lymphoid lineages (lymphocytes), ensuring continuous renewal to replace aged or damaged cells.[2] Erythrocytes have a lifespan of about 120 days and lack nuclei, allowing efficient gas exchange via hemoglobin, a protein containing iron-rich heme groups.[3] In contrast, leukocytes vary widely in lifespan—from hours for some granulocytes to years for memory lymphocytes—and are classified morphologically into granulocytes (neutrophils, eosinophils, basophils), which contribute to innate immunity, and agranulocytes (monocytes and lymphocytes), with monocytes involved in innate immunity and lymphocytes in adaptive immunity.[4] Platelets, derived from megakaryocytes, circulate for 7–10 days and contain granules that release mediators for hemostasis, thrombosis, and even immune functions beyond clotting.[5] Abnormalities in blood cell production, count, or function can lead to disorders such as anemia (low erythrocytes), leukemias (malignant leukocytes), or thrombocytopenia (low platelets), highlighting their vital role in maintaining homeostasis.[1] Blood cells are continuously monitored via complete blood counts, which quantify their numbers and subtypes to assess health.[1]Overview
Definition and classification
Blood is classified as a specialized connective tissue, consisting of cells and cell fragments suspended in an extracellular matrix known as plasma.[6] This matrix and its cellular components together enable blood to function as a fluid transport medium throughout the body. The composition of blood is approximately 55% plasma—a yellowish fluid primarily composed of water, proteins, and electrolytes—and 45% formed elements, which include the cellular components erythrocytes, leukocytes, and thrombocytes.[7] These formed elements constitute the solid portion of blood and are responsible for its primary physiological roles.[8] Blood cells are broadly classified into three major types based on their structure and primary functions: erythrocytes (red blood cells), leukocytes (white blood cells), and thrombocytes (platelets). Erythrocytes are the most abundant, comprising the majority of formed elements, and are specialized for gas transport.[1] Leukocytes, which are fewer in number, are further subdivided into granulocytes—containing cytoplasmic granules and including neutrophils, eosinophils, and basophils—and agranulocytes, which lack prominent granules and include lymphocytes and monocytes.[4] Thrombocytes, the smallest of the blood cells, are cell fragments essential for hemostasis and clotting processes.[9] This classification reflects the diverse roles these cells play in maintaining homeostasis, though their integrated contributions to circulation are explored further elsewhere. Morphologically, blood cells exhibit distinct features that aid in their identification and differentiation. Erythrocytes are anucleate biconcave discs, typically measuring 7-8 μm in diameter, which optimizes their flexibility and surface area for transport.[10] In contrast, leukocytes and thrombocytes are nucleate (or derived from nucleate precursors in the case of platelets), with leukocytes ranging from 10-20 μm in size and displaying varied nuclear shapes and cytoplasmic characteristics depending on subtype.[11] Thrombocytes are notably smaller, at 2-3 μm, and appear as irregular discoid fragments. These structural differences underscore the specialized adaptations of each cell type. In evolutionary terms, blood cells in vertebrates originate from the mesoderm, one of the three primary germ layers formed during early embryonic development.[12] This mesodermal derivation is conserved across vertebrate species, giving rise to the hematopoietic lineages that produce erythrocytes, leukocytes, and thrombocytes through subsequent differentiation processes.[13]Role in circulation
Blood cells, primarily erythrocytes, leukocytes, and platelets, are suspended in plasma to form whole blood, whose rheological properties are essential for efficient circulation throughout the vascular system. The viscosity of whole blood is a key determinant of flow dynamics, exhibiting shear-thinning behavior where it decreases at higher shear rates due to red blood cell (RBC) deformation and disaggregation. Hematocrit, the volume percentage of RBCs, profoundly influences this viscosity; for instance, an increase in hematocrit elevates blood viscosity, thereby increasing shear stress on vessel walls and contributing to peripheral resistance, particularly in the microcirculation. This balance ensures optimal blood flow while supporting oxygen delivery, as higher hematocrit enhances oxygen-carrying capacity but can impede flow if excessive. In their integrated roles, erythrocytes facilitate the maintenance of oxygen-carbon dioxide balance by circulating through the vasculature, leukocytes patrol the bloodstream to detect and respond to pathogens, and platelets adhere to vessel walls to prevent plasma leakage and uphold endothelial integrity. These cells interact dynamically with plasma components; for example, fibrinogen and other plasma proteins promote RBC aggregation into rouleaux formations under low shear conditions, which reduces the effective viscosity in microvessels and enhances axial flow by channeling RBCs toward the vessel center. Such interactions, including transient cell-plasma adhesions, minimize energy loss during circulation and optimize perfusion in narrower vessels. Homeostatic regulation maintains an equilibrium among blood cell populations to preserve circulatory efficiency; disruptions, such as elevated leukocyte counts during infection (leukocytosis), can increase whole blood viscosity by altering the fractional volume of cellular components, leading to sluggish flow, microvascular sludging, and potential tissue hypoperfusion. In hyperleukocytic states, like those in acute leukemias, this heightened viscosity exacerbates vascular resistance and promotes leukocyte adhesion to endothelium, further impairing circulation.Hematopoiesis
Hematopoietic stem cells
Hematopoietic stem cells (HSCs) are multipotent, self-renewing cells that serve as the foundational progenitors for all mature blood cell lineages, including erythrocytes, leukocytes, and platelets.[14] These cells possess the dual properties of multipotency, enabling differentiation into diverse hematopoietic lineages, and extensive self-renewal capacity, allowing them to maintain the hematopoietic system throughout life.[15] HSCs are rare, comprising approximately 1 in 10,000 to 1 in 100,000 bone marrow cells in adults, and their function is critical for steady-state hematopoiesis and response to stress such as infection or blood loss.[16] In adults, HSCs are primarily located within specialized niches in the bone marrow, including the endosteal niche near the bone surface and the vascular niche adjacent to sinusoidal blood vessels.[17] These niches provide a supportive microenvironment that maintains HSC quiescence, with the chemokine CXCL12 (also known as SDF-1) playing a key role in retaining HSCs by signaling through the CXCR4 receptor on HSC surfaces.[18] Disruption of CXCL12-CXCR4 interactions can mobilize HSCs into the peripheral blood, highlighting the niche's regulatory influence.[19] HSCs are identified by surface markers such as CD34 positivity, often combined with the absence of lineage-specific markers (Lin-), and their long-term repopulating ability is functionally assayed through transplantation into irradiated animal models, where they reconstitute multilineage hematopoiesis for months.[20] This assay demonstrates their capacity to home to the bone marrow and sustain blood production over extended periods, distinguishing true HSCs from short-term progenitors.[21] The self-renewal and commitment of HSCs are tightly regulated by transcription factors such as RUNX1 and GATA2, which maintain stem cell identity and orchestrate lineage priming.[22] RUNX1 promotes HSC emergence and survival, while GATA2 is essential for HSC maintenance and expansion. Cytokines including stem cell factor (SCF) and FMS-like tyrosine kinase 3 ligand (FLT3L) further modulate HSC function; SCF supports survival and proliferation via c-KIT receptor signaling, and FLT3L enhances early progenitor expansion in synergy with other factors.[23][24] In clinical practice, HSC transplantation is a cornerstone therapy for treating hematologic malignancies, bone marrow failure syndromes, and certain immunodeficiencies, where donor HSCs repopulate the recipient's hematopoietic system following myeloablative conditioning.[25] This procedure, first successfully performed in humans in the 1960s, has evolved to include peripheral blood and umbilical cord blood sources, improving accessibility and outcomes for blood disorders.[26] Recent advancements as of 2025 include ex vivo HSC expansion, in vivo gene delivery, and FDA-approved gene therapies using edited HSCs for conditions like sickle cell disease and beta-thalassemia.[27]Bone marrow and production sites
In adults, the bone marrow serves as the primary site of hematopoiesis, where hematopoietic stem cells (HSCs) differentiate into all blood cell lineages.[28] Red bone marrow, rich in hematopoietic tissue, is predominantly located in the flat bones such as the pelvis, sternum, vertebrae, ribs, and proximal ends of the femur and humerus, while yellow bone marrow, which is largely fatty and inactive in blood production, occupies the medullary cavities of long bones.[29] This distinction allows red marrow to actively support blood cell formation, with the capacity to convert yellow marrow to red under stress to meet increased demand.[28] During fetal development, hematopoiesis occurs in sequential sites before establishing in the bone marrow. Primitive hematopoiesis begins in the yolk sac around the third week of gestation, producing early erythroid cells to support embryonic oxygenation.[30] This shifts to definitive hematopoiesis in the fetal liver and spleen by the sixth to eighth week, where HSCs generate multilineage progenitors capable of long-term repopulation.[31] By the third trimester, hematopoiesis transitions primarily to the bone marrow, which becomes the dominant site shortly after birth as liver and spleen activity diminishes.[28] The bone marrow microenvironment, or niche, provides critical structural and molecular support for HSC maintenance, self-renewal, and differentiation. Stromal cells, including mesenchymal stem cells and fibroblasts, secrete cytokines and growth factors such as stem cell factor and thrombopoietin to regulate HSC quiescence.[32] The extracellular matrix, composed of collagen, fibronectin, and laminins, anchors HSCs and modulates signaling pathways like Wnt and Notch for proper localization.[33] Vascular sinuses, formed by fenestrated endothelial cells, facilitate HSC migration and release into the bloodstream via interactions with adhesion molecules such as VLA-4 and SDF-1.[34] Under pathological conditions, extramedullary hematopoiesis can reactivate in sites like the liver and spleen when bone marrow production is insufficient. This compensatory mechanism is rare in healthy individuals but occurs in disorders such as thalassemia, where ineffective erythropoiesis drives expansion of hematopoietic tissue outside the marrow.[35] In these cases, the liver and spleen may form nodules of erythroid and myeloid precursors, potentially leading to organomegaly.[36] In healthy adults, the bone marrow produces approximately $10^{11} to $5 \times 10^{11} blood cells daily to maintain steady-state circulation, encompassing red blood cells, white blood cells, and platelets.[37] This output is finely tuned by the niche to match physiological needs without overwhelming systemic resources.[38]Red blood cells
Structure and composition
Red blood cells, also known as erythrocytes, possess a unique biconcave disc morphology that enhances their efficiency in circulation. This shape features a diameter of approximately 7.5 μm and a thickness of about 2 μm at the periphery, tapering to nearly 1 μm at the center, which maximizes the surface area-to-volume ratio for optimal diffusion.[3] The biconcave structure results in a characteristic central pallor when viewed in stained blood smears under light microscopy, reflecting the thinner central region where hemoglobin concentration appears lower.[3] The primary component of the erythrocyte's interior is hemoglobin, a tetrameric protein accounting for roughly 97% of the cell's dry weight, with each molecule consisting of two alpha and two beta globin chains bound to four heme groups containing iron atoms.[39] Mature erythrocytes lack a nucleus, mitochondria, and other organelles, a specialization that occurs during their development in the bone marrow to allocate maximal intracellular space to hemoglobin.[3] The plasma membrane, composed of a lipid bilayer embedded with proteins, is reinforced by an underlying cytoskeleton network dominated by spectrin tetramers cross-linked with actin and other proteins like ankyrin and band 3, conferring exceptional flexibility and resilience.[40] Erythrocyte deformability, essential for navigating microvasculature, arises from this spectrin-based cytoskeleton, which allows the cells to elongate and reversibly deform without rupture under shear stress.[40] The cell surface is adorned with carbohydrate-bearing glycoproteins and glycolipids that express the ABO blood group antigens (determined by A, B, and H antigens) and Rh factor (primarily the D antigen), forming the basis of human blood typing systems.[3]Oxygen transport function
Red blood cells (erythrocytes) are primarily responsible for oxygen transport in the vertebrate circulatory system, achieving this through the specialized protein hemoglobin, which constitutes approximately 97% of the dry weight of each mature erythrocyte. Each hemoglobin molecule, a tetrameric structure composed of two alpha and two beta globin chains each associated with a heme group, reversibly binds up to four oxygen molecules, enabling the carriage of about 1.34 mL of oxygen per gram of hemoglobin under physiological conditions. This binding process exhibits positive cooperativity, where the attachment of the first oxygen molecule induces a conformational change from the tense (T) to the relaxed (R) state, facilitating subsequent bindings and resulting in a sigmoidal oxygen-hemoglobin dissociation curve that optimizes oxygen loading in the lungs and unloading in tissues.[41][42][43] The cooperative oxygen binding can be qualitatively represented by the equilibrium: \text{Hb} + 4\text{O}_2 \rightleftharpoons \text{Hb}(\text{O}_2)_4 This equilibrium is modulated by environmental factors, notably the Bohr effect, whereby increased partial pressure of carbon dioxide (PCO₂) or decreased pH in tissues shifts the dissociation curve to the right, reducing hemoglobin's oxygen affinity and promoting unloading at sites of metabolic demand, such as active muscles. Conversely, in the pulmonary alveoli, lower PCO₂ and higher pH facilitate oxygen uptake. The Bohr effect arises from protonation of specific histidine residues (e.g., His146 on beta chains) and interactions with 2,3-bisphosphoglycerate (2,3-BPG), an allosteric effector synthesized in erythrocytes via the Rapoport-Luebering shunt.[44][45][46] In addition to oxygen transport, red blood cells play a crucial role in carbon dioxide (CO₂) elimination from tissues. Approximately 70% of CO₂ produced by cellular metabolism diffuses into erythrocytes, where it is rapidly converted to bicarbonate (HCO₃⁻) by the enzyme carbonic anhydrase, following the reaction: CO₂ + H₂O ⇌ H₂CO₃ ⇌ H⁺ + HCO₃⁻; the bicarbonate then exits the cell via the anion exchanger band 3 in exchange for chloride ions (Hamburger shift), allowing plasma transport to the lungs. The remaining CO₂ is carried as dissolved gas (about 7-10%) or bound to hemoglobin as carbaminohemoglobin (20-23%). The Haldane effect complements this process: deoxygenation of hemoglobin in tissues enhances its capacity to bind CO₂ and buffer protons, while reoxygenation in the lungs releases bound CO₂, aiding exhalation. 2,3-BPG further supports tissue oxygen delivery by stabilizing the deoxyhemoglobin (T-state) conformation, thereby decreasing oxygen affinity independently of pH changes and ensuring efficient unloading where oxygen demand is high.[47][48][49] Pathophysiologically, disruptions in red blood cell function impair oxygen transport; for instance, anemia—characterized by reduced erythrocyte count or hemoglobin concentration—diminishes the blood's oxygen-carrying capacity, leading to tissue hypoxia despite compensatory increases in cardiac output and 2,3-BPG levels. In severe cases, such as iron-deficiency anemia, oxygen delivery can fall below critical thresholds, manifesting as fatigue, dyspnea, and organ dysfunction.[50][51][52]Production and lifecycle
The production of red blood cells, known as erythropoiesis, occurs primarily in the bone marrow and involves a series of maturation stages beginning with the proerythroblast, the earliest recognizable erythroid precursor. This process progresses through basophilic erythroblast, polychromatophilic erythroblast, orthochromatic erythroblast (or normoblast), and finally to the reticulocyte, during which the cell undergoes nuclear condensation, hemoglobin synthesis, and organelle reduction.[53] The entire maturation from proerythroblast to reticulocyte typically takes 7 to 10 days in the bone marrow under normal conditions.[54] Erythropoiesis is primarily stimulated by erythropoietin (EPO), a hormone secreted by the kidneys in response to tissue hypoxia, which binds to receptors on erythroid progenitors to promote their survival, proliferation, and differentiation.[55] Upon completion of intramedullary maturation, reticulocytes—immature red blood cells retaining some ribosomal RNA—are released into the peripheral circulation, where they undergo final maturation into erythrocytes by extruding residual organelles and achieving full biconcave disc morphology. This circulatory phase of reticulocyte maturation lasts approximately 1 to 2 days, during which the cells lose their staining affinity for supravital dyes like brilliant cresyl blue.[56] Reticulocytes constitute about 1% of circulating red blood cells in healthy adults, serving as a marker of ongoing erythropoiesis.[56] Mature erythrocytes circulate for an average lifespan of 120 days, after which they undergo senescence, a process marked by the progressive clustering of band 3 anion exchanger proteins on the cell membrane, which exposes hidden antigenic sites and signals for removal.[57][58] Senescent red blood cells lose deformability and accumulate oxidative damage, further contributing to their recognition by the reticuloendothelial system.[57] Aged erythrocytes are primarily cleared by macrophages through phagocytosis in the spleen and liver, where they are engulfed without prior apoptosis, preventing the release of potentially harmful intracellular contents.[59] During this erythrophagocytosis, macrophages degrade hemoglobin via the enzyme heme oxygenase-1, which catabolizes heme into biliverdin, carbon monoxide, and free iron, enabling efficient iron recycling for new erythropoiesis—accounting for over 90% of daily iron requirements in steady-state conditions.[60][61] The recycled iron is bound to transferrin and transported back to the bone marrow for hemoglobin synthesis.[61] The regulation of erythropoiesis is tightly controlled by the hypoxia-inducible factor (HIF) pathway, which senses low oxygen levels and stabilizes HIF transcription factors, particularly HIF-2α in renal interstitial cells, to induce EPO gene expression and secretion.[62] This oxygen-sensing mechanism ensures that red blood cell production scales with physiological demands, such as altitude exposure or anemia, by linking hypoxia detection directly to EPO-mediated progenitor expansion.[63]White blood cells
Types and subtypes
White blood cells, also known as leukocytes, are broadly classified into granulocytes and agranulocytes based on the presence or absence of cytoplasmic granules visible under light microscopy.[4] Granulocytes contain enzyme-filled granules, while agranulocytes lack them, and this distinction aids in their identification during differential blood counts.[4] The total leukocyte count in healthy adults typically ranges from 4,000 to 11,000 cells per microliter of blood.[64] Granulocytes comprise approximately 60-70% of circulating leukocytes and include three main subtypes: neutrophils, eosinophils, and basophils. Neutrophils, the most abundant, account for 50-70% of total leukocytes; they feature a multilobed nucleus (typically 3-5 lobes) and are highly phagocytic, engulfing pathogens.[65] Eosinophils represent 2-4% of leukocytes, characterized by a bilobed nucleus and large granules that play a role in anti-parasitic responses.[66] Basophils, the rarest granulocytes at 0.5-1% of leukocytes, have a bilobed nucleus obscured by dark-staining granules involved in allergic responses.[66] Agranulocytes make up 30-40% of leukocytes and consist of lymphocytes and monocytes. Lymphocytes constitute 20-40% of total leukocytes, with a large round nucleus and scant cytoplasm; they are further divided into T cells (involved in cell-mediated immunity), B cells (key for antibody production), and natural killer (NK) cells (important for innate antiviral defense).[66][67] Monocytes account for 2-8% of leukocytes, serving as precursors to macrophages and dendritic cells; they are the largest leukocytes, with a kidney-shaped or indented nucleus.[66] Differential identification of these subtypes relies on staining techniques such as Wright-Giemsa, which highlights nuclear and cytoplasmic features for microscopic examination. Size variations also aid classification: for example, lymphocytes typically measure 7-15 μm in diameter, neutrophils 10-12 μm, and monocytes 15-20 μm.[4]| Subtype | Category | Relative Abundance (% of total leukocytes) | Key Identifiers |
|---|---|---|---|
| Neutrophils | Granulocyte | 50-70 | Multilobed nucleus (3-5 lobes), fine granules |
| Eosinophils | Granulocyte | 2-4 | Bilobed nucleus, large eosinophilic granules |
| Basophils | Granulocyte | 0.5-1 | Bilobed nucleus, coarse basophilic granules |
| Lymphocytes (T, B, NK) | Agranulocyte | 20-40 | Round nucleus, minimal cytoplasm |
| Monocytes | Agranulocyte | 2-8 | Indented nucleus, abundant grayish cytoplasm |
Immune functions
White blood cells, also known as leukocytes, are essential effectors in the immune system, providing rapid defense against pathogens through innate mechanisms and long-term adaptive responses. In innate immunity, these cells offer immediate, non-specific protection, while adaptive immunity involves antigen-specific recognition and memory formation. This dual system enables leukocytes to detect, engulf, and eliminate threats, as well as coordinate broader immune activation.[68] In the innate immune response, neutrophils are primary responders that perform phagocytosis to engulf and destroy bacteria and fungi via lysosomal enzymes and reactive oxygen species. They also release neutrophil extracellular traps (NETs), web-like structures of DNA and antimicrobial proteins that trap and kill pathogens extracellularly, particularly effective against larger microbes or biofilms. Eosinophils contribute to defense against parasitic infections by releasing cytotoxic granules containing major basic protein and eosinophil peroxidase, which damage helminth exoskeletons, while also contributing to allergic and inflammatory responses through the release of their granule contents, such as major basic protein and eosinophil cationic protein, and lipid mediators like leukotrienes.[69] Basophils and mast cells, though distinct in location (basophils circulate, mast cells reside in tissues), both participate in IgE-mediated hypersensitivity; upon allergen cross-linking of IgE bound to FcεRI receptors, they degranulate to release histamine, leukotrienes, and cytokines, initiating type I hypersensitivity and promoting inflammation against parasites. Monocytes, upon tissue migration, differentiate into macrophages or dendritic cells that phagocytose debris and present antigens via MHC class II molecules to bridge innate and adaptive immunity, enhancing T-cell activation.[70][71][72][73] Adaptive immunity relies on lymphocytes for targeted responses. T lymphocytes, or T cells, include cytotoxic CD8+ subsets that recognize viral or tumor antigens on MHC class I, inducing apoptosis in infected cells through perforin and granzymes. Helper CD4+ T cells secrete cytokines to amplify responses and support other immune cells. B lymphocytes produce antibodies upon antigen stimulation, neutralizing pathogens and marking them for phagocytosis or complement activation, with memory B cells ensuring rapid secondary responses. Natural killer (NK) cells, bridging innate and adaptive immunity, perform natural cytotoxicity against virus-infected or cancerous cells lacking MHC class I, using perforin and granzymes without prior sensitization.[74][75] Leukocyte migration to infection sites involves diapedesis, the transmigration across endothelium, mediated by selectins for initial rolling, integrins for firm adhesion, and PECAM-1 for junctional crossing, allowing paracellular or transcellular passage. Chemotaxis follows, directed by chemokines such as IL-8 (CXCL8), which binds CXCR1/2 receptors on neutrophils to guide their directional movement via actin polymerization and pseudopod extension toward inflammatory signals.[76][77] Immune coordination occurs through cytokine networks, where interferon-gamma (IFN-γ), produced by NK cells, T cells, and macrophages, amplifies responses by activating macrophages for enhanced phagocytosis, promoting Th1 differentiation, and upregulating MHC expression for better antigen presentation. This pleiotropic cytokine sustains inflammation while preventing overactivation through feedback loops.[78]Production and circulation
White blood cells, or leukocytes, are produced through a process known as leukopoiesis, which encompasses the differentiation of hematopoietic stem cells into various leukocyte lineages. Granulopoiesis, the production of granulocytes such as neutrophils, eosinophils, and basophils, occurs primarily in the bone marrow from myeloid progenitors.[79] Lymphopoiesis, on the other hand, generates lymphocytes; B cells mature in the bone marrow, while T cells develop in the thymus.[79] The release of leukocytes from the bone marrow into circulation is tightly regulated by specific factors. Granulocyte colony-stimulating factor (G-CSF) plays a central role in promoting the mobilization of neutrophils, acting as an essential regulator under basal conditions by signaling through the G-CSF receptor to facilitate their entry into the bloodstream.[80] Additionally, leukocyte counts exhibit diurnal variations, with granulocytes typically peaking in the late afternoon and lymphocytes showing nocturnal elevations, influenced by circadian rhythms in hormone levels and sleep-wake cycles.[81] Once in circulation, leukocytes maintain dynamic movement and distribution. Neutrophils have a short lifespan of hours to days in the blood, whereas lymphocytes can persist for years, enabling long-term immune surveillance.[82] A portion of circulating neutrophils participates in margination, adhering loosely to vascular endothelium, which allows rapid response to inflammatory signals; upon activation, they undergo extravasation, migrating across the vessel wall into tissues via diapedesis.[82] Homeostasis of leukocyte populations relies on bone marrow reserves, where a large pool of mature neutrophils is stored for quick release, ensuring steady circulating levels.[82] During stress, such as acute physiological challenges, cortisol induces stress leukocytosis by redistributing leukocytes from marginal pools and the bone marrow into circulation, enhancing immune readiness.[83] Leukocyte turnover is primarily managed through programmed cell death and clearance mechanisms. Aged or activated leukocytes undergo apoptosis, after which they are efficiently phagocytosed by macrophages in tissues and the spleen, preventing inflammation from cellular debris.[84] This process maintains immune balance and supports continuous renewal from the bone marrow.[84]Platelets
Structure and formation
Platelets, also known as thrombocytes, are small, anucleate cellular fragments derived from the cytoplasm of megakaryocytes in the bone marrow.[85] They exhibit a discoid shape, typically measuring 2-4 μm in diameter, which allows them to circulate efficiently in the bloodstream while remaining responsive to vascular injury.[85] This structure is supported by a marginal band of microtubules that maintains the discoid form under resting conditions.[86] The internal composition of platelets includes specialized organelles essential for their role in hemostasis. Alpha granules, the most abundant type, store proteins such as fibrinogen and platelet-derived growth factor (PDGF), which are released upon activation to promote clot formation and tissue repair.[85] Dense granules contain smaller molecules, including adenosine diphosphate (ADP), serotonin, and calcium ions, that amplify platelet aggregation and vasoconstriction.[85] Additionally, the open canalicular system (OCS) forms a network of surface-connected channels that facilitates the uptake of plasma proteins and the secretion of granule contents during platelet activation.[86] Platelet formation, or thrombopoiesis, begins with megakaryopoiesis, the differentiation of hematopoietic stem cells into megakaryocyte progenitors within the myeloid lineage.[86] Mature megakaryocytes, which are large polyploid cells resulting from endomitosis, extend long, branched proplatelet processes through the endothelial sinuses of the bone marrow into the circulation.[86] These proplatelets undergo fragmentation, shedding approximately 2,000-5,000 platelets per megakaryocyte, with the process driven by cytoskeletal rearrangements and blood shear forces.[87] The production of platelets is primarily regulated by thrombopoietin (TPO), a cytokine mainly synthesized in the liver and kidneys.[88] TPO binds to the c-Mpl receptor on megakaryocyte progenitors, stimulating their commitment, proliferation, and maturation to maintain steady-state platelet levels in the blood.[89] This feedback mechanism ensures that platelet counts remain within the normal range of 150,000-450,000 per microliter, adjusting to physiological demands.[85]Role in hemostasis
Platelets play a crucial role in hemostasis, the process that prevents blood loss following vascular injury, primarily through primary hemostasis where they form a plug at the site of damage. Upon endothelial disruption, circulating platelets adhere to the exposed subendothelial matrix, particularly collagen, via the glycoprotein Ib-IX-V (GPIb-IX-V) complex binding to von Willebrand factor (vWF), which tethers platelets under high shear conditions.[90] This initial adhesion, mediated by the GPIbα subunit of GPIb-IX-V interacting with the A1 domain of vWF, slows platelets and allows subsequent firm attachment.[91] Adhered platelets then activate, undergoing shape change from discoid to spherical with pseudopod extension, and recruit additional platelets through aggregation.[92] Platelet activation triggers the conformational change in glycoprotein IIb/IIIa (GPIIb/IIIa, also known as αIIbβ3 integrin), exposing its fibrinogen-binding site and enabling bridging between platelets to form a stable aggregate.[93] Fibrinogen acts as a multivalent ligand, binding to GPIIb/IIIa on adjacent activated platelets, thereby crosslinking them and amplifying the hemostatic plug formation.[94] This aggregation step is essential for primary hemostasis, as deficiencies in GPIIb/IIIa, as seen in Glanzmann thrombasthenia, severely impair clot formation.[95] Activated platelets release contents from their dense and alpha granules, further propagating the hemostatic response. Dense granules discharge adenosine diphosphate (ADP) and thromboxane A2 (TxA2), potent agonists that bind to P2Y12 and TP receptors on nearby platelets, respectively, enhancing activation and recruitment in a positive feedback loop.[96] Additionally, serotonin released from dense granules induces local vasoconstriction, reducing blood flow to the injury site and supporting plug stability.[97] These mediators collectively amplify platelet aggregation without requiring external stimuli beyond the initial injury.[5] In secondary hemostasis, platelets provide a procoagulant surface that accelerates the coagulation cascade. Upon activation, platelets externalize phosphatidylserine on their outer membrane, forming a negatively charged phospholipid platform that assembles coagulation factor complexes, such as the tenase (factor IXa-VIIIa) and prothrombinase (factor Xa-Va).[98] This surface markedly enhances the activation of factor X to Xa by factor IXa, a rate-limiting step in thrombin generation, thereby promoting fibrin formation to reinforce the platelet plug.[99] Without this platelet-derived phospholipid environment, coagulation efficiency would be drastically reduced.[97] To limit excessive thrombosis and ensure vascular patency, platelets contribute to clot resolution through retraction and programmed cell death-like processes. Clot retraction involves actin-myosin interactions within platelets, contracting the fibrin network to consolidate the hemostatic plug and facilitate wound healing. Concurrently, pro-apoptotic signals, such as exposure to thrombin or shear stress, induce platelet phosphatidylserine externalization and microparticle shedding, marking senescent platelets for clearance and preventing unwarranted clot propagation. These mechanisms balance hemostasis by confining clot formation to the injury site.Lifecycle and regulation
Platelets have a circulating lifespan of approximately 7 to 10 days in healthy individuals, during which they maintain hemostasis before being cleared from circulation.[100] About one-third of the total platelet mass is sequestered in the spleen under normal conditions, forming an exchangeable pool that can be mobilized during stress or increased demand, while the remainder circulates freely in the blood.[101] This sequestration helps regulate platelet availability without significantly impacting circulating counts in the absence of splenic pathology.[102] As platelets age, they undergo senescence marked by desialylation of surface glycoproteins, particularly glycoprotein Ibα, which exposes underlying galactose residues.[103] These desialylated platelets are recognized and cleared primarily by the Ashwell-Morell receptor (AMR) on hepatocytes in the liver, initiating their removal from circulation to prevent dysfunctional cells from contributing to thrombosis or inflammation.[104] This receptor-mediated process ensures efficient turnover, with the liver playing a dominant role in steady-state clearance alongside minor contributions from the spleen and macrophages.[105] Platelet numbers are tightly regulated through feedback mechanisms involving thrombopoietin (TPO), the primary hormone controlling megakaryocyte maturation and platelet production; TPO levels in plasma are inversely proportional to circulating platelet mass, as platelets bind and internalize TPO via their c-Mpl receptors, thereby limiting its availability when counts are high.[106] During inflammation, interleukin-6 (IL-6) enhances thrombopoiesis by upregulating hepatic TPO production through JAK2-STAT3 signaling, providing a rapid compensatory response to increased platelet consumption or destruction.[107] This dynamic regulation maintains homeostasis, with approximately 10^{11} platelets produced and removed daily in adults to sustain a circulating count of 150–450 × 10^9/L.[108] In pathological states, such as immune thrombocytopenia, accelerated platelet destruction occurs when autoantibodies target platelet surface antigens, leading to phagocytosis by macrophages in the spleen and liver, which shortens lifespan and reduces circulating numbers below 100 × 10^9/L.[109] This immune-mediated clearance disrupts the normal TPO feedback loop, often prompting compensatory increases in production, though it may not fully offset the loss in severe cases.[110]Clinical aspects
Complete blood count
The complete blood count (CBC), also known as a full blood count, is a common laboratory test that evaluates the overall health and detects a wide range of disorders, such as anemia, infection, and many other diseases, by measuring the quantities and proportions of various blood cells.[111] It provides quantitative data on red blood cells (RBCs), white blood cells (WBCs), and platelets, along with derived parameters that aid in diagnosis.[112] Key components of a CBC include the RBC count, which quantifies the number of red blood cells; hemoglobin (Hgb), measuring the oxygen-carrying protein in RBCs; and hematocrit (Hct), the proportion of blood volume occupied by RBCs.[111] The WBC count assesses total white blood cells, with a differential breaking it down into subtypes such as neutrophils, lymphocytes, monocytes, eosinophils, and basophils to identify immune responses. Platelet count evaluates the number of thrombocytes essential for clotting.[112] The test is primarily performed using automated hematology analyzers, which employ electrical impedance (Coulter principle) to measure cell volume and count by detecting changes in electrical resistance as cells pass through an aperture, and flow cytometry, which uses lasers and fluorescent dyes to classify cells based on size, granularity, and specific markers.[112] For detailed morphological assessment, a manual peripheral blood smear is examined under a microscope after staining, often when automated results flag abnormalities.[113] Normal reference values vary by age, sex, and laboratory but generally include: for adult males, RBC 4.3-5.9 × 10^6/μL, hemoglobin 13.5-17.5 g/dL, hematocrit 41-53%, WBC 4.5-11.0 × 10^3/μL, and platelets 150-450 × 10^3/μL; for adult females, RBC 3.5-5.5 × 10^6/μL, hemoglobin 12.0-16.0 g/dL, hematocrit 36-46%, with WBC and platelet ranges similar to males.[114]| Parameter | Adult Males | Adult Females | Unit |
|---|---|---|---|
| RBC count | 4.3-5.9 × 10^6 | 3.5-5.5 × 10^6 | /μL |
| Hemoglobin | 13.5-17.5 | 12.0-16.0 | g/dL |
| Hematocrit | 41-53 | 36-46 | % |
| WBC count | 4.5-11.0 × 10^3 | 4.5-11.0 × 10^3 | /μL |
| Platelet count | 150-450 × 10^3 | 150-450 × 10^3 | /μL |