Blood plasma is the light yellow, straw-colored liquid portion of blood that suspends blood cells and constitutes approximately 55% of total blood volume.[1][2] It comprises over 90% water, with the balance formed by dissolved proteins, electrolytes, nutrients, hormones, enzymes, and waste products.[1][3]As the intravascular compartment of extracellular fluid, plasma maintains osmotic and hydrostatic pressure to regulate fluid balance across capillary walls, facilitates the transport of respiratory gases, nutrients, metabolic wastes, and signaling molecules throughout the body, and supplies essential clotting factors and immunoglobulins for hemostasis and immunity.[1][4] In clinical practice, plasma transfusions restore volume and coagulation in cases of acute hemorrhage, trauma, burns, or liver failure, while plasmapheresis and fractionation processes yield concentrated therapeutics such as albumin for hypovolemia, clotting factor concentrates for hemophilia, and immunoglobulins for immunodeficiency or autoimmune disorders.[5][6] The development of plasma separation and preservation techniques, notably during World War II, enabled large-scale banking and dried plasma for battlefield transfusions, markedly reducing mortality from shock and exsanguination.[7][8]
Composition and Properties
Chemical Composition
Blood plasma is composed predominantly of water, which constitutes 91-92% of its volume, providing the solvent medium for transport and osmotic balance. The remaining 8-9% consists of solutes, primarily proteins (approximately 7% by weight), electrolytes (about 0.9%), and minor components including glucose, lipids, hormones, vitamins, and metabolic wastes such as urea and creatinine.[1][9] These proportions maintain plasma's viscosity and density at around 1.025 g/mL, facilitating circulation.[10]The protein fraction totals 6.4-8.3 g/dL, with albumin comprising the majority at 3.5-5.0 g/dL, responsible for 80% of the oncotic pressure that prevents fluid leakage from capillaries. Globulins, at 2.3-3.4 g/dL, include alpha, beta, and gamma fractions; the latter primarily immunoglobulins for immune defense, while alpha and beta globulins serve transport roles for lipids, metals, and hormones. Fibrinogen, a clotting factor, is present at 0.2-0.4 g/dL. Other minor proteins like regulatory enzymes and complement factors contribute to hemostasis and immunity.[11][12]Electrolytes, essential for membrane potentials, pH balance, and osmotic pressure, are present in millimolar concentrations. Major cations include sodium (135-145 mmol/L), the principal extracellular ion; potassium (3.6-5.5 mmol/L); calcium (2.15-2.55 mmol/L ionized form); and magnesium (0.70-1.15 mmol/L). Anions comprise chloride (98-106 mmol/L), bicarbonate (22-28 mmol/L for pH buffering), and phosphate (0.8-1.5 mmol/L). These ions total roughly 150-160 mEq/L, dominated by sodium chloride equivalents.[13][14]
Electrolyte
Normal Plasma Concentration (mmol/L)
Sodium (Na⁺)
135-145
Potassium (K⁺)
3.6-5.5
Chloride (Cl⁻)
98-106
Bicarbonate (HCO₃⁻)
22-28
Calcium (total)
2.15-2.55
Organic solutes include glucose (3.9-5.6 mmol/L), amino acids (2-3 mmol/L total), and urea (2.5-7.5 mmol/L), reflecting metabolic status. Lipids such as cholesterol and triglycerides are transported bound to lipoproteins, with trace amounts of free fatty acids. Hormones and vitamins occur in nanomolar to picomolar ranges, underscoring plasma's role in endocrine signaling.[1] Variations in composition occur due to hydration status, diet, and pathology, but reference ranges define homeostasis.[15]
Physical Properties
Blood plasma is a clear, straw-colored or light-yellowish fluid that constitutes the liquid portion of blood after removal of cellular components.[1][9] Its appearance can vary slightly due to factors such as diet, hydration, or lipid levels; for instance, lipemic plasma exhibits a milky or turbid quality from excess triglycerides and chylomicrons.[16]The density of human blood plasma ranges from 1.022 to 1.029 g/mL at standard conditions, reflecting its high water content (91–92%) and dissolved solutes.[1][17]Plasma behaves as a Newtonian fluid, with shear viscosity independent of applied shear rate and measuring approximately 1.3 mPa·s at physiological temperature (37°C).[18] This viscosity is influenced primarily by protein concentration, particularly fibrinogen and globulins, and increases with elevated levels in conditions like inflammation.[18]The pH of plasma is tightly regulated between 7.35 and 7.45 to support enzymatic and metabolic functions.[19]Freezing point depression occurs due to colligative effects of solutes, lowering the freezing point to about -0.52°C relative to pure water.[20]
Blood plasma serves as the primary medium for the transport of dissolved substances throughout the circulatory system, facilitating the delivery of essential molecules from sites of production or absorption to tissues requiring them.[1] It carries nutrients such as glucose, amino acids, and lipids—primarily in the form of lipoproteins—to cells for energy production and biosynthesis, with plasma glucose concentrations typically maintained at 70-99 mg/dL in fasting adults.[2] Vitamins, including water-soluble ones like vitamin C and B-complex, and fat-soluble vitamins bound to carriers, are also disseminated via plasma to support enzymatic functions and antioxidant defenses.[9]Hormones produced by endocrine glands, such as insulin from the pancreas and thyroxine from the thyroid, are transported in plasma to target organs, enabling coordinated physiological responses; for instance, cortisol levels in plasma range from 6-23 μg/dL in the morning, influencing metabolism and stressadaptation.[1] Plasma proteins like albumin bind and shuttle hydrophobic hormones and drugs, preventing their rapid clearance and ensuring bioavailability.[21] Electrolytes, including sodium (135-145 mEq/L) and potassium (3.5-5.0 mEq/L), maintain osmotic balance and are carried to regulate cellular membrane potentials and nerve impulses.[9]Metabolic waste products, such as urea (7-20 mg/dL), creatinine (0.6-1.2 mg/dL), and bilirubin, are conveyed from tissues to the kidneys and liver for excretion or processing, preventing toxic accumulation.[2] A portion of respiratory gases dissolves directly in plasma—accounting for about 3% of oxygen and 7% of carbon dioxide transport—while bicarbonate ions in plasma handle the majority of CO2 carriage via the carbonic anhydrase-catalyzed reaction in red blood cells.[1] This transport system relies on plasma's high water content (approximately 92%) and protein buffering to sustain solubility and prevent precipitation of solutes during circulation.[21]
Regulatory Functions
Blood plasma plays a critical role in acid-base homeostasis primarily through the bicarbonate buffer system, which maintains arterial pH between 7.35 and 7.45. This system relies on the reversible reaction between dissolved carbon dioxide (CO₂), water, and the bicarbonateion (HCO₃⁻), catalyzed by carbonic anhydrase in red blood cells but effective in plasma: CO₂ + H₂O ⇌ H₂CO₃ ⇌ H⁺ + HCO₃⁻. Excess H⁺ ions from metabolic acids are buffered by HCO₃⁻, forming H₂CO₃, which dissociates into CO₂ and H₂O for pulmonary excretion, while respiratory CO₂ levels influence the equilibrium to prevent alkalosis./Acids_and_Bases/Buffers/Blood_as_a_Buffer)[1]Plasma proteins, including albumin and globulins, provide an additional buffering capacity by binding free H⁺ ions, contributing about 15-20% to overall blood buffering despite comprising a smaller portion compared to the bicarbonate system. These proteins maintain plasma pH slightly alkaline (around 7.4) by accepting protons during acidosis, with their negative charges facilitating ion interactions. Disruptions, such as hypoalbuminemia, can impair this function, leading to acidosis in conditions like liver disease.[1][21]In fluid volume regulation, plasma sustains oncotic pressure through its high concentration of colloids, primarily albumin (approximately 4 g/dL), which generates about 80% of the 25-28 mmHg colloid osmotic pressure in capillaries. This counteracts hydrostatic pressure, drawing fluid back into vessels via Starling forces and preventing edema; low oncotic pressure from protein loss (e.g., nephrotic syndrome) causes hypovolemia. Plasma osmolality, dominated by electrolytes like Na⁺ (135-145 mEq/L) and Cl⁻ alongside proteins and glucose, totals 275-295 mOsm/kg, ensuring osmotic equilibrium across compartments and influencing antidiuretichormone release for water retention.[22][23]Electrolyte homeostasis in plasma supports nerve and muscle function, with ions such as K⁺ (3.5-5.0 mEq/L) and Ca²⁺ (ionized fraction ~1.1-1.3 mmol/L) regulated by renal filtration, parathyroid hormone, and aldosterone to stabilize membrane potentials and prevent arrhythmias. Plasma acts as the dynamic reservoir, where deviations trigger compensatory mechanisms like the renin-angiotensin-aldosterone system to restore balance.[24]
Coagulation and Immune Support
Blood plasma contains the majority of clotting factors essential for hemostasis, including fibrinogen (factor I), prothrombin (factor II), and factors V, VII, VIII, IX, X, XI, XII, and XIII, which are predominantly liver-synthesized glycoproteins circulating in inactive forms.[25][1] Upon vascular endothelial damage, these factors initiate the extrinsic and intrinsic coagulation pathways, culminating in the conversion of prothrombin to thrombin, which cleaves fibrinogen into fibrin monomers that polymerize into a stabilizing mesh entrapping platelets and red blood cells to form a hemostatic plug.[25] This secondary hemostasis process prevents excessive blood loss, with plasma-derived factor deficiencies—such as in hemophilia A (factor VIII) or B (factor IX)—resulting in prolonged bleeding times and joint hemorrhages, as evidenced by prothrombin time (PT) and activated partial thromboplastin time (aPTT) assays that measure plasma coagulability.[1][26]In immune support, plasma transports immunoglobulins, primarily IgG (75-80% of total), IgA, and IgM, secreted by plasma cells to provide adaptive humoral immunity by binding antigens on pathogens, facilitating phagocytosis or neutralization.[27] Complement proteins, comprising over 30 soluble components like C3 and C1q predominantly in plasma, amplify innate and adaptive responses through three activation pathways: classical (antibody-initiated), alternative (spontaneous on foreign surfaces), and lectin (carbohydrate recognition).[28][29] These pathways generate opsonins for enhanced phagocytosis, anaphylatoxins (C3a, C5a) for inflammation and immune cell recruitment, and the membrane attack complex (C5b-9) for direct lysis of bacteria and infected cells, with deficiencies in plasma complement levels linked to recurrent infections as seen in hereditary angioedema or meningococcal susceptibility.[30][31] Plasma also carries acute-phase proteins like C-reactive protein (CRP), upregulated during inflammation to bind microbial phosphocholine and activate complement, underscoring plasma's role in bridging coagulation and immunity to maintain vascular integrity against infection-induced damage.[1][32]
Medical Applications
Transfusion and Volume Expansion
Fresh frozen plasma (FFP), prepared by freezing plasma within eight hours of collection and storing at -18°C or colder for up to one year, serves as a source of coagulation factors, proteins, and volume in transfusion medicine.[33] It is primarily indicated for patients with deficiencies in multiple coagulation factors, evidenced by prolonged prothrombin time (PT) or international normalized ratio (INR >1.5), coupled with active bleeding or high risk of hemorrhage, such as in massive transfusion protocols for trauma.[33][34] The standard dose is 10-20 mL/kg body weight, equivalent to 4-8 units in adults, aiming to achieve a 15-30% increase in factor levels and partial correction of coagulopathy.[35]While plasma provides oncotic pressure for volume expansion in hypovolemic states like hemorrhagic shock, guidelines caution against its use solely for this purpose without coagulopathy, favoring crystalloids or albumin to avoid unnecessary exposure to allogeneic proteins.[36] Systematic reviews of randomized trials indicate limited evidence for FFP's prophylactic efficacy in preventing bleeding or mortality across indications, including isolated hypovolemia, with no significant benefits over alternatives in non-bleeding scenarios.[37] In contrast, early plasma administration in balanced ratios (1:1:1 with red cells and platelets) during massive transfusion has shown associations with reduced mortality in trauma, potentially mitigating dilutional coagulopathy and endothelial damage.[38] Prehospital plasma transfusion, including lyophilized forms, demonstrates feasibility and possible survival benefits in high-risk hemorrhagic shock, though larger trials are needed to confirm causality.[39][40]Transfusion requires ABO compatibility to minimize hemolytic reactions, with thawing in a 37°C water bath taking 20-30 minutes before infusion over 30-120 minutes.[33] Risks include transfusion-related acute lung injury (TRALI), transfusion-associated circulatory overload (TACO), allergic/anaphylactic reactions, and febrile non-hemolytic responses, occurring at rates of approximately 1:5,000 for TRALI and higher for volume overload in vulnerable patients.[41][33] Infectious transmission risks, such as viral agents, have diminished with donor screening and pathogen reduction technologies, but remain a consideration.[42] Overuse for volume expansion without indicated coagulopathy contributes to inventory strain and potential harm without proportional benefit, underscoring the need for targeted application based on clinical and laboratory evidence.[43]
Fractionated Plasma Products
Fractionation of human plasma involves the separation of its protein components into therapeutic concentrates using physicochemical methods, primarily cold ethanol precipitation pioneered by Edwin J. Cohn and colleagues in the early 1940s.[44] The process sequentially adjusts variables such as ethanol concentration (up to 40%), pH (typically 4.8–7.2), ionic strength, temperature (around -5°C to 20°C), and protein concentration to exploit solubility differences, yielding five primary fractions labeled I through V.[45] Fraction I precipitates fibrinogen and prothrombin complex; Fractions II and III yield immunoglobulins and other gamma globulins; Fraction IV isolates alpha and beta globulins, including protease inhibitors; and Fraction V provides albumin after further purification.[45] Subsequent refinements, such as the Cohn-Oncley method, enhanced yields and purity, enabling large-scale production from recovered or source plasma collected via plasmapheresis.[46]These fractions undergo additional chromatographic purification, stabilization (e.g., with glycine or sugars), and pathogen inactivation steps—including solvent/detergent treatment, pasteurization at 60°C for 10 hours, and nanofiltration with 20–35 nm pores—to minimize risks from enveloped and non-enveloped viruses, prions, and bacteria while preserving protein functionality.[47] The multi-step nature of fractionation, combined with donor screening and nucleic acid testing, achieves log reductions exceeding 12–20 for major pathogens like HIV, hepatitis B/C, and parvovirus B19, rendering products safer than single-donor plasma transfusions.[48] Approximately 20 distinct plasma-derived therapeutics are produced globally, with annual fractionation volumes reaching around 50 million liters as of 2018, primarily in the United States, Europe, and Australia.[49][47]Key fractionated products and their primary clinical uses include:
Product
Derived From
Principal Indications
Albumin (human, 5% or 25% solutions)
Fraction V
Hypovolemia, burns, hypoalbuminemia, and as a priming fluid in cardiopulmonary bypass; provides oncotic pressure without coagulation risks.[50]
Intravenous immunoglobulin (IVIG)
Fractions II+III
Primary immunodeficiencies (e.g., common variable immunodeficiency), idiopathic thrombocytopenic purpura, and Kawasaki disease; replaces missing antibodies.[47][50]
Coagulation Factor VIII concentrate
Fraction I (with cryo-precipitate)
Hemophilia A; replaces deficient clotting factor to prevent bleeding episodes.[50]
Factor IX complex (prothrombin complex concentrates)
Fraction I/II+
Hemophilia B and reversal of vitamin K antagonist-induced coagulopathy.[50]
Hereditary angioedema; regulates complement and kinin pathways to prevent attacks.[50]
These products treat rare and chronic conditions affecting over 300 diseases, often as the sole biologics option when recombinant alternatives are unavailable or less effective.[47]Production is regulated by bodies like the FDA, requiring biologics license applications and adherence to current good manufacturing practices to ensure potency, purity, and sterility.[51] Despite advances, supply constraints persist due to reliance on paid plasma donation, with the U.S. supplying about 70% of global needs as of recent estimates.[49]
Diagnostic Uses and Comparison to Serum
Blood plasma is employed in clinical diagnostics primarily for assays requiring the preservation of clotting factors and other coagulation-related components, such as prothrombin time (PT), activated partial thromboplastin time (aPTT), and fibrinogen levels, where platelet-poor plasma (PPP) is standardized by centrifugation to remove cellular elements.[52] It also serves as a matrix for measuring electrolytes, proteins, and biomarkers in tests like therapeutic drug monitoring and certain metabolic panels, offering advantages in processing speed since anticoagulation prevents clotting delays.[53] Plasma's utility extends to immunodiagnostic tests for parasitic diseases, where it provides a stable fluid for antibody detection without the artifacts from coagulation.[54]In comparison, serum is derived from clotted blood and lacks fibrinogen and most clotting factors, making it unsuitable for coagulation studies but preferable for many routine chemistry panels, as laboratory reference intervals are typically validated using serum samples.[55] Plasma yields 15%–20% more volume per blood draw than serum due to the absence of clot formation, reducing the volume of blood needed from patients and minimizing hemolysis risk during handling.[56] However, plasma anticoagulants like heparin or EDTA can interfere with specific assays (e.g., calcium measurements with EDTA), whereas serum avoids such interferences but requires 30 minutes or more for clotting, potentially delaying turnaround times.[57] Plasma is favored when analytes might degrade during clotting, preserving a more physiological snapshot for studies in metabolomics or lipidomics, though serum often exhibits greater analyte stability for long-term storage.[58] Selection between plasma and serum depends on the test: plasma for dynamic processes like coagulation or rapid processing needs, and serum for hormone, enzyme, or protein analyses where clotting factor absence is beneficial.[59]
Donation and Supply Chain
Collection Methods
Blood plasma for medical use is collected primarily through two methods: recovery from whole blood donations and direct collection via automated plasmapheresis. In the recovery method, a standard whole blood donation of approximately 450-500 milliliters is centrifuged post-collection to separate plasma, yielding about 200-300 milliliters of plasma per unit after accounting for the hematocrit.[60] This approach supplies a smaller fraction of plasma for fractionation compared to apheresis, as whole blood donations prioritize red cell components for transfusion.[61]Automated plasmapheresis dominates source plasma collection, enabling higher yields while returning cellular components to the donor. During the procedure, blood is withdrawn from a donor's antecubital vein via a single or dual-lumen needle and anticoagulated with citrate to prevent clotting. The anticoagulated blood enters the apheresis machine, where continuous centrifugation separates plasma from red blood cells and platelets based on density gradients; plasma, being the lightest fraction, is expressed into a collection bag.[62] The remaining components, along with saline for volume replacement, are reinfused to the donor, typically completing the process in 45-90 minutes.[63] Machines such as centrifugation-based systems ensure sanitary, closed-loop operation to minimize contamination risks.[64]Plasma volume collected per plasmapheresis session varies by donor factors including weight, height, sex, and hematocrit, with U.S. Food and Drug Administration guidelines capping it at levels safe for frequent donation, often 625-880 milliliters including anticoagulant.[65] Mean yields approximate 760 milliliters, supporting collections up to twice weekly for qualified donors under regulatory oversight.[66] Donor screening, including hemoglobin checks and vital signs monitoring, precedes each procedure to ensure safety, with plasmapheresis regulated as a source plasma collection under 21 CFR Part 640 to maintain quality for therapeutic fractionation.[62]
Global Practices: Incentives and Regulations
The United States dominates global source plasma collection, supplying approximately 70% of the world's plasma used for fractionation into therapies, largely due to a compensated donation model regulated by the Food and Drug Administration (FDA).[67][68] Donors receive monetary payments typically ranging from $30 to $100 per donation, with frequent donors potentially earning up to $1,000 monthly, which incentivizes high-volume participation at over 900 commercial centers.[69] FDA regulations permit plasma donation up to twice within a seven-day period, provided at least 48 hours elapse between sessions, with mandatory screening for infectious diseases including HIV, hepatitis B and C, and syphilis, alongside hemoglobin checks and medical history reviews to ensure donor safety.[70][71] These rules, including a 30-day quarantine hold for initial donations, maintain product safety despite high frequency, with studies confirming no long-term health impairment from regulated plasmapheresis.[72]In contrast, the European Union adheres to a principle of voluntary unpaid donations under Council of Europe guidelines and recent EU regulations on substances of human origin (SoHO), emphasizing altruism to minimize risks from incentivized donors who might conceal health issues.[73][74] However, this approach has led to chronic shortages, with the EU importing 37-40% of its plasma from the US, prompting debates over self-sufficiency.[75][76] Exceptions exist in countries like Austria, Germany, Hungary, Czechia, and Latvia, where fixed-rate compensation—often €25-€50 per donation—is permitted to cover time and inconvenience without constituting full payment, boosting local collections by 3-6% annually in recent years.[77] EU rules now allow member states flexibility for such reimbursements to avoid competitive disadvantages, while mandating rigorous pathogen testing and donor deferral criteria similar to FDA standards.[78]Globally, incentives vary from cash payments in the US and select others to non-monetary perks like refreshments or tax credits elsewhere, with meta-analyses showing monetary compensation increases donation rates short-term at costs of $22-121 per additional unit, without evidence of elevated infectious disease transmission when screening protocols are enforced.[79][80] The World Health Organization endorses voluntary non-remunerated donations for ethical safety reasons but acknowledges shortages in low-incentive regions, where empirical data indicate compensated models expand supply for life-saving derivatives like immunoglobulins without causal links to poorer product quality.[81] In developing countries, regulations often mirror WHO standards with limited infrastructure for paid collection, relying on occasional voluntary drives amid variable enforcement.[82] Critics of unpaid systems, including economic analyses, argue they reflect ideological preferences over evidence-based supply maximization, as US exports have filled gaps without reported safety failures.[73][68]
Donor Health Risks and Ethical Debates
Plasma donation via plasmapheresis involves apheresis machines that separate plasma from blood cells, returning the latter to the donor, which can lead to acute adverse events such as hypotension, citrate-induced hypocalcemia causing paresthesia or tetany, and phlebotomy-related issues like bruising or infiltration.[83] In U.S. source plasma collections, the overall adverse event rate stands at 15.85 per 10,000 donations, with hypotensive events at 8.32 per 10,000 and phlebotomy events at 5.91 per 10,000, predominantly among repeat donors who comprise nearly 93% of collections.[83] These events are generally mild and self-limiting, with fatalities rare; FDA reports from 2016-2018 noted only five plasma donation-related deaths, often without clear causation established.[84]Long-term risks from frequent donation, permitted up to twice weekly under FDA guidelines (equivalent to about 104 times annually), include potential depletion of plasma proteins like immunoglobulins (IgG, IgA, IgM) and albumin, as well as iron stores leading to ferritin reductions.[85] Randomized trials have shown significant IgG declines below reference ranges in very high-frequency donors, alongside minor immune parameter shifts, though cellular immunity and overall health markers often remain stable even at volumes up to 45 liters per year.[86] Observational data link frequent plasma donation (>25 lifetime donations) to elevated odds of non-Hodgkin lymphoma (OR=2.14), possibly via immune alterations, while other studies report no increased malignancy risk or sustained protein deficits with regulatory limits.[87][88] Evidence on bone health, cardiovascular effects, or exercise performance shows minimal impact from repeated plasmapheresis.[89]Ethical debates center on compensated donation, dominant in the U.S. where payments of $20-50 per session incentivize supply but raise concerns of exploiting economically vulnerable populations, particularly low-income individuals reliant on plasma sales for essentials.[90] Critics argue payments coerce participation despite risks, potentially masking health issues or encouraging deception on eligibility, and note higher blood-borne infection rates in paid settings, as evidenced by hepatitis C prevalence in some donor cohorts.[91][92] Proponents counter that voluntary compensated donation enhances global plasma availability without inherent exploitation, akin to labor markets with minimum wages to prevent underpayment, and bans on payment—as in much of Europe—correlate with shortages forcing reliance on U.S. imports.[73] International disparities amplify scrutiny, with plasma-intensive therapies in wealthier nations sourced disproportionately from paid U.S. donors, prompting calls for equitable, non-exploitative models prioritizing donor well-being over ideological aversion to markets.[93]
Historical Context
Early Scientific Understanding
The fluid component of blood, later termed plasma, was implicitly recognized through early microscopic observations of blood's heterogeneous nature. In 1674, Dutch microscopist Antonie van Leeuwenhoek provided the first detailed description of red blood corpuscles, noting their disc-like shape and suspension in a transparent fluid medium, which distinguished the cellular elements from the surrounding liquor sanguinis.[94] Earlier, in the 1660s, Jan Swammerdam observed that blood cells remain stationary during circulation while the fluid flows, suggesting the plasma's role in transport.[1]Scientific separation and analysis of plasma advanced in the 18th century amid studies of coagulation. Theories of blood clotting traced to ancient Greek physicians like Galen, who described blood's transformation into a solid mass upon withdrawal, but lacked mechanistic insight or separation techniques.[94] British anatomist William Hewson, often called the father of hematology, achieved the first deliberate isolation of plasma from formed elements in 1770 by employing high concentrations of Glauber’s salt (sodium sulfate) as an anticoagulant, a method adapted from blood-processing practices like sausage making.[94] This prevented clotting, yielding uncoagulated plasma distinct from serum (the post-clot fluid).[94]Hewson's experiments further elucidated plasma's composition and function. He demonstrated that plasma alone, when allowed to coagulate, produced fibrin—the protein network of the clot—isolating fibrinogen as a soluble precursor therein, thus establishing plasma's causal role in hemostasis via protein precipitation rather than mere cellular aggregation.[94] Hewson also identified white blood cells (then "crassamentum inflammatorium") in plasma-derived lymph, linking plasma to immune responses through soluble factors.[94] These findings framed plasma as the nutrient- and waste-carrying matrix, comprising about 55% of blood volume, with salts, albumen, and globulins maintaining osmotic balance and viscosity.[1]By the late 19th century, plasma's protein fractions were quantified through chemical analysis, revealing albumins for oncotic pressure and globulins for potential antibody functions, though full fractionation awaited 20th-century techniques.[95] Early researchers viewed plasma's variability—e.g., turbidity in lipemic states or dilution in edema—as indicators of systemic health, informing rudimentary diagnostic uses before serological advancements.[1] This foundational understanding prioritized plasma's biophysical properties over speculative humoral theories, grounding hematology in observable separation and reconstitution experiments.[94]
World War II Mobilization
The mobilization of blood plasma production accelerated in response to World War II demands, particularly after the fall of France in 1940 prompted the "Blood for Britain" initiative, where plasma was collected and processed in the United States for shipment to aid British war casualties.[8] Dr. Charles R. Drew, appointed medical director of this program, oversaw the separation of plasma from whole blood, enabling its bottling in liter units and packaging for overseas transport, which extended shelf life and facilitated logistics compared to perishable whole blood.[96]Following U.S. entry into the war in December 1941, the American Red Cross launched a national Blood Donor Service in February 1941 to supply plasma for the armed forces, with the first commercial processing occurring on February 4, 1941, by Sharp & Dohme, Inc.[97] Eight commercial firms were contracted to process donated blood into dried plasma packages, allowing stockpiling and rapid deployment to combat zones where it treated shock from blood loss in wounded soldiers.[98] By war's end, the Red Cross had collected 13.3 million pints of blood, converting 10.3 million into plasma, which proved vital in theaters like Sicily, where medics administered it immediately post-injury to stabilize casualties before evacuation.[99][100]Parallel efforts advanced plasma fractionation, led by biochemist Edwin J. Cohn at Harvard, who in 1940 developed cold ethanol fractionation to isolate components like albumin for volume expansion without the risks of whole blood transfusions.[101] This method, scaled under the Office of Scientific Research and Development, yielded purified albumin solutions by 1943, enhancing military medical kits and reducing dependency on scarce whole blood supplies.[102] The plasma program's termination in September 1945 marked the shift from wartime exigency, though its innovations in preservation and fractionation laid foundations for post-war blood banking.[103]
Post-War Fractionation and Commercialization
Following World War II, plasma fractionation shifted from wartime exigencies to sustained commercial production, leveraging Edwin J. Cohn's cold ethanol precipitation method, which separated plasma proteins by adjusting ethanol concentration, pH, temperature, and ionic strength to isolate therapeutically useful components like albumin and immunoglobulins.[46][101] This process, refined during the war for military needs, enabled the scalable extraction of human serum albumin (HSA) as the primary initial product, with commercial output ramping up as demand transitioned to civilian applications such as treating hypovolemic shock, burns, and hypoalbuminemia.[104] By 1947, Cohn had delineated six major plasma fractions: Fraction I (fibrinogen and antihemophilic globulin), Fraction II (gamma globulins), Fraction III (beta and alpha globulins), and others yielding prothrombin, isoagglutinins, and albumin, providing a blueprint for targeted commercial yields.[105]In the United States, seven pharmaceutical firms that had supplied albumin to military specifications during the war—maintaining 96-99% purity through heat pasteurization at 60°C for 10 hours—continued and expanded production post-1945 under federal oversight, processing pooled plasma donations into sterile, stable solutions for broader medical distribution.[101] By December 1943, nine commercial laboratories were already engaged in dried plasma output, a capacity that persisted and grew after demobilization, with eight U.S. facilities by 1953 converting citrated blood into plasma, HSA, and derivatives for national stockpiles and hospital use.[106][97] This commercialization decoupled fractionation from nonprofit blood banks like the American Red Cross, which curtailed plasma processing in favor of whole blood, fostering a private industry focused on high-volume, quality-controlled protein therapeutics.[95]The post-war era saw fractionation yield additional derivatives beyond albumin, including immune serum globulin (ISG) from Fraction II, commercially licensed in the late 1940s for intramuscular prophylaxis against measles and hepatitis, with initial batches demonstrating efficacy in reducing disease incidence by providing passive antibodies.[105] Production efficiencies improved through larger-scale ethanol-based operations, though early challenges included variable protein stability and undetected viral contaminants like hepatitis, prompting iterative refinements in pooling (up to thousands of donors per lot) and pathogen inactivation.[46] Internationally, adoption accelerated; for instance, European transfusion centers implemented albumin fractionation protocols, while Australia established dedicated commercial facilities by the mid-20th century, processing up to 500 tonnes of plasma annually in multi-tonne batches.[107] This era marked the inception of the plasma products industry, prioritizing empirical yield optimization over whole plasma transfusion due to fractionation's advantages in concentrating bioactive proteins while discarding less stable elements.[108]
Alternatives and Innovations
Synthetic Plasma Substitutes
Synthetic plasma substitutes, primarily synthetic colloid solutions, serve as temporary volume expanders to mimic the oncotic pressure of blood plasma and restore intravascular volume in hypovolemic states such as hemorrhage, surgery, or shock, without providing coagulation factors or proteins found in natural plasma.[109] These agents include dextrans, hydroxyethyl starches (HES), and gelatin derivatives, which are designed for rapid administration and shelf stability, avoiding risks of pathogen transmission associated with donor plasma.[110] Unlike crystalloid solutions like 0.9% saline, synthetic colloids remain predominantly intravascular longer due to their larger molecular size, potentially requiring smaller infusion volumes for equivalent expansion.[111]Dextrans, branched polysaccharides produced via bacterial fermentation of sucrose, were first proposed as plasma expanders in 1943 by Swedish researchers and entered clinical use in the late 1940s, particularly dextran 70 (average molecular weight 70,000 Da) for sustained volume support up to 24 hours.[112] HES solutions, derived from modified amylopectinstarch, vary by substitution degree and molecular weight—examples include hetastarch (high MW, ~450 kDa) for prolonged effect and pentastarch (medium MW, ~200 kDa) for shorter duration—and were developed in the mid-20th century to address plasma shortages.[111] Gelatin-based colloids, hydrolyzed bovine collagen cross-linked for stability, include succinylated forms like Gelofusine and urea-linked polygeline (Haemaccel), offering brief expansion (2-4 hours) with minimal coagulation interference but higher diuresis rates.[110][113]Clinical efficacy of these substitutes centers on hemodynamic stabilization, with studies showing comparable short-term volume expansion to crystalloids or albumin in elective surgery and trauma, though without survival benefits in large trials.[114] For instance, dextrans improve microcirculatory flow but carry risks of anaphylactoid reactions (up to 0.07% incidence) and von Willebrand factor inhibition leading to bleeding.[115] HES formulations demonstrated no reduction in mortality or organ failure versus saline in high-risk surgical patients, per a 2020 randomized trial of 3,000 participants.[114] Gelatins provide effective initial resuscitation in sepsis models but meta-analyses indicate potential harm, including elevated anaphylaxis risk (1:13,000) and no clear advantage in renal outcomes over starches.[116][117]Concerns over synthetic colloids have intensified due to adverse effects: HES is linked to acute kidney injury (AKI), renal replacement therapy needs, and excess mortality in critically ill patients, as evidenced by the 2012 CHEST trial (7,000 ICU patients) showing 8% relative increase in RRT and FDA/EMA restrictions since 2013 limiting use outside perioperative settings.[118][119] Gelatins correlate with higher hospital mortality and bleeding in non-randomized studies, prompting cautious application.[120] These risks stem from dilutional coagulopathy, osmotic nephrosis, and immune activation, outweighing benefits in sepsis or trauma per subgroup analyses.[121]Current guidelines from bodies like the Surviving Sepsis Campaign prioritize balanced crystalloids (e.g., lactated Ringer's) as first-line for resuscitation, viewing synthetic colloids as optional for refractory hypovolemia but advising against HES in septic or renal-impaired patients due to lacking superiority and safety signals.[113] Dextrans and gelatins persist in select contexts like minor surgery, but overall adoption has declined amid evidence favoring restrictive strategies; emerging "supra-plasma" hyperviscous expanders aim to enhance oxygen delivery via rheological optimization, though clinical validation remains pending.[122]
Recent Technological and Therapeutic Advances
In plasma fractionation, recent innovations have emphasized chromatography-based purification and automation to enhance efficiency and product yield. By 2025, the integration of advanced chromatographic steps following traditional ethanol fractionation has enabled higher purity levels for therapeutics like immunoglobulins and coagulation factors, reducing impurities while scaling production for small-volume facilities.[46][123]Engineering modifications, such as jacketed vessels for precise temperature control and inclined plane systems for residue minimization, have further optimized downstream processing, minimizing waste and contamination risks in commercial-scale operations.[124]Pathogen inactivation technologies have advanced with nucleic acid cross-linking methods, including amotosalen plus UVA light (INTERCEPT system) and riboflavin plus UV light (Mirasol), which inactivate viruses, bacteria, and parasites in fresh frozen plasma without significantly impairing clotting function.[125][126] These systems, implemented more widely post-2020, have demonstrated efficacy against emerging threats like arboviruses in platelets and plasma pools, with UV-based approaches showing superior reduction in infectivity while preserving therapeutic efficacy.[127] Solvent-detergent treatments remain standard for pooled plasma derivatives, achieving near-complete elimination of enveloped viruses.[128]Therapeutically, therapeutic plasma exchange (TPE) has expanded beyond traditional indications like autoimmune disorders to novel applications, including post-acute sequelae of COVID-19 and severe infections. A February 2025 study reported that TPE cleared pro-inflammatory immune factors in long COVID patients, alleviating symptoms by modulating the peripheral inflammatory milieu.[129] In severe yellow fever cases, intensive TPE protocols implemented in 2023-2025 reduced mortality by 84% through rapid removal of pathogenic antibodies and cytokines.[130] A landmark May 2025 clinical trial from the Buck Institute found that TPE combined with intravenous immunoglobulin lowered biological age markers by an average of 2 years in participants, suggesting potential anti-aging effects via dilution of circulating pro-aging factors, though larger trials are needed to confirm causality.[131][132]Convalescent plasmatherapy, while less effective against variants in immunized populations, improved survival in non-vaccinated COVID-19 patients by June 2025 analyses.[133] These developments underscore TPE's role in immune modulation, with emerging preclinical evidence linking plasma extracellular vesicles to therapeutic outcomes.[134]