Technical articles
Types, Mechanisms, and Applications of Blood Collection Tube Additives
Types, Mechanisms, and Applications of Blood Collection Tube Additives
Blood collection tube additives determine the coagulation status of blood after collection, the preservation state of cellular components, and the stability of analytes, and therefore constitute an important part of pre-analytical control in blood sample handling. Different additives correspond to different sample types and testing purposes, and their selection directly affects the accuracy and comparability of test results.
Keywords: blood collection tube; additive; anticoagulant; clot activator; separation gel; pre-analysis; sample handling; testing application
1 Basic Functions of Blood Collection Tube Additives
1.1 Functional Roles in the Pre-analytical Phase
(1) Control of the coagulation process
After blood is collected, the coagulation cascade is rapidly initiated. Blood collection tube additives first determine whether the final specimen will be processed as serum, plasma, or whole blood.
(2) Stabilization of sample status
Cellular metabolism, ion transport, protein release, and enzymatic activity continue after blood collection. Additives can delay, block, or redirect these processes, thereby improving the stability of target analytes.
(3) Standardization of workflow
Blood collection tube additives affect not only sample composition, but also mixing procedures, centrifugation timing, centrifugation parameters, and storage pathways. Therefore, additive selection is directly related to the consistency of the testing workflow.
1.2 Major Functional Categories
(1) Anticoagulant additives
These are used to inhibit the coagulation process and obtain plasma or whole blood samples.
(2) Clot-promoting additives
These are used to accelerate coagulation and improve the efficiency of serum separation.
(3) Separation-support additives
These mainly refer to systems such as separation gels, which form a stable barrier between serum or plasma and blood cells after centrifugation.
(4) Protective and stabilizing additives
These are used to inhibit glycolysis, protect nucleic acids, maintain cellular morphology, or reduce the risk of analyte degradation.
2 Major Categories of Blood Collection Tube Additives
2.1 Anticoagulants
(1) Ethylenediaminetetraacetic acid salts (EDTA)
EDTA inhibits coagulation by chelating Ca2+ and is one of the most commonly used anticoagulants in hematology testing. Its advantages include relatively good preservation of cellular morphology, making it suitable for complete blood count testing, blood cell differential analysis, certain molecular assays, and some pre-analytical procedures for flow cytometry. Its limitations are that it markedly affects the measurement of calcium, magnesium, and other metal ions, and it is not suitable for coagulation testing.
(2) Heparin and its salts
Common forms include sodium heparin, lithium heparin, and ammonium heparin. Heparin inhibits coagulation by enhancing antithrombin activity and is suitable for certain biochemical assays, blood gas analysis, and emergency testing. Heparinized plasma can be obtained relatively quickly, but heparin itself may interfere with some molecular biological reactions and certain staining systems.
(3) Citrates
Sodium citrate achieves anticoagulation through reversible binding of Ca2+ and is most classically used in coagulation testing. Because its anticoagulant effect can be reversed by calcium supplementation, it is particularly suitable for coagulation analysis systems. This type of anticoagulant requires strict control of the blood-to-anticoagulant ratio, and any imbalance in this ratio directly affects the result.
(4) Oxalate/fluoride combined systems
Oxalates function as anticoagulants, whereas fluoride is mainly used to inhibit glycolysis. These combination tubes are commonly used for the detection of metabolic markers such as glucose and lactate. Their methodological value does not lie in preserving the most natural sample state, but in rapidly terminating post-collection metabolism.
2.2 Clot-promoting Additives
(1) Silicon dioxide-based clot-promoting particles
These accelerate clot formation by providing a contact surface for coagulation and are among the most common clot-promoting systems in routine serum tubes.
(2) Clot activators
These include certain inorganic or organic coagulation-promoting components used to shorten natural clotting time and improve sample turnaround efficiency. Their main application is serum preparation for routine clinical biochemistry and immunological testing.
2.3 Separation Gel
(1) Basic function
After centrifugation, the separation gel forms a stable barrier between the upper serum or plasma layer and the lower blood cell layer, thereby reducing remixing and upward displacement of cellular components.
(2) Methodological value
Its main advantages are improved workflow efficiency, better compatibility with automation, and reduced errors during subsequent sample transfer.
(3) Application boundaries
Not all test items are suitable for separation gel use. In some trace analyses, small-molecule metabolite assays, drug concentration measurements, and certain mass spectrometry applications, separation gels may introduce adsorption effects or background interference.
2.4 Inhibitory and Protective Additives
(1) Glycolysis inhibitors
The most typical example is sodium fluoride, which is mainly used in glucose testing systems to reduce false decreases caused by ongoing glucose consumption by blood cells after collection.
(2) Nucleic acid preservation systems
These are used in certain molecular testing blood collection tubes and emphasize leukocyte lysis control, nuclease inhibition, and nucleic acid stabilization.
(3) Cell preservation systems
These are mainly used for flow cytometric analysis, circulating tumor cell detection, special immunophenotypic analysis, or cytogenetic testing, where preservation of cellular integrity and antigen stability is critical.
Table 1 Main Categories and Functions of Common Blood Collection Tube Additives
Additive category | Representative type | Main function | Common sample type | Main application direction |
Anticoagulant | EDTA | Chelates Ca2+ and inhibits coagulation | Whole blood, plasma | Hematology, certain molecular assays |
Anticoagulant | Heparin | Inhibits the coagulation cascade | Plasma | Biochemistry, blood gas analysis, emergency testing |
Anticoagulant | Sodium citrate | Reversible anticoagulation | Plasma | Coagulation testing |
Anticoagulant/inhibitor | Oxalate/fluoride | Anticoagulation and glycolysis inhibition | Plasma | Glucose and lactate testing |
Clot promoter | Silicon particles/clot activators | Accelerates coagulation | Serum | Routine biochemistry, immunological testing |
Separation-support additive | Separation gel | Forms a stratification barrier | Serum, plasma | Automated testing, sample preservation |
Protective system | Nucleic acid/cell preservative | Stabilizes target components | Specialized whole blood samples | Molecular testing, cell analysis |
3 Mechanisms and Compatibility Characteristics of Common Additives
3.1 EDTA Systems
(1) Mechanism of action
EDTA blocks coagulation by efficiently chelating Ca2+. Because its anticoagulant effect is stable and its influence on cell morphology is relatively limited, it is most widely used in hematology.
(2) Main compatible applications
① Complete blood count and blood cell counting
② Peripheral blood cell morphological examination
③ Pre-processing for certain molecular diagnostic assays
④ Pre-analytical procedures for some flow cytometric assays
(3) Main limitations
EDTA affects Ca2+, Mg2+, and some enzyme activity-related analytes. It is not suitable for coagulation testing and should not be directly used for certain biochemical assays requiring preservation of the natural ionic state.
3.2 Heparin Systems
(1) Mechanism of action
Heparin inhibits activation of coagulation factors through an antithrombin-mediated mechanism and therefore represents a physiologically based anticoagulant pathway.
(2) Main compatible applications
① Emergency biochemical testing
② Blood gas analysis
③ Certain clinical chemistry assays
④ Pre-processing for some cell function experiments
(3) Main limitations
Heparin may interfere with certain PCR systems, enzymatic reactions, and staining analyses, and therefore should not be regarded as a universal anticoagulant.
3.3 Sodium Citrate Systems
(1) Mechanism of action
Sodium citrate temporarily interrupts coagulation by forming complexes with Ca2+, and coagulation can subsequently be restored in the testing system by calcium supplementation.
(2) Main compatible applications
① PT, APTT, TT, FIB, and other coagulation assays
② Certain erythrocyte sedimentation assays
③ Some functional coagulation analyses
(3) Main limitations
The blood-to-anticoagulant volume ratio must be strictly controlled. In samples with high hematocrit, the anticoagulant volume must also be adjusted; otherwise, systematic bias may occur.
3.4 Clot-promoting and Separation Gel Systems
(1) Mechanism of action
Clot-promoting additives accelerate clot formation, whereas separation gels form a stratification barrier after centrifugation. These are commonly used together in serum separation tubes.
(2) Main compatible applications
① Routine biochemical testing
② Routine immunological testing
③ Hormone and antibody assays
④ High-throughput automated sample processing
(3) Main limitations
For assays emphasizing trace analysis, small-molecule drug monitoring, or specialized research applications, it is necessary to verify in advance whether the separation gel and clot-promoting system introduce bias.
3.5 Glycolysis Inhibition Systems
(1) Mechanism of action
These systems slow continued glucose consumption by blood cells after collection by inhibiting the activity of glycolytic enzymes.
(2) Main compatible applications
① Glucose testing
② Lactate analysis
③ Stringent pre-analytical control for certain metabolic assays
(3) Main limitations
The purpose of these systems is not to preserve the natural state of blood, but to prioritize post-collection metabolic control; therefore, they should not be used arbitrarily as substitutes for routine biochemistry blood collection tubes.
4 Major Application Scenarios of Blood Collection Tube Additives
4.1 Routine Biochemical and Immunological Testing
(1) Situations in which serum systems are preferred
Most routine biochemistry assays, immunoglobulin tests, antibody tests, hormone assays, and tumor marker tests are more suitable for clot-activator tubes or serum separation tubes.
(2) Situations in which plasma systems are preferred
When rapid sample turnaround is required, prompt separation and instrument loading are needed, or when certain analytes are specifically validated in a plasma matrix, heparin tubes can improve workflow efficiency.
4.2 Hematology and Cell Analysis
(1) Complete blood count
EDTA remains one of the standard choices for routine hematology analysis, with emphasis on preservation of cell morphology and counting stability.
(2) Flow cytometric analysis
Depending on the target antigen and testing system, EDTA or a specific cell preservation system may be used. When delayed testing or transported samples are involved, greater attention must be paid to the effects of stabilizing additives.
4.3 Coagulation Function Testing
(1) Coagulation analysis
Sodium citrate is the core additive for coagulation testing. Its significance lies not merely in anticoagulation, but in providing the methodological basis for in vitro reconstitution of the coagulation cascade.
(2) Quality control requirements
Coagulation assays are highly sensitive to fill volume, mixing method, and centrifugation conditions, and therefore one anticoagulant tube cannot be substituted for another simply because both prevent clotting.
4.4 Molecular Testing and Specialized Sample Collection
(1) Nucleic acid testing
The collection tube should be selected according to the analytical target, using either a nucleic acid preservation tube or an anticoagulant system compatible with downstream nucleic acid extraction. Some anticoagulants may prevent clotting but are not necessarily suitable for pre-PCR or pre-sequencing handling.
(2) Cytogenetic and specialized biomarker testing
If the analytical target is circulating nucleic acids, circulating tumor cells, or specific extracellular vesicle components, the choice of blood collection tube additive directly affects preservation of the target material.
Table 2 Selection Logic of Blood Collection Tube Additives for Different Testing Directions
Testing direction | More commonly used additive system | Key selection consideration |
Routine biochemistry | Clot activator/separation gel | Serum separation efficiency and automation compatibility |
Immunological testing | Clot activator/separation gel | Stability of the serum matrix |
Complete blood count | EDTA | Preservation of cellular morphology |
Coagulation function | Sodium citrate | Reversible anticoagulation and ratio control |
Blood gas analysis | Heparin | Rapid anticoagulation and suitability for emergency testing |
Glucose/lactate | Fluoride-related systems | Inhibition of post-collection glycolysis |
Molecular testing | Specific anticoagulant/protective systems | Compatibility with downstream nucleic acid workflows and stability |
Table 3 Product Table of Blood Collection Tube Additive-Related Products
Product type | Catalog No. | Name | CAS No. | Grade and purity | Applicable research direction/use |
EDTA anticoagulant | Sterile EDTA.2K Anticoagulant (10×) | 25102-12-9 | BioReagent, sterile, 10× | Suitable for EDTA-based blood collection anticoagulant systems, mainly for hematology and pre-processing for molecular testing | |
EDTA anticoagulant | EDTA.2K Anticoagulant (10×) | 25102-12-9 | BioReagent, 10× | Suitable for routine EDTA anticoagulant system development and formulation applications | |
EDTA system raw material | Ethylenediaminetetraacetic acid dipotassium salt dihydrate | 25102-12-9 | AR, ≥98% | Suitable as a raw material for K2EDTA anticoagulant systems | |
EDTA system raw material | Ethylenediaminetetraacetic acid tripotassium salt dihydrate | 65501-24-8 | ≥99% | Suitable as a raw material for K3EDTA anticoagulant systems | |
Heparin system raw material | Heparin sodium salt | 9041-08-1 | ≥99%, ≥150(units/mg),from bovine intestinal mucosa | Suitable for heparin anticoagulant systems corresponding to plasma biochemistry and some emergency pre-analytical testing | |
Heparin system raw material | Heparin lithium salt | 9045-22-1 | ≥150 USP units/mg | Suitable for lithium heparin anticoagulant systems, mainly for plasma biochemistry and rapid separation applications | |
Citrate system | Citrate Concentrated Solution | 68-04-2 | BioReagent, 4% (w/v), suitable for coagulation assays | Suitable for citrate-based anticoagulant systems for coagulation testing | |
Citrate system raw material | Sodium citrate dihydrate | 6132-04-3 | pharmaceutical grade, PharmPure™ | Suitable for selection of raw materials for blood collection tube citrate systems | |
Oxalate/fluoride anticoagulant system | Potassium Oxalate-Sodium Fluoride Anticoagulant | — | BioReagent | Suitable for anticoagulant and glycolysis inhibition systems used in glucose, lactate, and related assays | |
Oxalate/fluoride anticoagulant system | Sterile Potassium Oxalate-Sodium Fluoride Anticoagulant | — | BioReagent, sterile | Suitable for potassium oxalate-sodium fluoride systems requiring higher sterility | |
Oxalate system raw material | Potassium oxalate monohydrate | 6487-48-5 | AR, ≥99.8% | Suitable as a raw material for oxalate anticoagulant systems | |
Oxalate system raw material | Sodium oxalate | 62-76-0 | ≥99% | Suitable as a raw material for oxalate anticoagulant systems | |
Glycolysis inhibition system raw material | Sodium fluoride | 7681-49-4 | BioReagent Plus, ≥99% | Suitable for glycolysis inhibition systems in glucose and lactate testing | |
Clot activator | Blood Coagulant (Water-Based) | — | BioReagent | Suitable for clot-promoting systems in serum blood collection tubes | |
Clot activator | Coagulants (containing enzymes) | — | BioReagent | Suitable for clot-promoting systems requiring enhanced coagulation initiation efficiency | |
Clot activator | Blood Coagulant (Alcohol-Based) | — | BioReagent | Suitable for development and application of blood collection tube clot-promoting systems | |
Separation gel | Transparent Radiation-Resistant Blood Separation Gel | — | BioReagent | Suitable for serum/plasma stratification barrier systems | |
Separation gel | Semi-transparent Radiation-Resistant Blood Separation Gel | — | BioReagent | Suitable for serum/plasma separation and irradiation-related application scenarios | |
Inner-wall treatment auxiliary material | Water-Soluble Siliconizing Fluid | — | BioReagent | Suitable for inner-wall surface treatment and improved flow properties of blood collection tubes, and may be included as a supplementary processing material for tube manufacture |
The selection of blood collection tube additives is, in essence, the selection of the pre-analytical pathway for the sample. Through regulation of coagulation, cellular metabolism, nucleic acid stability, and sample stratification, different additives convert the same blood specimen into analytical material suitable for different testing purposes. Understanding blood collection tube additives should therefore be based on a unified framework integrating mechanism of action, sample type, and analytical compatibility.
