Fresh frozen plasma (FFP) is a blood product made from the liquid portion of whole blood. It is used to treat conditions in which there are low blood clotting factors (INR>1.5) or low levels of other blood proteins. It is also used as part of plasma exchange. The specific batch typically needs to be tested for compatibility before it is given. Use as a volume expander is not recommended. It is given by injection into a vein.
Side effects include nausea and itchiness. Rarely there may be allergic reactions, blood clots, or infections. It is unclear if use during pregnancy or breastfeeding is safe for the baby. Greater care should be taken in people with protein S deficiency, IgA deficiency, or heart failure. Fresh frozen plasma is made up of a complex mixture of water, proteins, carbohydrates, fats, and vitamins. When frozen it lasts about a year.
Plasma first came into medical use during the Second World War. It is on the World Health Organization's List of Essential Medicines, the most effective and safe medicines needed in a health system. In the United Kingdom it costs about £30 per unit. A number of other versions also exists including plasma frozen within 24 hours after phlebotomy, cryoprecipitate reduced plasma, and solvent detergent plasma.
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Definition
In the United States it refers to the fluid portion of one unit of human blood that has been centrifuged, separated, and frozen solid at -18 °C (0 °F) or colder within eight hours of collection. The phrase "FFP" is often used to mean any transfused plasma product. The other commonly transfused plasma, PF24, has similar indications as those for FFP with the exception of heat-sensitive proteins in the plasma such as factor V.
Medical uses
Very few specific indications for the use of FFP exist. These indications generally are limited to the treatment of deficiencies of coagulation proteins for which specific factor concentrates are unavailable or undesirable. In many clinical practices, fresh and frozen plasma contains proteins with two important coagulation factors in it--the V and the VIII. Other documentations indicate FFP has not enough beneficial effect when it is used as a transfusion to stop massive hemorrhage. In addition, circumstances exist in which FFP has been employed and is believed to be of therapeutic value, but data supporting its efficacy are limited or unavailable (e.g., multiple coagulation protein deficiencies in the uncontrollably bleeding patient). Because such patients are often critically ill and satisfactory alternative therapy may not be at hand, FFP may be appropriate.
Indications for the use of FFP include the following:
- Replacement of isolated factor deficiencies FFP is used to treat rare bleeding disorders when specific factor concentrates are not available. FFP is the usual treatment for factor V deficiency.
- Reversal of warfarin effect Patients who are anticoagulated with warfarin are deficient in the functional vitamin K dependent coagulation factors II, VII, IX, and X, as well as proteins C and S. These functional deficiencies can be reversed by the administration of vitamin K. For anticoagulated patients who are actively bleeding or who require emergency surgery prothrombin complex concentrate should be used if available. FFP (or single-donor plasma) should only be used if more effective alternative treatments are not available.
- Use in antithrombin III deficiency FFP can be used as a source of antithrombin III in patients who are deficient of this inhibitor and are undergoing surgery or who require heparin for treatment of thrombosis.
- Treatment of immunodeficiencies FFP is useful in infants with secondary immunodeficiency associated with severe protein-losing enteropathy and in whom total parenteral nutrition is ineffectual. FFP also can be used as a source of immunoglobulin for children and adults with humoral immunodeficiency. However, the development of a purified immune globulin for intravenous use largely has replaced Fresh frozen plasma
- Treatment of thrombotic thrombocytopenic purpura FFP may be beneficial for the treatment of thrombotic thrombocytopenic purpura.
Risks
The risks of FFP include disease transmission, anaphylactoid reactions, and excessive intravascular volume, as well as transfusion related acute lung injury (TRALI) and an increase in infections (including surgical wound infections). The potential viral infectivity of FFP probably is similar to that of whole blood and red blood cells. The rate of posttransfusion hepatitis depends on many factors, including donor selection. In rare instances, human immunodeficiency virus (HIV) is transmitted by blood transfusions and possibly by FFP. Allergic or anaphylactoid reactions can occur in response to FFP administration and may vary from hives to fatal noncardiogenic pulmonary edema.
FFP should be blood type-matched to ensure compatibility, as agglutination reactions are possible, though rare. As with any intravenously administered fluid, excessive amounts of FFP may result in hypervolemia and cardiac failure.
Chemistry
FFP is made by centrifugation followed by freezing and preservation.
Usage
The use of plasma and its products has evolved over a period of four decades. The use of FFP has increased tenfold in the United States from between the years 2000-2010 and has reached almost 2 million units annually. This trend may be attributable to multiple factors, possibly including decreased availability of whole blood due to widespread acceptance of the concept of component therapy.
Alternatives
Evidence indicates that other plasma components (e.g., single-donor plasma) that do not meet the criteria of FFP may have adequate levels of coagulation factors and are suitable for patients in whom FFP is indicated. Single-donor plasma is efficacious in the treatment of mild deficiencies of stable clotting factors. It also is of value in treatment of multiple deficiencies as in reversal of warfarin effects or in liver disease.
Safe and effective alternative treatment often exists so that FFP is no longer the therapy of choice in many conditions. Cryoprecipitate should be used when fibrinogen or von Willebrand factor is needed. For treatment of hemophilia A, cryoprecipitate or factor VIII concentrates, heated or unheated, are available. For treatment of severe hemophilia B, factor IX complex is preferable. Both of these concentrates are prepared from pooled plasma, and the risk of virus transmission is negligible as there hasn't been an infection since 1985 when techniques were developed to kill off viruses including HIV. The factor IX concentrate carries the additional hazard of thrombogenicity.
Crystalloid, colloid solutions containing human serum albumin or plasma protein fraction, hydroxyethyl starch, and dextran are preferable to FFP for volume replacement. The practice of administering both packed red cells and FFP to the same patient should be discouraged, as this adds to the cost and doubles the infection rate. When conditions are appropriate, whole blood should be given.
For nutritional support, amino acid solutions and dextrose are available.The most important alternative to the use of FFP is a comprehensive program of blood conservation. This includes measures such as autologous donation before elective surgery, the infusion of shed blood, and the realization that in many patients normovolemic anemia is not an indication for transfusion.
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