Plasmapheresis

Plasmapheresis
Intervention

Plasmapheresis machine
ICD-10-PCS
ICD-9-CM 99.7
MeSH D010956

Plasmapheresis (from the Greek πλάσμα—plasma, something molded, and ἀφαίρεσις—aphairesis, taking away) is the removal, treatment, and return or exchange of blood plasma or components thereof from and to the blood circulation. It is thus an extracorporeal therapy (a medical procedure performed outside the body).

Three general types of plasmapheresis can be distinguished:

Plasmapheresis of the autologuous and exchange types is used to treat a variety of disorders, including those of the immune system, such as Goodpasture's syndrome,[2] myasthenia gravis,[3][4] Guillain–Barré syndrome, lupus, and thrombotic thrombocytopenic purpura.

Medical uses

During plasmapheresis, blood (which consists of blood cells and a clear liquid called plasma) is initially taken out of the body through a needle or previously implanted catheter. Plasma is then removed from the blood by a cell separator. Three procedures are commonly used to separate the plasma from the blood cells, with each method having its own advantages and disadvantages:

After plasma separation, the blood cells are returned to the person undergoing treatment, while the plasma, which contains the antibodies, is first treated and then returned to the patient in traditional plasmapheresis. Rarely, other replacement fluids, such as hydroxyethyl starch, may be used in individuals who object to blood transfusion but these are rarely used due to severe side-effects. Medication to keep the blood from clotting (an anticoagulant) is given to the patient during the procedure.

Plasmapheresis is used as a therapy in particular diseases. It is an uncommon treatment in the United States, but it is more common in Europe and particularly Japan.[5]

An important use of plasmapheresis is in the therapy of autoimmune disorders, where the rapid removal of disease-causing autoantibodies from the circulation is required in addition to other medical therapy. It is important to note that plasma exchange therapy in and of itself is useful to temper the disease process, while simultaneous medical and immunosuppressive therapy is required for long-term management. Plasma exchange offers the quickest short-term answer to removing harmful autoantibodies; however, the production of autoantibodies by the immune system must also be suppressed, usually by the use of medications such as prednisone, cyclophosphamide, cyclosporine, mycophenolate mofetil, rituximab, or a mixture of these.

Other uses are the removal of blood proteins where these are overly abundant and cause hyperviscosity syndrome.

Examples of diseases that can be treated with plasmapheresis:

Complications of plasmapheresis therapy

Though plasmapheresis is helpful in certain medical conditions, like any other therapy, there are potential risks and complications. Insertion of a rather large intravenous catheter can lead to bleeding, lung puncture (depending on the site of catheter insertion), and, if the catheter is left in too long, it can get infected.

Aside from placing the catheter, the procedure itself has complications. When patient blood is outside of the body passing through the plasmapheresis machine, the blood has a tendency to clot. To reduce this tendency, in one common protocol, sodium citrate is infused while the blood is running through the circuit. Citrate binds to calcium in the blood, calcium being essential for blood to clot. Citrate is very effective in preventing blood from clotting; however, its use can lead to life-threateningly low calcium levels. This can be detected using the Chvostek's sign or Trousseau's sign. To prevent this complication, calcium is infused intravenously while the patient is undergoing the plasmapheresis; in addition, calcium supplementation by mouth may also be given.

Other complications include:

As a manufacturing process

BioLife Plasma Services, one of several chains of plasma centers in the United States.

Donating plasma is similar in many ways to whole blood donation, though the end product is used for different purposes. Most plasmapheresis is for fractionation into other products; other blood donations are transfused with relatively minor modifications. Plasma that is collected solely for further manufacturing is called Source Plasma.

Plasma donors undergo a screening process to ensure both the donor's safety and the safety of the collected product. Factors monitored include blood pressure, pulse, temperature, total protein, protein electrophoresis, health history screening similar to that for whole blood, as well as an annual physical exam with a licensed physician or an approved physician substitute under the supervision of the physician. Donors are screened at each donation for viral diseases that can be transmitted by blood, sometimes by multiple methods. For example, donations are tested for HIV by ELISA, which shows if they have been exposed to the disease, as well as by nucleic acid methods (PCR or similar) to rule out recent infections that the ELISA test might miss and are also screened for hepatitis B and hepatitis C. Industry standards require at least two sets of negative test results before the collected plasma is used for injectable products. The plasma is also treated in processing multiple times to inactivate any virus that was undetected during the screening process.

In a few countries, plasma (like blood) is donated by unpaid volunteers. In others, including the United States, most plasma donors are paid for their time as the time commitment for regular donors is over 200 hours per year. Standards for donating plasma are set by national regulatory agencies such as the U.S. Food and Drug Administration (FDA),[8] the European Union, and by a professional organization, the Plasma Protein Therapeutics Association (or PPTA),[9] which audits and accredits collection facilities. A National Donor Deferral Registry (NDDR) is also maintained by the PPTA for use in keeping donors with prior positive viral antibody test results from donating at any facility.

Almost all plasmapheresis in the US is performed by automated methods such as the Plasma Collection System (PCS2) made by Haemonetics or the Autopheresis-C (Auto-C) made by Fenwal, Inc., a former division of Baxter International. In some cases, automated plasmapheresis is used to collect plasma products like Fresh frozen plasma for direct transfusion purposes, often at the same time as plateletpheresis.

Manual method
For the manual method, approximately the same as a whole blood donation is collected from the donor. The collected blood is then separated by centrifuge machines in separate rooms, the plasma is pressed out of the collection set into a satellite container, and the red blood cells are returned to the donor. Since returning red cells causes the body to replace plasma more rapidly, a donor can provide up to a liter of plasma at a time and can donate with only a few days between donations, unlike the 56-day deferral for blood donation. The amount allowed in a donation varies vastly from country to country, but generally does not exceed two donations, each as much as a liter, per seven-day period.

The danger with this method was that if the wrong red blood cells were returned to the donor, a serious and potentially fatal transfusion reaction could occur. Requiring donors to recite their names and ID numbers on returned bags of red cells minimized this risk. This procedure has largely become obsolete in favor of the automated method.

Automated method
The automated method uses a very similar process. The difference is that the collection, separation, and return are all performed inside a machine connected to the donor through a needle in the arm, typically the antecubital vein. There is no risk of receiving the wrong red cells.[10] The devices used are very similar to the devices used for therapeutic plasmapheresis, and the potential for citrate toxicity is similar. The potential risks are explained to prospective donors at the first donation, and most donors tolerate the procedure well.[11]

If a significant amount of red blood cells cannot be returned, the donor may not donate for 56 days, just as if they had donated a unit of blood. Depending on the collection system and the operation, the removed plasma may be replaced by saline. The body typically replaces the collected volume within 24 hours, and donors typically donate up to twice a week, though this varies by country.

The collected plasma is promptly frozen at lower than -20 °C (-4 °F) and is typically shipped to a processing facility for fractionation. This process separates the collected plasma into specific components, such as albumin and immunoglobulins, most of which are made into medications for human use. Sometimes the plasma is thawed and transfused as Fresh Frozen Plasma (FFP), much like the plasma from a normal blood donation.

Donors are sometimes immunized against agents such as tetanus or hepatitis B so that their plasma contains the antibodies against the toxin or disease. In other donors, an intentionally incompatible unit of blood is transfused to produce antibodies to the antigens on the red cells. The collected plasma then contains these components, which are used in manufacturing of medications. Donors who are already ill may have their plasma collected for use as a positive control for laboratory testing.

History

Michael Rubinstein was the first person to use plasmapheresis to treat an immune-related disorder when he "saved the life of an adolescent boy with thrombotic thrombocytopenic purpura (TTP) at the old Cedars of Lebanon Hospital in Los Angeles in 1959".[12] The modern plasmapheresis process itself originated in the "[U.S.] National Cancer Institute between 1963 and 1968, [where] investigators drew upon an old dairy creamer separation technology first used in 1878 and refined by Edwin Cohn's centrifuge marketed in 1953."[12]

See also

References

  1. "Why Donate Plasma". Retrieved 26 September 2011.
  2. MedlinePlus. "Goodpasture syndrome". U.S. National Library of Medicine. Retrieved 7 April 2013.
  3. Yazdi, MF; Baghianimoghadam, M; Nazmiyeh, H; Ahmadabadi, AD; Adabi, MA (2012). "Response to plasmapheresis in myasthenia gravis patients: 22 cases report". Romanian journal of internal medicine = Revue roumaine de medecine interne. 50 (3): 245–7. PMID 23330293.
  4. Batocchi, AP; Evoli, A; Di Schino, C; Tonali, P (2000). "Therapeutic apheresis in myasthenia gravis". Therapeutic Apheresis. 4 (4): 275–9. doi:10.1046/j.1526-0968.2000.004004275.x. PMID 10975473.
  5. Drew, MJ (2002). "Plasmapheresis in the dysproteinemias". Therapeutic Apheresis. 6 (1): 45–52. doi:10.1046/j.1526-0968.2002.00393.x. PMID 11886576.
  6. Mori, M; Kuwabara, S; Fukutake, T; Hattori, T (2002). "Plasmapheresis and Miller Fisher syndrome: analysis of 50 consecutive cases". Journal of neurology, neurosurgery, and psychiatry. 72 (5): 680. doi:10.1136/jnnp.72.5.680. PMC 1737859Freely accessible. PMID 11971070.
  7. Kiprov D.D., Stricker R.B., Miller R.G. Int. Conf. AIDS. 1992 Jul 19-24; 8: 95 (abstract no. PuB 7281). U.S. Nat`l Institutes of Health, NLM Gateway. Abstract retrieved 8-22-2009.
  8. FDA > CDRH > CFR Title 21 Database Search
  9. Plasma Protein Therapeutics Association. PPTA [Online]. Retrieved 8-22-2009.
  10. Biolife - Donating Plasma: The Donation Process Archived August 22, 2007, at the Wayback Machine.
  11. Octapharma Plasma, Inc. - Plasma donation safety
  12. 1 2 Wallace, D. J. "Apheresis for lupus erythematosus". Lupus (1999) 8, 174–180.

External links

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