Factor V Leiden Mutation Causing Thrombophilia

oPatientPlus articles are written by UK doctors and are based on research evidence, UK and European Guidelines. They are designed for health professionals to use, so you may find the language more technical than the condition leaflets.

Synonyms: 'activated protein C resistance: Leiden type' and 'factor V:G1691A mutation'

Factor V Leiden (FVL) mutation (named after the Dutch university where it was discovered) is a point mutation in the gene for clotting factor V.

  • It has autosomal dominant inheritance and is the most common cause of inherited thrombophilia.
  • FVL is the most prevalent thrombotic risk factor known in the Caucasian population (around 5%).[1] 
  • Heterozygotes have a three to five times increased risk of thrombosis. Homozygotes are much less common but have a much higher thrombotic risk, around eight times increased risk.
  • It leads to a hypercoagulable state. Heterozygous FVL mutation and the G20210A mutation in the prothrombin gene are the most frequent clotting abnormalities associated with venous thromboembolism (VTE). The two mutations may co-exist.
  • An individual may be heterozygote or homozygote for the FVL mutation. It is difficult to estimate the increased risk of thrombosis in given individuals, particularly heterozygotes, due to the variable penetrance of the thrombotic tendency (interaction with rest of genotype) and variation in other risk factors. Heterozygous carriers have a 4- to 8-fold increased risk of VTE and homozygotes have an 80-fold increased risk.[1] 
  • The risk of VTE of a FVL mutation is considerably lower than a deficiency of protein C, protein S, or antithrombin III.[2] 

NB: FVL mutation should be distinguished from factor V deficiency, also known as Owren's disease (or parahaemophilia), which is a rare, inherited coagulopathy.[3] 

NEW - log your activity

  • Notes Add notes to any clinical page and create a reflective diary
  • Track Automatically track and log every page you have viewed
  • Print Print and export a summary to use in your appraisal
Click to find out more »

Factor V is one of the essential clotting factors in the coagulation cascade. Its active form, factor Va, acts as a cofactor allowing factor X to stimulate the conversion of prothrombin to thrombin. Thrombin is then able to cleave fibrinogen to fibrin and a fibrin clot is formed.

Activated protein C is a natural anticoagulant. It limits the extent of clotting by destroying factor V and reducing further thrombin formation. FVL mutation causes activated protein C resistance, hence leading to the hypercoagulable state.

  • FVL is present in around 5% of Caucasians.[4] .
  • It is rare or absent in people of black African, Far East Asian, native Australian and native American origin.

The condition is usually diagnosed following thrombophilia screening due to VTE in the patient or a close relative. It may also be detected after investigation for recurrent miscarriage.

Carriers of FVL mutation have actually been reported to have various advantageous phenotypes related to haemostasis, inflammation and fertility. These include less menstrual blood loss, decreased risk of intracranial haemorrhage, higher survival in and lower susceptibility to severe sepsis, higher survival in acute respiratory distress syndrome and less severe diabetic nephropathy.[4]

  • Screening tests for hereditary thrombophilia should only be carried out by physicians with a specialist knowledge who can explain the relevance of the findings to the patient and give any necessary therapy. Screening for thrombophilic disorders should not be undertaken routinely.[5] 
  • Genetic testing can be performed. The polymerase chain reaction for the presence of the FVL mutation is 99% accurate. See separate article Thrombophilia, which describes general investigations for thrombophilia.

General

There is no evidence that the risk of VTE is high enough to warrant long-term anticoagulation in carriers of the gene, even in the homozygous state. Guidelines published by the British Society of Haematology state that:[5] 

  • Initiation and intensity of anticoagulant therapy following a diagnosis of acute venous thrombosis should be the same in patients with and without heritable thrombophilia.
  • Indiscriminate testing for heritable thrombophilias in unselected patients presenting with a first episode of venous thrombosis is not indicated.
  • Decisions regarding duration of anticoagulation (lifelong or not) in unselected patients should be made with reference to whether or not a first episode of venous thrombosis was provoked or not, other risk factors, and risk of anticoagulant therapy-related bleeding, regardless of whether a heritable thrombophilia is known.
  • Case finding of asymptomatic relatives with low-risk thrombophilia such as FVL is not indicated.

Decisions regarding the optimal duration of anticoagulation are based on an individualised assessment of the risks for VTE recurrence and anticoagulant-related bleeding. In the absence of a history of thrombosis, long-term anticoagulation is not routinely recommended for asymptomatic FVL heterozygotes, although prophylactic anticoagulation may be considered in high-risk clinical settings.[1] 

However, among individuals heterozygous for the FVL mutation, while VTE recurrence risk is greater, the risk for bleeding is recognised to be lower. Some specialists are now recommending considering longer duration anticoagulation.[6] 

FVL mutation and the combined oral contraceptive pill (COCP)/hormone replacement therapy (HRT)

  • There is no evidence that routine screening for the FVL mutation should be carried out in women starting the COCP.[7] .
  • The relative risk of VTE is significantly increased but the absolute incidence of thromboembolic events is low and fatal pulmonary embolism is rare.
  • The absolute risk of VTE increases in women with FVL mutation during COCP use. However, this risk is still lower than the absolute risk during the pregnancy postpartum period.
  • Asymptomatic women with a family history of venous thrombosis should be tested if a thromboembolic event in a first-degree relative was unprovoked, or provoked by pregnancy, COCP exposure or a minor risk factor. The result will be more informative if the first-degree relative has a known thrombophilia.[5] 
  • Most women with a previous unprovoked venous thrombosis or pregnancy or COCP-related thrombosis will qualify for thromboprophylaxis on clinical risk alone and so testing for heritable thrombophilia is not required.
  • COCPs are usually discouraged in women with any thrombophilic defects.[8] 
  • It is important that women are educated regarding contraceptive options and also the risks of both VTE and unintended pregnancy, to enable these women to make an informed choice regarding contraception.[2] 
  • The use of thrombophilia screening for women considering COCP use, who have a family history of VTE, is unclear. Women with a family history of VTE in a first-degree relative <45 years of age may indicate an increased likelihood of a hereditary thrombophilia. Screening should be considered in women with a history of previous VTE or a strong family history of VTE who wish to take the COCP.[7] 
  • If a first-degree relative with venous thrombosis has not been tested for FVL then those women should consider an alternative contraceptive or transdermal HRT. Testing for heritable thrombophilia will provide an uncertain estimate of risk and is not recommended.[5] 
  • If a first-degree relative with venous thrombosis has been tested and the result is positive then that woman should also consider an alternative contraceptive or transdermal HRT before being considered for testing, as a negative test result does not exclude an increased risk of venous thrombosis. Testing for heritable thrombophilia may assist counselling of selected women particularly if a high-risk thrombophilia has been identified in the symptomatic relative.[5] 

FVL mutation and pregnancy

VTE

  • Inherited thrombophilia is present in 30-50% of women with pregnancy-associated VTE,  with FVL being the most frequently identified thrombophilia in the white population.[9]
  • Whether the administration of low-molecular-weight heparin (LMWH) during pregnancy is effective in preventing obstetric complications and pregnancy-related VTE in women who are carriers of FVL is controversial.[10] .
  • Current opinion is often based on consensus and clinical judgement of the benefits and risks of antithrombotic therapy in individual cases. Joint opinion of haematologist, obstetrician and patient should decide the issue in non-straightforward cases.
  • Therapeutic decisions should be based on clinical circumstances and not on the results of thrombophilia testing. For example, in the case of the older woman (eg, aged >35 years) with a poor obstetric history a decision to treat with low-dose heparin should not be determined by the results of testing for heritable thrombophilia.[5] .
  • Antithrombotic therapy should not be given to pregnant women based on tests for heritable thrombophilia. Randomised controlled trials with a no treatment or placebo arm in women with a history of pregnancy complications are in progress.[5] 
  • LMWH prophylaxis has been shown to reduce the risk of obstetric complications in carriers of FVL, particularly in those with previous obstetric events. In addition, LMWH prophylaxis reduces the risk of pregnancy-related VTE.[10] 
  • The use of LMWH during pregnancy has been shown to be safe and effective in preventing VTE in susceptible patients with FVL.[11]
  • Heterozygotes are not routinely anticoagulated but a personal or family history of VTE or other risk factors (eg, obesity) may make them candidates for heparinisation.[12] 
  • Once a woman is in labour or thinks she is in labour, she should discontinue her heparin and be reassessed, on admission to hospital, by medical staff. Local guidelines should be followed.[12] 
  • Those considered to be in need of anticoagulation should usually receive warfarin or heparin for at least six weeks postpartum, when the risk of VTE is high. It is safe to breast-feed whilst taking warfarin.

Pregnancy loss

  • Carriers of FVL have double the risk of experiencing recurrent miscarriage compared with women without this thrombophilic mutation.[13] 
  • One study clearly demonstrated a a positive correlation between recurrent pregnancy loss and FVL gene mutations.[14] 
  • Current recommendations are that women with second-trimester miscarriage should be screened for inherited thrombophilias including FVL.[13] 
  • However, one recent study has shown that the frequency of FVL mutation was not significantly different between patients with recurrent miscarriage and healthy women.[15] 

Further reading & references

  1. Kujovich JL; Factor V Leiden thrombophilia. Genet Med. 2011 Jan;13(1):1-16. doi: 10.1097/GIM.0b013e3181faa0f2.
  2. van Vlijmen EF, Veeger NJ, Middeldorp S, et al; Thrombotic risk during oral contraceptive use and pregnancy in women with factor V Leiden or prothrombin mutation: a rational approach to contraception. Blood. 2011 Aug 25;118(8):2055-61; quiz 2375. doi: 10.1182/blood-2011-03-345678. Epub 2011 Jun 9.
  3. Thalji N, Camire RM; Parahemophilia: new insights into factor v deficiency. Semin Thromb Hemost. 2013 Sep;39(6):607-12. doi: 10.1055/s-0033-1349224. Epub 2013 Jul 26.
  4. van Mens TE, Levi M, Middeldorp S; Evolution of Factor V Leiden. Thromb Haemost. 2013 Jul;110(1):23-30. doi: 10.1160/TH13-02-0115. Epub 2013 Apr 25.
  5. Clinical guidelines for testing for heritable thrombophilia; British Committee for Standards in Haematology (January 2010)
  6. Donovan AK, Smith KJ, Ragni MV; Anticoagulation duration in heterozygous factor V Leiden: a decision analysis. Thromb Res. 2013 Dec;132(6):724-8. doi: 10.1016/j.thromres.2013.09.012. Epub 2013 Sep 16.
  7. First Prescription of Combined Oral Contraception; Faculty of Family Planning and Reproductive Health Care (2007); now known as the Faculty of Sexual and Reproductive Healthcare
  8. Blanco-Molina A; Oral contraception in women with mild thrombophilia: what have we learned recently? Thromb Res. 2012 Oct;130 Suppl 1:S16-8. doi: 10.1016/j.thromres.2012.08.263.
  9. Lim W, Eikelboom JW, Ginsberg JS; Inherited thrombophilia and pregnancy associated venous thromboembolism. BMJ. 2007 Jun 23;334(7607):1318-21.
  10. Tormene D, Grandone E, De Stefano V, et al; Obstetric complications and pregnancy-related venous thromboembolism: the effect of low-molecular-weight heparin on their prevention in carriers of factor V Leiden or prothrombin G20210A mutation. Thromb Haemost. 2012 Mar;107(3):477-84. doi: 10.1160/TH11-07-0470. Epub 2012 Jan 25.
  11. Calderwood CJ, Greer IA; The role of factor V Leiden in maternal health and the outcome of pregnancy. Curr Drug Targets. 2005 Aug;6(5):567-76.
  12. Reducing the Risk of Thrombosis and Embolism during Pregnancy and the Puerperium; Royal College of Obstetricians and Gynaecologists (November 2009)
  13. The Investigation and Treatment of Couples with Recurrent First-trimester and Second-trimester Miscarriage; Royal College of Obstetricians and Gynaecologists (April 2011)
  14. Isaoglu U, Ulug P, Delibas IB, et al; The association between inherited thrombophilia and recurrent pregnancy loss in Turkish women. Clin Exp Obstet Gynecol. 2014;41(2):177-81.
  15. Parand A, Zolghadri J, Nezam M, et al; Inherited thrombophilia and recurrent pregnancy loss. Iran Red Crescent Med J. 2013 Dec;15(12):e13708. doi: 10.5812/ircmj.13708. Epub 2013 Dec 5.

Disclaimer: This article is for information only and should not be used for the diagnosis or treatment of medical conditions. EMIS has used all reasonable care in compiling the information but make no warranty as to its accuracy. Consult a doctor or other health care professional for diagnosis and treatment of medical conditions. For details see our conditions.

Original Author:
Dr Michelle Wright
Current Version:
Peer Reviewer:
Dr John Cox
Last Checked:
13/05/2014
Document ID:
2380 (v23)
© EMIS