Afibrinogenemia, sometimes called congenital afibrinogenemia, is an inherited blood disorder in which the blood does not clot normally. It occurs when there is a lack (deficiency) of a protein called fibrinogen (or coagulation factor I), which is needed for the blood to clot. Affected individuals may be susceptible to severe bleeding (hemorrhaging) episodes, particularly during infancy and childhood. Afibrinogenemia is thought to be transmitted as an autosomal recessive trait. Treatment may include cryoprecipitate (a blood product containing concentrated fibrinogen and other clotting factors), fibrinogen (RiaSTAP) or plasma (the liquid portion of the blood which contains clotting factors).

• Nosebleeds that are difficult to stop
• Bleeding in the mucus membranes
• Bleeding in the joints
• Bruising easily
• Gastrointestinal bleeding
• Menorrhagia and postpartum hemorrhage
• Heavy bleeding after injury or surgery
• Spontaneous rupture of the spleen
• Bleeding inside the skull (intracranial hemorrhage) - very rare
• Miscarriage

Normal Function

The FGG gene provides instructions for making the fibrinogen gamma (γ) chain, one piece (subunit) of the fibrinogen protein. This protein is important for blood clot formation (coagulation), which is needed to stop excessive bleeding after injury. To form fibrinogen, the γ chain attaches to the fibrinogen A alpha (Aα) and fibrinogen B beta (Bβ) chains, each produced from different genes. Two sets of this three-protein complex combine to form functional fibrinogen.

For coagulation to occur, another protein called thrombin removes a piece from the Aα and the Bβ subunits of the functional fibrinogen protein (the pieces are called the A and B fibrinopeptides). This process converts fibrinogen to fibrin, the main protein in blood clots. Fibrin proteins attach to each other, forming a stable network that makes up the blood clot.

Health Conditions Related to Genetic Changes

Congenital afibrinogenemia

Mutations in the FGG gene can lead to congenital afibrinogenemia, a condition that causes excessive bleeding due to the absence of fibrinogen protein in the blood. Most FGG gene mutations that cause this condition lead to an abnormally short blueprint for protein formation (mRNA). If any fibrinogen γ chain is produced, it is nonfunctional. Because this condition occurs when both copies of the FGG gene are altered, there is a complete absence of functional fibrinogen γ chain. Without the γ subunit, the fibrinogen protein is not assembled, which results in the absence of fibrin. As a result, blood clots do not form in response to injury, leading to the excessive bleeding seen in people with congenital afibrinogenemia.

Other disorders

Mutations in one or both copies of the FGG gene can cause other bleeding disorders known as hypofibrinogenemia, dysfibrinogenemia, or hypodysfibrinogenemia.

Hypofibrinogenemia is a condition characterized by decreased levels of fibrinogen in the blood. This condition is caused by mutations that reduce but do not eliminate the production of the fibrinogen γ chain. People with hypofibrinogenemia can have bleeding problems that vary from mild to severe. Generally, the less fibrinogen in the blood, the more severe the bleeding problems are.

Dysfibrinogenemia is a condition characterized by abnormally functioning fibrinogen, although the protein is present at normal levels. This condition is usually caused by mutations that change a single protein building block (amino acid) in the fibrinogen γ chain. These mutations alter the function of the fibrinogen protein and, depending on the functional change, can lead to excessive bleeding or abnormal blood clotting (thrombosis).

Hypodysfibrinogenemia is a condition characterized by low levels of abnormally functioning fibrinogen protein in the blood. As in dysfibrinogenemia, this condition can result in excessive bleeding or thrombosis.

Other Names for This Gene

• FIBG_HUMAN
• fibrinogen gamma chain isoform gamma-A precursor
• fibrinogen gamma chain isoform gamma-B precursor
• fibrinogen, gamma polypeptide

Genomic Location

Normal Function

The FGB gene provides instructions for making a protein called the fibrinogen B beta (Bβ) chain, one piece (subunit) of the fibrinogen protein. This protein is important for blood clot formation (coagulation), which is needed to stop excessive bleeding after injury. To form fibrinogen, the Bβ chain attaches to two other proteins called the fibrinogen A alpha (Aα) and fibrinogen gamma (γ) chains, each produced from different genes. Two sets of this three-protein complex combine to form functional fibrinogen.

For coagulation to occur, another protein called thrombin removes a piece from the Aα and the Bβ subunits of the functional fibrinogen protein (the pieces are called the A and B fibrinopeptides). This process converts fibrinogen to fibrin, the main protein in blood clots. Fibrin proteins attach to each other, forming a stable network that makes up the blood clot.

Health Conditions Related to Genetic Changes

Congenital afibrinogenemia

Mutations in the FGB gene can lead to congenital afibrinogenemia, a condition that causes excessive bleeding due to the absence of fibrinogen protein in the blood. Most FGB gene mutations that cause this condition lead to an abnormally short blueprint for protein formation (mRNA). If any fibrinogen Bβ chain is produced, it is nonfunctional. Some mutations in the FGB gene result in the formation of a protein that cannot be released from the cell, making the protein effectively nonfunctional. Because this condition occurs when both copies of the FGB gene are altered, there is a complete absence of functional fibrinogen Bβ chain. Without the Bβ subunit, the fibrinogen protein is not assembled, which results in the absence of fibrin. As a result, blood clots do not form in response to injury, leading to excessive bleeding.

Other disorders

Mutations in one or both copies of the FGB gene can cause other bleeding disorders known as hypofibrinogenemia, dysfibrinogenemia, or hypodysfibrinogenemia.

Hypofibrinogenemia is a condition characterized by decreased levels of fibrinogen in the blood. This condition is caused by mutations that reduce but do not eliminate the production of the fibrinogen Bβ chain. People with hypofibrinogenemia can have bleeding problems that vary from mild to severe. Generally, the less fibrinogen in the blood, the more severe the bleeding problems are.

Dysfibrinogenemia is a condition characterized by abnormally functioning fibrinogen, although the protein is present at normal levels. This condition is usually caused by mutations that change a single protein building block (amino acid) in the fibrinogen Bβ chain. These mutations alter the function of the fibrinogen protein and, depending on the functional change, can lead to excessive bleeding or abnormal blood clotting (thrombosis).

Hypodysfibrinogenemia is a condition characterized by low levels of abnormally functioning fibrinogen protein in the blood. As in dysfibrinogenemia, this condition can result in excessive bleeding or thrombosis.

Other Names for This Gene

• FIBB_HUMAN
• fibrinogen beta chain isoform 1 preproprotein
• fibrinogen beta chain isoform 2 preproprotein
• fibrinogen, B beta polypeptide

Genomic Location

Normal Function

The FGA gene provides instructions for making a protein called the fibrinogen A alpha (Aα) chain, one piece (subunit) of the fibrinogen protein. This protein is important for blood clot formation (coagulation), which is needed to stop excessive bleeding after injury. To form fibrinogen, the Aα chain attaches to two other proteins called the fibrinogen B beta (Bβ) and fibrinogen gamma (γ) chains, each produced from different genes. Two sets of this three-protein complex combine to form functional fibrinogen.

For coagulation to occur, another protein called thrombin removes a piece from the Aα and the Bβ subunits of the functional fibrinogen protein (the pieces are called the A and B fibrinopeptides). This process converts fibrinogen to fibrin, the main protein in blood clots. Fibrin proteins attach to each other, forming a stable network that makes up the blood clot.

Health Conditions Related to Genetic Changes

Congenital afibrinogenemia

Mutations in the FGA gene can lead to congenital afibrinogenemia, a condition that causes excessive bleeding due to the absence of fibrinogen protein in the blood. Most FGA gene mutations that cause this condition lead to an abnormally short blueprint for protein formation (mRNA). If any fibrinogen Aα chain is produced, it is nonfunctional. Because this condition occurs when both copies of the FGA gene are altered, there is a complete absence of functional fibrinogen Aα chain. Without the Aα subunit, the fibrinogen protein is not assembled, which results in the absence of fibrin. Consequently, blood clots do not form in response to injury, leading to the excessive bleeding seen in people with congenital afibrinogenemia.

Other disorders

Mutations in one or both copies of the FGA gene can cause other bleeding disorders known as hypofibrinogenemia, dysfibrinogenemia, or hypodysfibrinogenemia.

Hypofibrinogenemia is a condition characterized by decreased levels of fibrinogen in the blood. This condition is caused by mutations that reduce but do not eliminate the production of the fibrinogen Aα chain. People with hypofibrinogenemia can have bleeding problems that vary from mild to severe. Generally, the less fibrinogen in the blood, the more severe the bleeding problems are.

Dysfibrinogenemia is a condition characterized by abnormally functioning fibrinogen, although the protein is present at normal levels. This condition is usually caused by mutations that change a single protein building block (amino acid) in the fibrinogen Aα chain. These mutations alter the function of the fibrinogen protein and, depending on the functional change, can lead to excessive bleeding or abnormal blood clotting (thrombosis).

Hypodysfibrinogenemia is a condition characterized by low levels of abnormally functioning fibrinogen protein in the blood. As in dysfibrinogenemia, this condition can result in excessive bleeding or thrombosis.

Mutations in the FGA gene are also responsible for some cases of a condition called hereditary renal amyloidosis, which causes impairment of kidney (renal) function and leads to kidney failure. This condition is characterized by the accumulation of protein clumps called amyloid deposits in the kidneys. When the condition is caused by FGA gene mutations, the amyloid deposits are made up of abnormal fibrinogen Aα chain proteins, and the condition is sometimes called fibrinogen amyloidosis. The mutations involved in this condition typically change a single amino acid in the fibrinogen Aα chain and do not seem to affect fibrinogen's clotting activity.

Other Names for This Gene

• Fib2
• FIBA_HUMAN
• fibrinogen alpha chain isoform alpha preproprotein
• fibrinogen alpha chain isoform alpha-E preproprotein
• fibrinogen, A alpha polypeptide

Genomic Location

• 25% (1 in 4) chance to be affected,
• 50% (1 in 2) chance to be an unaffected carrier like each parent,
• 25% (1 in 4) chance to be unaffected and not be a carrier.

There is no known prevention or cure for afibrinogenemia. To treat bleeding episodes or to prepare for surgery to treat other conditions, patients may receive:

• The liquid portion of the blood (plasma)
• Fibrinogen (RaiSTAP)
• A blood product containing concentrated fibrinogen (cryoprecipitate) through a vein (transfusion)

Prophylactic therapy should also be considered for patients with recurrent bleeding episodes, CNS hemorrhage, or during pregnancy for women with recurrent miscarriage.Individuals with afibrinogenemia should consider the following as part of their management plan:

• Consultation with a hematologist/hemostasis specialist, particularly for patients who require fibrinogen replacement therapy.
• Genetic counseling and family studies, especially for individuals with extensive family history or those considering pregnancy.
• Follow-up by a comprehensive bleeding disorder care team experienced in diagnosing and managing inherited bleeding disorders.
• Vaccination with the hepatitis B vaccine because transfusion increases the risk of hepatitis.

Aside from the fact that women have similar symptoms to men with bleeding disorders (recurrent nosebleeds, easy bruising, bleeding from the digestive or urinary tract and excessive bleeding from the mouth or gums), they can also experience added obstetric and gynecological complications. Bleeding disorders are particularly troublesome for reproductive-aged women. Heavy and prolonged menstrual bleeding, also known as menorrhagia, can lead to serious complications if left untreated.

Recurrent spontaneous abortions can also occur in women with afibrinogenemia. This phenomenon, however, may be prevented by routine prophylaxis with fibrinogen concentrates starting early in pregnancy. In addition, women with afibrinogenemia may experience postpartum hemorrhage.

In cases where a woman with a bleeding disorder becomes pregnant, it is recommended that she see an obstetrician as soon as possible. This will help ensure that the doctor can consult with the appropriate specialists who can provide pre- and postnatal care for the woman and her baby.

Although we were not able to find data regarding the life expectancy for individuals with afibrinogenemia, excessive bleeding is common with this condition. These episodes may be severe, or even fatal. Bleeding in the brain is a leading cause of death in patients with this disorder. Postoperative bleeding is also commonly associated with mortality in this condition.