Haemophilia B


Haemophilia B is a blood clotting disorder causing easy bruising and bleeding due to an inherited mutation of the gene for factor IX, and resulting in a deficiency of factor IX. It is less common than factor VIII deficiency.
Haemophilia B was first recognized as a distinct disease entity in 1952. It is also known by the eponym Christmas disease, named after Stephen Christmas, the first patient described with haemophilia B. In addition, the first report of its identification was published in the Christmas edition of the British Medical Journal.

Signs and symptoms

Symptoms include easy bruising, urinary tract bleeding, nosebleeds, and bleeding into joints.

Complications

Patients with bleeding disorders show a higher incidence of periodontal disease as well as dental caries, concerning the fear of bleeding which leads to a lack of oral hygiene and oral health care. The most prominent oral manifestation of a mild haemophilia B would be gingival bleeding during exfoliation of primary dentition, or prolonged bleeding after an invasive procedure/tooth extraction; In severe haemophilia, there may be spontaneous bleeding from the oral tissues, lips and gingiva, with ecchymoses. In rare cases, hemarthrosis of the temporomandibular joint may be observed.
Patients with haemophilia will experience many episodes of oral bleeding over their lifetime. Average 29.1 bleeding events per year are serious enough to require factor replacement in F VIII-deficient patients which 90% involved oral structures. Children with severe haemophilia have significant lower prevalence of dental caries and lower plaque scores compared with matched, healthy controls.

Genetics

The factor IX gene is located on the X chromosome. It is an X-linked recessive trait, which explains why males are affected in greater numbers.
In 1990, George Brownlee and Merlin Crossley showed that two sets of genetic mutations were preventing two key proteins from attaching to the DNA of people with a rare and unusual form of haemophilia B – haemophilia B Leyden – where sufferers experience episodes of excessive bleeding in childhood but have few bleeding problems after puberty.
This lack of protein attachment to the DNA was thereby turning off the gene that produces clotting factor IX, which prevents excessive bleeding.

Pathophysiology

Factor IX deficiency leads to an increased propensity for haemorrhage, which can be either spontaneously or in response to mild trauma.
Factor IX deficiency can cause interference of the coagulation cascade, thereby causing spontaneous hemorrhage when there is trauma. Factor IX when activated activates factor X which helps fibrinogen to fibrin conversion.
Factor IX becomes active eventually in coagulation by cofactor factor VIII. Platelets provide a binding site for both cofactors. This complex will eventually activate factor X.

Diagnosis

The diagnosis for hemophilia B can be done via the following tests/methods:
The differential diagnosis for this inherited condition is the following: hemophilia A, factor XI deficiency, von Willebrand disease, fibrinogen disorders and Bernard–Soulier syndrome

Treatment

Treatment is given intermittently, when there is significant bleeding. It includes intravenous infusion of factor IX and/or blood transfusions. NSAIDS should be avoided once the diagnosis is made since they can exacerbate a bleeding episode. Any surgical procedure should be done with concomitant tranexamic acid.

Dental considerations

Surgical treatment, including a simple dental extraction, must be planned to minimize the risk of bleeding, excessive bruising, or hematoma formation. Soft vacuum-formed splints can be used to provide local protection following a dental extraction or prolonged post-extraction bleed.

History

In the 1950s and 1960s, with newfound technology and gradual advances in medicine, pharmaceutical scientists found a way to take the factor IX from fresh frozen plasma and give it to those with haemophilia B. Though they found a way to treat the disease, the FFP contained only a small amount of factor IX, requiring large amounts of FFP to treat an actual bleeding episode, which resulted in the person requiring hospitalization. By the mid-1960s scientists found a way to get a larger amount of factor IX from FFP. By the late 1960s, pharmaceutical scientists found methods to separate the factor IX from plasma, which allows for neatly packaged bottles of factor IX concentrates. With the rise of factor IX concentrates it became easier for people to get treatment at home. Although these advances in medicine had a significant positive impact on the treatment of haemophilia, there were many complications that came with it. By the early 1980s, scientists discovered that the medicines they had created were transferring blood-borne viruses, such as hepatitis, and HIV, the virus that causes AIDS. With the rise of these deadly viruses, scientists had to find improved methods for screening the blood products they received from donors.In 1982, scientists made a breakthrough in medicine and were able to clone factor IX gene. With this new development it decreased the risk of the many viruses. Although the new factor was created, it wasn't available for haemophilia B patients until 1997.

Society

In 2009, an analysis of genetic markers revealed that haemophilia B was the blood disease affecting many European royal families of Great Britain, Germany, Russia and Spain: so-called "Royal Disease".