Rare Prekallikrein Deficiency Identified During Workup of Isolated Prolonged Activated Partial Thromboplastin Time

DISCUSSION

Preoperative coagulation testing of aPTT and prothrombin time are generally discouraged, as contemporary evidence shows coagulation testing is a poor predictor of bleeding and may lead to unnecessary delays in surgery.⁸ Instead, preoperative coagulation studies should be reserved for selected patients, especially those with active bleeding and history of a bleeding disorder.^9,10 Although test utilization practices are changing in response to current evidence, preoperative coagulation testing may still be ordered, and providers must be familiar with the workup of abnormal coagulation values.

Isolated prolonged aPTT refers to the prolongation of aPTT in the setting of a normal prothrombin time. Determining the cause of isolated prolonged aPTT is necessary to assess bleeding risk and to develop an appropriate therapeutic management plan. Our case highlights a patient with a rare factor deficiency and illustrates a contemporary approach to the workup of isolated prolonged aPTT (Figure).^3,5,11,12

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Figure.

Diagnostic algorithm for the contemporary workup of an isolated prolonged activated partial thromboplastin time (aPTT). This algorithm depicts factor activity testing, lupus anticoagulant (LA) testing, and the mixing study test performed concurrently.^3,5,11,12 HMWK, high molecular weight kininogen.

The workup begins with ruling out preanalytical causes of prolonged aPTT. Preanalytical causes include heparin contamination through an intravenous line, collection of serum or a clotted sample, and/or altered plasma to citrate ratio due to hemoconcentration (hematocrit >55%) or incorrectly filled collection tubes.⁵ Information regarding the patient's anticoagulant status is critically important, and whenever possible, specimens should be collected in patients not receiving any anticoagulant treatment. The thrombin time test can be elevated in the presence of thrombin-inhibiting anticoagulant medications. Therefore, the thrombin time test can be performed as a screening test to rule out interference with thrombin-inhibiting anticoagulant drugs.⁵

In the medical curriculum, the mixing study has traditionally been taught as the initial test to differentiate between factor deficiency and the presence of an inhibitor. However, in clinical practice, mixing study tests are often conducted concurrently with other coagulation tests or omitted entirely.¹³ The contemporary approach to investigating an isolated prolonged aPTT prioritizes evaluating for factor deficiency, a clinically relevant diagnosis, and assessing for the presence of lupus anticoagulant antibodies, the most common cause of isolated prolonged aPTT.³ While the mixing study test is less emphasized, it may still offer valuable insights for guiding a hemostatic workup. Consequently, factor activity testing, lupus anticoagulant testing, and mixing study tests are performed concurrently in the contemporary diagnostic algorithm, rather than following a stepwise approach starting with the mixing study.

Factor activity tests are performed in the workup of an isolated prolonged aPTT to determine whether a factor deficiency or inhibitor is present. Factor activity tests for factors VIII, IX, and XI should be performed because deficiencies of these factors are associated with clinical bleeding. Factor activity tests can also suggest the presence of inhibitors, as inhibitors can cause factor activity to appear low or demonstrate an inhibitor pattern during testing (ie, factor activity appears to increase with each dilution).⁵ If an inhibitor pattern is identified or is suspected for a specific factor, factor inhibitor testing can be performed to confirm the presence of the specific factor being investigated. A noteworthy point is that patients with von Willebrand disease may also present with an isolated prolonged aPTT because of the reduced factor VIII causing the aPTT prolongation.¹⁴ Factor VIII levels may be reduced in patients with von Willebrand disease because von Willebrand factor protects factor VIII from proteolysis.¹⁵ Therefore, workup for von Willebrand disease may be appropriate for patients with both isolated prolonged aPTT and reduced factor VIII; however, aPTT is not a reliable test in screening for a diagnosis of von Willebrand disease.¹⁶

Lupus anticoagulants are a heterogeneous group of antibodies directed against phospholipid-binding proteins, thereby prolonging phospholipid-dependent coagulation assays. Clinically, however, lupus anticoagulants are associated with increased risk for thrombosis and not with anticoagulation in vivo as the name suggests. Because lupus anticoagulants are the most common cause of an isolated prolonged aPTT, lupus anticoagulant testing should be performed to investigate prolonged aPTT. Examples of lupus anticoagulant tests include the dilute Russell viper venom time and aPTT-based tests utilizing a low concentration of phospholipid.¹¹ In the workup of antiphospholipid antibody syndrome, lupus anticoagulant testing should be performed together with tests for anticardiolipin and beta-2 glycoprotein 1 antibodies.¹¹

Mixing studies are performed by mixing an equal volume of citrated patient plasma with normal pooled plasma. The 1:1 mix is then tested for aPTT both immediately after mixing and after a 1- to 2-hour incubation at 37 °C to assess for time- and temperature-dependent inhibitors. Because only 30% of factor activity is sufficient to yield a normal aPTT result, the 1:1 mixture should allow for the aPTT of the mix to correct into the normal reference range if a sample is factor deficient.⁵ Conversely, an aPTT mixing study that does not correct suggests the presence of an inhibitor. Lupus anticoagulants act as inhibitors of coagulation and therefore demonstrate a mixing study that does not correct.⁵ In many instances, a mixing study is bypassed altogether, as mixing studies are not standardized and can be difficult to interpret,¹³ such as in instances of near-complete correction in the setting of multiple factor deficiencies or correction in the setting of a weak lupus anticoagulant that is diluted out with the addition of normal plasma. For some providers, the mixing study serves as a secondary screening assay, while specific factor activities, factor inhibitor studies, and lupus anticoagulant testing allow for definitive diagnosis.¹³

If deficiencies and inhibitors of factors VIII, IX, and XI are excluded, and a mixing study demonstrates correction, measurement of contact factors can be performed to evaluate for contact factor deficiency. Benzon et al reported that factor XII deficiency was the most frequent factor deficiency identified in adult patients with isolated prolonged aPTT, while deficiencies of prekallikrein and high molecular weight kininogen are uncommon.¹⁷ Contact factor tests are typically performed at specialized reference laboratories. In general, providers must weigh the benefits of additional testing against the potential delay of treatment. Some physicians may argue that the measurement of contact factors does not add significant value once lupus anticoagulants and deficiencies of factors VIII, IX, and XI are excluded.

If factor deficiencies/inhibitors and lupus anticoagulants are excluded, alternate causes for a prolonged aPTT can be explored, such as elevated C-reactive protein displaying phospholipid-dependent interference with aPTT¹⁸ or lupus anticoagulants not detected by the lupus anticoagulant tests because other variables influenced the testing. For instance, acute phase reactants, such as elevated factor VIII, shorten the aPTT and may mask lupus anticoagulants during lupus anticoagulant testing.¹⁹

Plasma prekallikrein, also known as Fletcher factor, is a contact factor that participates in the initiation of the intrinsic coagulation pathway. In circulation, prekallikrein is mainly complexed with high molecular weight kininogen.^20-22 As a zymogen, prekallikrein is activated to the serine protease kallikrein by activated factor XII (XIIa), with high molecular weight kininogen as a cofactor. Kallikrein in turn initiates surface-mediated activation of coagulation and participates in fibrinolysis and kinin generation.²²

Deficiencies of prekallikrein may result in prolongation of the aPTT. Congenital prekallikrein deficiency is a rare autosomal recessive condition associated with mutations of the KLKB1 gene.²¹ In a 2020 study, Barco et al analyzed 111 individuals with prekallikrein deficiency, the largest cohort to date.²³ The authors estimated the prevalence of severe prekallikrein deficiency to be 1/155,668 overall and 1/4,725 for individuals of African ancestry. The study also demonstrated a low prevalence of bleeding events, consistent with the understanding that clinical bleeding is not associated with prekallikrein deficiency.²³ In general, genetic testing for KLKB1 mutations is not required in routine practice.