Clinical practice

Vascular anomalies causing bleeding complications in children are various forms of structural anomalies, such as hereditary hemorrhagic telangiectasia, disorders of the connective tissue (including Ehlers–Danlos disease and osteogenesis imperfecta), and small vessel vasculitis [24]. The Ehlers–Danlos disease includes a clinically and genetically heterogeneous group of connective tissue diseases of which the key features are skin hyperextensibility, delayed wound healing with atrophic scarring, joint hypermobility, easy bruising, and generalized connective tissue fragility.

In children, excessive bruising is frequently the presenting symptom, especially in the vascular type of Ehlers–Danlos disease. Other common signs are bleeding from the gums following brushing of the teeth and after tooth extraction. Ehlers–Danlos syndrome is often associated with platelet or coagulation abnormalities such as platelet function disorders and deficiencies of factors XIII, IX and XI. However, generalized vascular fragility dominates the clinical picture. It sometimes leads to severe varicosities and arterial rupture, which may cause sudden death, usually in the third or fourth decade of life.

VWD was first described by Erik von Willebrand in 1926. Several decades later, it was recognized that it is caused by deficient or defective VWF, a very large multimeric glycoprotein, which (1) promotes the adhesion of platelets to the injured vessel and to each other and (2) binds and stabilizes factor VIII (FVIII). It is the most frequent inherited bleeding disorder with an incidence around 1% [6]. VWD is classified into six different types: type 1 is due to partial quantitative deficiency of VWF, types 2A, 2B, 2M, and 2N are due to qualitative defects of VWF, and type 3 to a total absence of VWF. Type 1 accounts for about 70% of all VWD cases and is inherited in an autosomal dominant manner. Type 2 accounts for 25% of all cases and the inheritance is either autosomal dominant or autosomal recessive. Type 3 accounts for less than 5% and is transmitted as an autosomal dominant trait. The clinical picture varies but usually comprises mild to moderate mucocutaneous bleeding including bruising without trauma, epistaxis, prolonged bleeding after dental extractions, menorrhagia, and prolonged or excessive bleeding after childbirth. Clinical manifestations in type 2N resemble those of mild hemophilia A. Type 3 is the most severe form of VWD because of the combination of the absence of VWF and profound deficiency of FVIII. Bleeding manifestations are mucocutaneous hemorrhages but most of all prolonged bleeding after surgery. Desmopressin is generally an effective preventative or curative treatment for bleeding in type 1. Desmopressin is a synthetic analog of the pituitary antidiuretic hormone vasopressin. It induces an increase in plasma levels of VWF and FVIII, and it improves platelet adhesion and aggregation. The exact mechanism of action, however, is not fully understood [16]. In patients with type 2 VWD, the response to desmopressin is variable and therapy with purified human VWF is often required. Patients with type 3 VWD need therapy with purified human VWF in combination with FVIII. These children should be seen by an experienced hematologist.

The normal platelet count for neonates and children ranges from 150 to 450 × 10⁹/L. Thrombocytopenia is defined as a platelet count of less than 150 × 10⁹/L. In general, the risk of bleeding is relatively small unless the platelet count drops to less than 50 × 10⁹/L. Spontaneous bleeding usually does not occur until the platelet count is less than 20 × 10⁹/L and is also dependent on the cause of thrombocytopenia. For example, the risk of intracranial hemorrhage is higher in neonates with a platelet count of less than 30 × 10⁹/L caused by alloimmune thrombocytopenia than by autoimmune thrombocytopenia. When thrombocytopenia is detected, therapy is not always necessary. It is essential to implement reasonable precautions to minimize bleeding complications such as avoiding aspirin and nonsteroidal anti-inflammatory drugs, intramuscular injections, and contact sports in school children and adolescents. However, in some patients, prompt treatment is required to prevent long-term disability.

Platelet function disorders in children can be classified into acquired or inherited disorders. Most platelet function disorders are acquired. The most frequent cause of acquired platelet dysfunction is medication including nonsteroidal anti-inflammatory drugs, aspirin, valproic acid, beta-lactam antibiotics, and selective serotonin reuptake inhibitors [23]. Acquired platelet dysfunction can also be a complication of an underlying disease such as renal failure, liver disease, and malignant disorders [4]. Inherited disorders of platelet function are a rare and heterogeneous group of diseases, which are characterized by easy bruising, epistaxis, menorrhagia, and mucocutaneous and perioperative bleeding. Classification of these disorders is usually based on alterations in function or structure [13]. In the German-speaking countries, the incidence has been estimated to be 1.3 to 2.2 affected children per one million children [18]. Only in half of the children, defects were well classified: 32% presented with Glanzmann thrombasthenia, 21% with aspirin-like defects, 17% with platelet receptor defects, 15% with storage pool disorders, 8% with Bernard–Soulier syndrome, and 7% with other defects.

Treatment of platelet function disorders consists of desmopressin, antifibrinolytic agents, or transfusion of platelets. Many disorders respond well to desmopressin [18, 33]. It is advisable to test the therapeutic efficacy of desmopressin. Platelet transfusions should be used in patients with severe bleeding complications, which do not respond on medical therapy and platelet defects that cannot be managed by desmopressin therapy. Alloantibodies either to human leucocyte antigens or missing GPs may easily occur. An alternative in patients who no longer respond to platelet transfusions is recombinant factor VIIa [14].

It is essential to perform a complete blood count to study the number of platelets. The result of the blood count will rapidly eliminate or diagnose thrombocytopenia as the cause of bleeding. It is important to realize that a low number of platelets affects potential platelet function testing. In the past, platelets were counted manually with phase-contrast microscopy. The introduction of automated full blood counters has improved the precision and velocity of counting. Additionally, these counters made it possible to record various platelet indices including MPV. Normal ranges for platelet counts and MPV do not differ from adult normal ranges [2, 9]. In giant platelet disorders such as Bernard–Soulier, MPV is high, whereas in Wiskott–Aldrich syndrome, MPV is low, reflecting the small size of the platelets in this syndrome. MPV may not always reflect the actual platelet size, especially in thrombocytopenia and in giant-platelet disorders. Furthermore, the presence of anemia may give an indication for the severity of acute or chronic blood loss as a result of bleeding. Chronic blood loss is usually represented by a hypochomic, microcytic anemia, while acute blood loss is characterized by a normocytic anemia. Both anemias are accompanied by a low number of reticulocytes. If thrombocytopenia is caused by bone marrow failure, it is usually accompanied by another suppressed blood cell line, i.e., normocytic anemia with reticulopenia and/or leucopenia.

A peripheral blood smear is indispensable in any patient with a potential platelet disorder to rule out thrombocytopenia which is the result of clumping of the platelets, to identify abnormal cells including blasts, and to examine platelet morphology. Electron microscopy can, for example, identify the absence of α-granules in gray platelet syndrome.

The bleeding time, developed by Duke in 1910, was the first test to assess primary hemostasis in vivo [11]. In this test, which was improved by Ivy, the patient was stabbed by a lancet on the ventral side of the forearm while a blood pressure cuff was placed on the upper arm and inflated to 40 mmHg. Blood was drawn off every 30 s by a filter paper, and the bleeding time was documented as the time from when the wound was made until bleeding stopped. Andrew et al. used a modified device that makes a smaller skin incision and showed that bleeding times in neonates are shorter than those in adults [1]. The shorter bleeding time or enhanced platelet–vessel interaction in healthy neonates compared to older children or adults is caused by the higher concentration and activity of circulating VWF and higher hematocrit [15]. In the recent past, this test has become less popular due to its invasiveness, low sensitivity and specificity, and its inability to predict bleeding in unselected patients. Especially in neonates and infants, this test is time-consuming and difficult to perform and standardize [8]. In most hospitals, the in vivo bleeding time is, therefore, replaced by the in vitro bleeding time devices in particular the PFA-100. This test needs about 1 ml of citrated whole blood, is easy to perform, and produces results very rapidly. In the PFA-100, citrated whole blood is applied to a cartridge with a membrane that is coated with collagen/epinephrine or collagen/ADP. This membrane has a very small aperture, which occludes after contact with the applied blood. The time necessary to occlude the aperture is the closure time. Term neonates have shorter closure times than older children or adults [5]. Infants and older children have closure times in the same range as those in adults [22]. Although the PFA-100 is more sensitive and reliable than the bleeding time, it is not the perfect screening tool for primary hemostatic disorders [31]. It is highly sensitive for severe VWD and platelet defects, including Bernard–Soulier syndrome, but it is insensitive for mild disorders such as mild type 1 VWD, storage pool disease, and Hermansky–Pudlak syndrome. False-positive results may easily occur, especially in anemic patients. As a consequence, PFA-100 may help to exclude severe forms of VWD and platelet defects in children, especially when it is difficult to obtain blood. However, if clinical suspicion of a bleeding disorder is high and PFA is normal, other tests are still required including VWF and platelet function tests. Additionally, because abnormal PFA-100 results are not specific, further investigation is required in patients with abnormal PFA-100 results.

Besides mediating the initial adhesion of platelets at the sides of vascular injury, an additional function of VWF is binding and stabilizing FVIII in the circulation. Therefore, initial tests to detect VWD or low VWF include VWF:Ag, VWF:RCo, and FVIII activity [26]. The normal values of these tests range from 50 to 150 IU/dL. VWF:Ag is a qualitative immunoassay that measures the concentration of VWF protein in the plasma. VWF:RCo is a functional assay of VWF that measures its ability to interact with normal platelets. In this assay, the antibiotic ristocetin causes VWF to bind to platelets resulting in platelet clumps. Several methods can be used to detect platelet clumping.

FVIII coagulant assay is a measure of the function of the clotting factor FVIII in plasma. In VWD, the VWF:Ag and VWF:RCo are both decreased. A low VWF may result in a low level of FVIII leading to a prolonged activated partial thromboplastin time.

The coefficient of variation of all three assays is high, especially that of the VWF:RCo assay. It has been measured in laboratory surveys at 30% or greater, and it is still higher when the VWF:RCo is lower than 12–15 IU/dL. Nevertheless, it is still the most broadly accepted laboratory test of VWF function. The coefficient of variation of the VWF:Ag and FVIII assay is also relatively high (about 10–20% or greater) [17]. The quality of laboratory testing varies among laboratories as well. Repeated testing for VWD is sometimes necessary to detect low levels of VWF. Plasma levels of VWF increase due to systemic inflammation, administration of oral contraceptives, and stress including surgery, exercise, anxiety, and crying in an anxious child. The phlebotomy should be performed in a quiet setting and as atraumatic as possible to limit exposure of tissue factor from the site and the activation of clotting factors, minimizing falsely high or low values. Furthermore, individuals who have blood type O have concentrations approximately 25% lower compared to persons who have other ABO blood types. In conclusion, the high variability of the three diagnostic assays as well as the variability of plasma levels of VWF and FVIII as result of conditions of the patient or blood sample make it difficult to diagnose VWD or classify the VWD subtype.

The VWF:RCo-to-VWF:Ag ratio can help to discriminate between type 1 and type 2 VWD. A ratio of <0.5 – 0.7 is suggestive of type 2A, 2B, and 2M VWD (Table 3). Most tests to classify the subtypes of VWD, such as multimer analysis, can only be performed in specialized coagulation laboratories. Classification of subtypes of VWD is mandatory, as desmopressin therapy causes thrombocytopenia in type 2B and is therefore contraindicated. Genetic testing may help to find the correct diagnosis and select affected family members.

Platelet aggregation tests remain the “gold standard” for the evaluation of platelet function. In the second step, specific diagnostic tests should be used to confirm the hypothesis such as platelet secretion tests, flow cytometry, and measurement of platelet nucleotides. All these specialized tests are only performed in specialized coagulation laboratories. These tests are time-consuming, technically challenging, and require large volumes of freshly drawn citrated blood, which is an important drawback in studying young children. Investigating neonates without bleeding symptoms but with a positive family history should therefore be deferred to a later date when the child is older. In healthy children older than 1 year, platelet aggregation and dense granule release of adenosine triphosphate (ATP) do not vary significantly with age and are not different than results in adults, which suggest that established adult normal ranges may be used in children beyond 1 year [19].

The most common method of assessing platelet function is light transmission aggregometry. In this test, agonists such as ADP, epinephrine, collagen, or arachidonic acid are added to platelet-rich plasma in a cuvette at 37°C, which is stirred between a light source and a photocell. When an agonist is added, the platelets aggregate and absorb less light, which is detected by the photocell, producing a specific aggregation trace. Characteristic patterns of aggregation tracings obtained using an agonist panel can be indicative of a specific diagnosis, especially abnormalities of the platelet receptors (Table 4). For example, an absent aggregation to all agonists with a normal response to ristocetin indicates Glanzmann thrombasthenia. The diagnosis can be confirmed by flow cytometry that determines the lack of GPIIbIIIa on the platelet surface. In patients with abnormalities of the platelet granules causing SPD, there is a large variability in platelet aggregation. In a large study of 106 patients with δ-SPD, only 33% had typical aggregation traces, whereas about 25% had normal aggregation. To detect patients with SPD, measurement of platelet nucleotides or lumi-aggregometry may be more sensitive than light transmission aggregometry. Lumi-aggregometry is a modification of light transmission aggreggometry, which measures ATP release from the dense granules. Detailed algorithms for diagnostic approach to children with suspected inherited disorders of platelet function have been published [3, 13].