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Query: UMLS:C0409974 (
lupus
)
22,386
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Most causes of abnormal bleeding can be determined from a complete blood count including platelet count and bleeding, prothrombin, activated partial thromboplastin, and thrombin times. Occasionally, further evaluation is necessary, such as tests of factor XIII function, fibrinolysis, and vascular integrity. Possible diagnoses include disseminated intravascular coagulation, thrombotic thrombocytopenic purpura,
vitamin K deficiency
, von Willebrand's disease, heparin-induced thrombocytopenia, acquired inhibitors of factor VIII,
lupus
anticoagulants, and coagulation disorders related to the acquired immunodeficiency syndrome.
...
PMID:Laboratory evaluation of a bleeding patient. 266 Apr 7
Coagulation disorders usually confront the emergency physician as bleeding episodes or as abnormalities of laboratory tests. Bleeding has to be treated aggressively, while pathological coagulation tests should be related to a more differentiated diagnosis at first. The most common causes of acquired coagulation disorders are liver disease,
vitamin K deficiency
, and disseminated intravascular coagulation (DIC). More rarely, inhibitors, external factors such as drugs or extracorporeal circulation, or other diseases such as amyloidosis are present. Since localized hemorrhage is the most common bleeding source in liver disease, endoscopic and surgical therapeutic measures, respectively, are warranted. Careful and balanced substitution therapy according to laboratory findings should be initiated simultaneously and should consist of fresh frozen plasma (FFP), which contains all components of the coagulation system physiologically balanced. Prothrombin complex concentrates should be used in emergency situations only, keeping their potential hazards in mind. Adequate vitamin K substitution is indicated in liver disease as well as in coagulopathy due to
vitamin K deficiency
. Management of DIC primarily consists of aggressive treatment of the underlying disease. Substitution therapy is difficult and should be carefully monitored by the adequate laboratory tests. FFP is the adequate source of both procoagulants and inhibitors but may cause certain problems. Heparin therapy can be beneficial but is not recommended generally. Antithrombin III substitution cannot be assumed as established therapy so far. Inhibitors can lead to bleeding, but the most common inhibitor,
lupus
anticoagulant, rather predisposes to thrombosis. In bleeding patients with inhibitors against single clotting factors, treatment consists of adequate substitution before initiating the diagnostic workup.
...
PMID:Management of acquired coagulation disorders in emergency and intensive-care medicine. 871 94
We have assessed the proficiency of diagnostic haemostasis facilities to correctly identify coagulation factor abnormalities and inhibitors. Forty-two laboratories participating in the external Quality Assurance Program (QAP) conducted by the RCPA agreed to participate and were each sent a set of eight samples (each 3 x 1 ml) for evaluation. They were asked to blind test these samples for the presence or absence of inhibitors, and where identified, to perform further analysis (including specific inhibitor analysis). In order to make the exercise more challenging, in addition to true factor inhibitors, samples were provided that reflected potential pre-analytical variables that might arise and complicate inhibitor detection or lead to false inhibitor identification. In brief, the sample set comprised a true high level factor (F) V inhibitor, a true moderate level FVIII inhibitor (but sample was defibrinogenated), a true
lupus
anticoagulant (LA), a normal (but slightly aged) plasma sample, a normal serum sample, a normal EDTA sample, an oral anticoagulant/
vitamin K deficiency
sample, and a gross heparin ( approximately 10 U/ml) contaminated sample. Sixty-three percent of participants correctly identified the true FV inhibitor as such, although the reported range varied greatly [10 to >250 Bethesda units (BU/ml)] and 46% correctly identified the true FVIII inhibitor, despite the complication of the sample presentation, although the reported range also varied (7 to 64 BU/ml). Some laboratories either failed to identify the inhibitor present, or misidentified the inhibitor type. The LA, the oral anticoagulant/
vitamin K deficiency
, the normal serum sample, and the normal (aged) sample were also correctly identified by most laboratories, as was the absence of specific factor inhibitors in these samples. However, a small subset of laboratories incorrectly identified the presence of specific factor inhibitors in some of these samples. The heparin sample was also correctly identified by most (68%) laboratories. In contrast, the normal EDTA sample was misidentified as a FV and/or FVIII inhibitor by most (68%) laboratories, and only one laboratory correctly identified this as an EDTA sample. Thus, we conclude that although laboratories are able, in most cases, to identify the presence of true factor inhibitors, there is a large variation in identified inhibitor levels and there are also some significant errors in identification (i.e. false negatives and misidentifications). In addition, there is a significant false positive error rate where some laboratories will identify the presence of specific factor inhibitors where no such inhibitor exists (i.e. false positives).
...
PMID:Identification of factor inhibitors by diagnostic haemostasis laboratories: a large multi-centre evaluation. 1680 54
Topical hemostats, fibrin sealants, and surgical adhesives are regularly used in a variety of surgical procedures involving multiple disciplines. Generally, these adjuncts to surgical hemostasis are valuable means for improving wound visualization, reducing blood loss or adding tissue adherence; however, some of these agents are responsible for under-recognized adverse reactions and outcomes. Bovine thrombin, for example, is a topical hemostat with a long history of clinical application that is widely used alone or in combination with other hemostatic agents. Hematologists and coagulation experts are aware that these agents can lead to development of an immune-mediated coagulopathy (IMC). A paucity of data on the incidence of IMC contributes to under-recognition and leaves many surgeons unaware that this clinical entity, originating from normal immune responses to foreign antigen exposure, requires enhanced post-operative vigilance and judicious clinical judgment to achieve best outcomes.Postoperative bleeding may result from issues such as loosened ties or clips or the occurrence of a coagulopathy due to hemodilution,
vitamin K deficiency
, disseminated intravascular coagulation (DIC) or post-transfusion, post-shock coagulopathic states. Other causes, such as liver disease, may be ruled out by a careful patient history and common pre-operative liver function tests. Less common are coagulopathies secondary to pathologic immune responses. Such coagulopathies include those that may result from inherent patient problems such as patients with an immune dysfunction related to systemic
lupus
erythrematosus (SLE) or lymphoma that can invoke antibodies against native coagulation factors. Medical interventions may also provoke antibody formation in the form of self-directed anti-coagulation factor antibodies, that result in problematic bleeding; it is these iatrogenic post-operative coagulopathies, including those associated with bovine thrombin exposure and its clinical context, that this panel was convened to address.The RETACC panel's goal was to attain a logical consensus by reviewing the scientific evidence surrounding IMC and to make recommendations for the clinical recognition, diagnosis and evaluation, and clinical management of these complications. In light of the under-recognition and under-reporting of IMC, and given the associated morbidity, utilization of health care resources, and potential economic impact to hospitals, the panel engaged in a detailed review of peer-reviewed reports of bovine thrombin associated IMC. From that clinical knowledge base, recommendations were developed to guide clinicians in the recognition, diagnosis, and management of this challenging condition.
...
PMID:Building an immune-mediated coagulopathy consensus: early recognition and evaluation to enhance post-surgical patient safety. 1946 80
Use of a coagulation panel [prothrombin time (PT), partial thromboplastin time (PTT), thrombin time (TT) and fibrinogen], intended for evaluation of bleeding, tripled over 6 years, out of proportion to admissions, surgery, or transfusions. To determine whether the panels were ordered appropriately, we classified 28,737 sets of panel results into groups followed by chart reviews to determine typical patient histories. In 39% of panels, PT/PTT was normal. Prolonged PT occurred in 33% of results, due to liver failure (8%), warfarin (23%), and presumed
vitamin K deficiency
(69%). Prolonged PTT occurred in 34% of results and was primarily associated with long PT or
lupus
inhibitors. Prolonged PTT and TT (15% of panels) indicated heparin therapy. Fibrinogen was normal in 98% and low in 1.4%. Critical fibrinogen (below 100 mg/dl, 0.6% of panels) was associated with bleeding in 90% of patients. Only 8% of panel orders were clinically indicated based on patient history. Clinician interviews indicated many were unaware the panel included fibrinogen and TT. Interventions included an education program and an order form change. The education program had no effect on overall order volume or test selection. A later order form change made TT and fibrinogen a separate order. This reduced TT and fibrinogen testing by 90% without complaints or changes in blood transfusion statistics. We conclude that many coagulation test panel orders were not clinically indicated, that PT more often diagnosed
vitamin K deficiency
than bleeding risk, and that order-based restriction of testing was more effective than educational programs at introducing change in clinical test utilization.
...
PMID:Reducing the use of coagulation test panels. 2193 88
Blood dose not normally coagulate in the blood vessels covered with endothelial cells, because these cells contain some substances responsible for antithrombotic action such as thrombomodulin, heparin-like substance, prostacyclin, nitric oxide and tissue plasminogen activator. Most important role of blood coagulation is hemostasis. Blood can coagulate in two ways: intrinsic coagulation pathway and extrinsic coagulation pathway that is activated by negatively charged substances and FVIIa-tissue-factor (TF) complex, respectively. Prothrombin time(PT) can represent extrinsic pathway, while activated partial thromboplastin time (APTT) can represent intrinsic pathway. PT is prolonged in such diseases as
vitamin K deficiency
, hepatic failure and warfarin intake, while APTT is prolonged such diseases as hemophilia A & B, von Willebrand disease and
lupus
anticoagulant. Cross mixing test is very useful to assess prolonged clotting time. FDP means fibrin/fibrinogen degradation products and D-dimer is the smallest products of fibrin degradation. These markers are often used to diagnose disseminated intravascular coagulation (DIC) and deep vein thrombosis (DVT). Thrombin-antithrombin complex (TAT) and plasmin-alpha2 plasmin inhibitor (PIC) can be used to evaluate the extent of coagulation and fibrinolysis activation, respectively. These two markers is essential for classify the pathophysiology of DIC: DIC with suppressed fibrinolysis, enhanced fibrinolysis or balanced fibrinolysis. In conclusion, exact interpretation of hemostatic and fibrinolytic markers is one of the most important abilities in clinical situation.
...
PMID:[Interpretation of hemostatic and fibrinolytic markers]. 2218 80
The first case report describes an extremely prolonged activated partial thromboplastin time (APTT) in a patient with no history of increased bleeding tendency. Heparin use was excluded. The APTT mixing study combined with the medical history suggests a deficiency in one of the non-essential coagulation factors. This was confirmed by factor XII activity of <1%. The second case report describes a prolonged APTT in a patient with no history of increased bleeding tendency. The negative bleeding tendency in combination with a failure of the mixing study to correct the coagulation assay results suggests a factor inhibitor, most probably
lupus
anticoagulant. Indeed, the
lupus
anticoagulant was positive and the anti-cardiolipin antibody titre was also positive. Aberrations in the process of haemostasis can be efficiently screened using a platelet count, an APTT, a PT and a thorough physical examination combined with a thorough medical history taking. Common causes of prolonged PT and/or APTT are the use of oral anticoagulants or heparin,
vitamin K deficiency
and liver disease. Other causes include coagulation factor deficiencies, coagulation factor inhibitors and diffuse intravascular coagulation.
...
PMID:[Investigation of coagulation time: PT and APTT]. 2291 38
The Quick test and activated partial thromboplastin time (aPTT) are so-called global assays used to characterize different steps in plasmatic hemostasis. They reflect hemostasis in its classical differentiation into extrinsic and intrinsic pathways. However, they do not cover physiological aspects of cell-based hemostasis. Results are not necessarily congruent with a specific clinical situation and do not replace a complete medical history. Patients suffering from hemophilia A or B, for example, have normal Quick test results. Severe factor XII deficiency reveals an extreme aPTT prolongation without a significant bleeding tendency. In
Lupus
patients, aPTT is also prolonged with clinically a rather increased thrombotic risk. Fibrinogen as a substrate of coagulation discloses pathological results in both global tests in case of considerable reduction. In case of positive bleeding history and a normal global assay, disorders in platelets, von Willebrand factor and factor XIII must be considered. Reduced Quick test results may be expected in factor VII, II, V, or X deficiency. Disorders of liver synthesis of coagulation factors as well as
vitamin K deficiency
will be indicated by the Quick test rather than by aPTT. The most frequent hereditary reasons for a prolonged aPTT are hemophilia A and B as well as von Willebrand disease. In case of an acquired bleeding tendency, the diagnostic strategy must include autoantibodies. The sensitivity of the aPTT reagent varies widely. Low-molecular weight heparin and pentasaccharides do not influence the test. Oral direct inhibitors may reveal pathological results in a reagent-dependent manner.
...
PMID:[Importance of Quick, partial thromboplastin time, and Co]. 2478 34
The activated partial thromboplastin time (APTT) assay is a very common coagulation test, used for several reasons. The test is conventionally used for assessing the contact factor (intrinsic) pathway of blood coagulation, and thus for screening deficiencies in this pathway, most typically factors VIII, IX, and XI. The APTT is also sensitive to contact factor deficiencies, including factor XII, prekallikrein, and high-molecular-weight kininogen. The APTT may also be elevated in a variety of conditions, including liver disease,
vitamin K deficiency
, and disseminated intravascular coagulation. The APTT can also be used for monitoring unfractionated heparin (UFH) therapy, as well as for screening
lupus
anticoagulant (LA) or for assessing thrombosis risk. Which of these separate uses is important to a given laboratory or clinician depends on the laboratory and the clinical context. For example, UFH sensitivity is important in hospital-based laboratories, where UFH therapy is used, but not in hospital-based laboratories where low-molecular-weight heparin (LMWH) is largely employed or where UFH may be assessed by anti-factor Xa testing, or in private/community laboratories not associated with a hospital system. High sensitivity to (low levels of) factors VIII, IX, and XI is generally preferred, as their deficiencies are clinically significant. Also preferred, but not usually achieved, is low sensitivity to factor XII and other contact factors, as these deficiencies are usually asymptomatic. Nevertheless, a good knowledge of factor sensitivity is usually needed, if only to help explain the reasons for a prolonged APTT in a given patient, or whether factor testing or other investigation is required. A good working knowledge of reagents sensitivity to LA is also advisable, especially when the reagent is used as part of a LA test panel, or else as a "general-purpose screening reagent." The current report is aimed at providing some guidance around these questions, and is intended as a kind of "how to" guide, that will enable laboratories to assess APTT reagents in regard to their sensitivity to heparin, LA, and clotting factors. The report also provides some advice on generation of normal reference ranges, as well as solutions for troubleshooting prolonged APTTs, when performing factor testing or searching for inhibitors.
...
PMID:How to Optimize Activated Partial Thromboplastin Time (APTT) Testing: Solutions to Establishing and Verifying Normal Reference Intervals and Assessing APTT Reagents for Sensitivity to Heparin, Lupus Anticoagulant, and Clotting Factors. 3063 Feb 6
