ALBERT

Description: Introduction: 1% of patients of warfarin experience life-threatening bleeding per year and require emergency reversal of their anticoagulation. This is usually done by using a combination of vitamin K and prothrombin complex concentrate (PCC), FVIIa or FFP. Algorithms for warfarin reversal commonly use INR thresholds to guide the PCC dose. However, the INR system has only been validated for values up to 4.5. Aim: To compare the ability of PCC, FVIIa and FFP to reverse the warfarin effects on the INR and thrombin generation (TG) as measured by the calibrated automated thrombography (CAT). We hypothesised that INRs greater than 4.5 would not correlate with TG and in which case one concentration of reversal agents would be suitable to reverse warfarin in all these patients. Methods and Results: A pool of plasma from patients on warfarin (final INR 4.8) was spiked with Beriplex P/N (25Units/kg), FVIIa (~140μg/kg) and FFP (~20ml/kg). The INR normalised with Beriplex and FVIIa and was reduced to 1.4 with FFP. However, only Beriplex completely normalised TG parameters. In view of this Beriplex was used for subsequent reversal experiments. We analysed 48 plasma samples with INR 〉4.5 (median 5.5; range 4.6–8.0) and measured TG at 5pM tissue factor. We found a significant moderate correlation between the INR and the endogenous thrombin potential (ETP) which is the maximum amount of thrombin generated (r=−0.59; P= 8.0 were spiked with 5 concentrations of Beriplex P/N (7.5, 15, 25, 35 & 50Units/kg) in order to decide which is the ideal concentration of this PCC to reverse warfarin effects on the CAT. Both samples showed that a concentration between 25 and 35Units/kg could normalise TG without producing hypercoagulability. Hence we chose 30Units/kg to spike another 10 samples with INR 〉4.5 (mean 6.4; range 4.7–8.0). The INR, TG and FII, VII, IX and X were tested after the addition of Beriplex P/N. The INR normalised in all samples (median 1.2; range 1.08–1.3) as did the ETP (median 1942nM.min; range 1546–2753nM.min), FII (mean 114U/dl; range 76–126U/dl), FIX (mean 127U/dl; range 106–154U/dl) and FX (mean 131U/dl; range 120–140U/dl). FVII increased to a mean 52U/dl (range 20–68U/dl). A lower concentration of Beriplex (25U/ kg) did not satisfactorily normalise the INR and TG in all samples tested. Conclusion: PCCs fully reverse the effects of warfarin when compared to standard doses of FFP and FVIIa. INRs 〉4.5 still correlate with TG but the amount of thrombin generated was comparatively low making the use of one dose of PCC (30U/kg) suitable for reversing the effect of all INRs 〉4.5. This not only simplifies the reversal algorithms but reduces cost since doses up to 50U/kg are sometimes advocated for INRs 〉6.0.

Description: Background: We have previously shown that a single intravenous administration of a self-complementary adeno-associated virus (scAAV) vector containing a codon-optimised factor IX gene, under control of a synthetic liver specific promoter and pseudotyped with serotype 8 capsid, (scAAV2/8-LP1-hFIXco) resulted in a dose-dependent increase in plasma FIX levels in all 10 enrolled severe hemophilia B (HB) patients (ClinicalTrials.gov:NCT00979238; Nathwani et al 2011). FIX activity was stably maintained for at least 3 years (Nathwani et al 2014) but concerns over FIX expression declining over time remain. This is because AAV-mediated transgene expression is mediated mainly by episomally retained viral genomes, which may be lost with natural hepatocyte turn-over. The only vector-associated adverse event was an asymptomatic rise in liver enzymes associated with a decline in FIX levels, occurring within 3 months of gene transfer in two-thirds of the patients treated at a dose of 2x1012 vector genomes(vg)/kg. Liver enzymes normalized with corticosteroids without complete loss of transgene expression. There was no long-lasting toxicity over a period of 3 years but further follow-up is required. The vector preparation used contained an excess of empty capsids, which lacked a full-length viral genome, and are therefore, non-functional but capable of provoking an immune response against transduced hepatocytes. Therefore, a new clinical preparation of scAAV2/8-LP1-hFIXco was manufactured from which most of the empty particles were removed by caesium chloride density centrifugation in the hope that this would reduce the risk of hepatotoxicity. We report on the evaluation of this new vector preparation in severe HB patients and provide an update on up to 8 years follow-up of our original cohort of patients. Methods: Ten subjects were recruited in 2010-2012 to the initial dose-escalation/extension study arm, which entailed a single intravenous infusion of scAAV2/8-LP1-hFIXco (full: empty capsid ratio ~1:10) at a dose of either 2x1011vg/kg, 6x1011vg/kg or 2x1012vg/kg. Two severe HB patients (FIX

Description: Investigation of three families with von Willebrand disease showed that haemorrhagic symptoms were associated with disproportionately reduced collagen binding activity whilst Ristocetin co-factor activity was commensurate with antigen and multimeric analysis was normal. Genetic analysis revealed heterozygosity for two novel mutations in two of the families: W1745C in exon 30 and S1783A in exon 31. In the third family the affected individuals were heterozygous for a previously-described mutation: S1731T in exon 30 but two unaffected individuals also carried this mutation. All three mutations lie in the A3 domain containing the main collagen binding site in VWF. In patients’ samples VWF:CB activity was measured using human type I and type III collagen. Patients heterozygous for W1745C and S1731T showed a reduction in binding to both collagens but more marked reduction in binding to type III collagen. Heterozygosity for S1731T resulted in mild impairment of type I collagen binding but normal binding to type III collagen. Site-directed mutagenesis was used to generate vectors containing the three mutations (S1731T, W1745C and S1783A) and also one containing a W1745A mutation. Mutated VWF was expressed in HEK293T cells both singly and in co-transfection with a wild-type VWF (wtVWF) vector. All VWF mutants were expressed at a similar rate to wtVWF. Multimeric analysis demonstrated that all the mutants had a similar multimeric structure compared to recombinant wtVWF. However recombinant-wtVWF (wtVWF) had a lower collagen binding to VWF antigen ratio (CB:Ag) compared to plasma VWF (0.39 type I collagen and 0.45 type III collagen vs 〉0.7 for plasma VWF). This is most likely due to the slight shift towards lower molecule weight multimers seen with recombinant VWF. CB:Ag ratios for the recombinant VWF showed the same pattern of binding to collagen type I and III as the clinical samples. The W1745A mutant demonstrated a similar CB:Ag ratio to W1745C. Kinetic analysis of binding to type I collagen demonstrated that W1745C, W1745A and S1783A did not bind and that S1731T bound with significantly less affinity compared to wtVWF (KD,app 27.1 ± 0.5nM and 7.3 ± 0.8nM respectively). Analysis of binding to type III collagen demonstrated that W1745C and W1745A both bound with ~ 8-fold reduced affinity (KD,app 16 ± 2.6nM and 21.3 ± 6.3nM) but wtVWF and S1731T bound with similar affinity, (KD,app 2.0 ± 0.1nM and 3.7 ± 0.85nM respectively). Analysis of the crystal structure of the VWF A3 domain showed that W1745 may interact with Y1780 and we noted the mutation Y1780A has also been shown to significantly reduce collagen binding. Measurement of free thiols present in VWF demonstrated that the new cysteine residue in W1745C is not involved in disulphide bond formation. These results indicate that it is the loss of W1745 rather than the creation of a new cysteine residue that is responsible for the loss of collagen binding activity. We therefore hypothesised that W1745 and Y1780 participate in an internal aromatic interaction that helps to maintain the structural configuration of A3. We sought confirmation by expressing another mutant; W1745F, replacing the tryptophan with another aromatic amino acid. As predicted this did not significantly affect collagen binding. In conclusion, our findings demonstrate that type 2 VWD may be arise from mutations in A3 causing abnormal collagen binding without other functional defects or abnormalities in multimer formation. This type of VWD may be under-recognised unless laboratories measure binding to both types I and III collagen. Mutations in A3 yield insights into the structural requirements for collagen binding may have differential effects on binding to collagen types I and III and can result in variable clinical phenotypes. Some mutations may not be consistently associated with bleeding symptoms.

Description: Background: The direct, oral, factor Xa inhibitor, rivaroxaban, is increasingly used to provide effective anticoagulation in atrial fibrillation and venous thromboembolism. Whilst rivaroxaban does not require therapeutic monitoring there are situations when it is useful to estimate the anticoagulant effect of the drug such as during bleeding episodes or before emergency surgery. It has previously been shown that conventional coagulation tests can provide a crude estimation of anticoagulant effect of rivaroxaban if a sensitive reagent is used. In this study we explore whether rotational thromboelastometry (ROTEM) would provide a more accurate measure of rivaroxaban effect. Methods: Peak serum rivaroxaban levels were taken 3-5 hours post-dose in 121 consecutive patients established on a once-daily anticoagulation regime with rivaroxaban. Conventional coagulation tests, prothrombin time (PT) and activated partial thromboplastin time (APTT) were performed alongside rivaroxaban level and rotational thromboelastometry (ROTEM, TEM Ltd, Germany) on native citrated whole blood. PT and APTT used HemosIL Recombiplastin 2G and SynthasIL reagents (Instrumentation Laboratory (IL), USA) respectively. Rivaroxaban levels were measured using HemosIL Liquid Anti Xa kit (IL, USA) with rivaroxaban calibrators from Hyphen Biomed, France on an ACL TOP 700 coagulometer (IL, USA)). Demographic and biochemical data was collected on each patient. Results were analysed to determine if ROTEM can be used to assess the anticoagulant effect of rivaroxaban in real-world patients with different demographics and organ function. Results: Significant positive correlation was seen between rivaroxaban level and prothrombin time (PT) (R=0.796, Pearson's correlation coefficient). Weaker correlation was observed between rivaroxaban level and activated partial thromboplastin time (APTT) (R=0.425). There was modest positive correlation between the clotting time (CT) parameter using ROTEM and rivaroxaban level (R=0.328). However, when grouped into low (300ng/ml) rivaroxaban levels, the CTs show no meaningful association and therefore cannot be used as a surrogate marker to predict anticoagulant effect. There is no significant difference between the mean rivaroxaban levels for patients on 15mg rivaroxaban, those on 20mg with creatinine clearance 60ml/min (Analysis of Variance, n=121, F=2.009, P=0.159), suggesting that with dose adjustment a similar anticoagulant effect is achieved in patients with different renal function. Conclusion: Our data suggests that the correlation between rivaroxaban levels and ROTEM CT parameter is not sufficiently strong to reliably predict the anticoagulant effect of rivaroxaban and does not confer any advantage over conventional clotting tests. Disclosures Chowdary: Baxalta: Honoraria, Membership on an entity's Board of Directors or advisory committees; Biogen: Honoraria, Membership on an entity's Board of Directors or advisory committees; CSL Behring: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Sobi: Honoraria; Bayer: Honoraria; Pfizer: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Novo Nordisk: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding. Drebes:Bayer: Consultancy; Bayer: Other: Educational Grant.

Description: Introduction: AAV-mediated gene transfer of blood coagulation Factor IX (FIX) has been established as a safe and long-term treatment for patients suffering from severe hereditary Haemophilia B. A gain-of-function F9 transgene (F9-R338L; Padua) has recently been used to achieve higher functional levels of FIX, effectively eliminating the need for regular prophylaxis. The naturally-occurring R338L Padua mutation is situated in the catalytic domain of FIX on a helical side loop (region 332-339) that is involved in FVIIIa-mediated stimulation of substrate turnover. Here, we examined if a single amino acid substitution of a lysine at position 301 leads to gain of function. This basic residue sits adjacent to the 332-339 loop on an exposed helical segment (292-303) that has been implicated to interact with the FVIIIa A2 domain in the FIXa-FVIIIa tenase complex. Methods: We examined the lysine at position 301 (numbering based on mature polypeptide chain) in more detail by conservative mutation to arginine (K301R) and non-conservative mutation to leucine (K301L). To assess specific FIX activity, F9-K301 variants were transiently expressed in HEK293T cells and tested for antigenic FIX levels and chromogenic activity 48 hours post transfection. To assess specific activity in plasma, AAV-mediated gene transfer (1x1010vg/mouse) of F9-K301 variants in hemophilia B knock-out mice (CL57B6) was carried out. In addition, we investigated whether the F9-K301R mutation enhances specific activity in combination with the F9-R338L Padua mutation via site-specific genome integration. Results: Transient transfection of F9-K301 variants in HEK293T cells showed a 25% increase in specific activity with F9-K301R but a 50% reduction in activity with F9-K301L as compared to wild type F9 (WT-F9). Validation of gain-of-function was done by AAV-mediated gene transfer in hemophilia B knock-out mice. Four weeks post injection, plasma FIX antigen levels were similar in mice transduced with either F9-K301R (0.91±0.3 U/ml; N=3), F9-K301L (0.93±0.0 U/ml; N=2) or WT-F9 (0.94±0.19 U/ml; N=4) constructs. Interestingly, specific chromogenic activity in plasma from F9-K301R mice (2.71±0.66 U/ml) was more than 2-fold higher compared to plasma from mice in the WT-F9 cohort (1.25±0.2 U/ml). On the other hand, specific activity in the F9-K301L cohort (0.37±0.07 U/ml) was reduced compared to wild type F9, consistent with a haemophilic phenotype. Next, we investigated whether the F9-K301R mutation enhances activity in combination with the F9-R338L Padua mutation. To do so, we stably expressed wild type FIX (WT-FIX) and three FIX gain-of-function variants (FIX-K301R, FIX-R338L and FIX-K301R/R338L) in HEK293 cells via site-specific genome integration. Interestingly, higher FIX antigen levels were observed in conditioned media from cells (1.5x106) stably expressing FIX-K301R (0.14±0.01 U/ml) FIX-R338L (0.11±0.01 U/ml) and FIX-K301R/R338L (0.10±0.01 U/ml) relative to cells expressing WT-FIX (0.08±0.01 U/ml). Similar to previous results, specific chromogenic activity was more than 2-fold higher in FIX-K301R (1.25±0.08 U/ml) compared to WT-FIX (0.54±0.06 U/ml). In addition, specific activity was higher in FIX-K301R/R338L (7.71±0.35 U/ml) compared to FIX-R338L (6.69±0.32 U/ml), suggesting molecular synergism between both gain-of-function mutations. Ongoing studies are focused on characterizing these recombinant FIX variants in purified and plasma-based activity assays and unraveling the mechanism(s) leading to increased expression/secretion of these gain-of-function variants. Conclusion: In summary, these results show that the K301R mutation enhances catalytic activity of FIX in vitro and in vivo and synergistically enhances activity in combination with the R338L Padua mutation. As such, this gain-of-function mutation could potentially serve to facilitate higher levels of FIX activity in the plasma of Haemophilia B patients following AAV-mediated gene transfer. Disclosures Verhoef: Freeline: Employment, Equity Ownership. Foley:Freeline: Employment, Equity Ownership. Goodale:Freeline: Employment, Equity Ownership. Macrae:Freeline: Employment, Equity Ownership. McIntosh:BioMarin: Patents & Royalties; Freeline: Consultancy, Equity Ownership. Corbau:Freeline: Employment, Equity Ownership. Nathwani:Freeline: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees.

Description: Abstract 248 We have developed a unique approach for the treatment of hemophilia B (HB) that is currently being tested in the clinic. This open-label Phase I/II clinical trial entails peripheral vein administration of a single dose of our novel self complementary AAV vector encoding a codon-optimised human FIX transgene (scAAV2/8-LP1-hFIXco) into adult subjects with severe HB. Our plan is to evaluate three dose levels, progressing to the intermediate and high doses only in the absence of toxicity in a minimum of two subjects each. Vector is being administered in the absence of immunosuppression. Thus far, two subjects have received peripheral vein infusion at the low dose, each without any side effects. Importantly, there were no adverse reactions during vector infusion and no subsequent evidence of hepatotoxicity. Overall, there were no significant changes in the complete blood count and serum chemistry panel. The longest follow-up is in the first subject, in whom plasma FIX levels increased from a baseline of

Description: We have examined the effect of the O-linked glycan (OLG) structures of VWF on its interaction with the platelet receptor glycoprotein Ibα. The 10 OLGs were mutated individually and as clusters (Clus) on either and both sides of the A1 domain: Clus1 (N-terminal side), Clus2 (C-terminal side), and double cluster (DC), in both full-length-VWF and in a VWF construct spanning D′ to A3 domains. Mutations did not alter VWF secretion by HEK293T cells, multimeric structure, or static collagen binding. The T1255A, Clus1, and DC variants caused increased ristocetin-mediated GPIbα binding to VWF. Platelet translocation rate on OLG mutants was increased because of reduced numbers of GPIbα binding sites but without effect on bond lifetime. In contrast, OLG mutants mediated increased platelet capture on collagen under high shear stress that was associated with increased adhesion of these variants to the collagen under flow. These findings suggest that removal of OLGs increases the flexibility of the hinge linker region between the D3 and A1 domain, facilitating VWF unfolding by shear stress, thereby enhancing its ability to bind collagen and capture platelets. These data demonstrate an important functional role of VWF OLGs under shear stress conditions.

Description: Investigation of 3 families with bleeding symptoms demonstrated a defect in the collagen-binding activity of von Willebrand factor (VWF) in association with a normal VWF multimeric pattern. Genetic analysis showed affected persons to be heterozygous for mutations in the A3 domain of VWF: S1731T, W1745C, and S1783A. One person showed compound heterozygosity for W1745C and R760H. W1745C and S1783A have not been reported previously. The mutations were reproduced by site-directed mutagenesis and mutant VWF expressed in HEK293T cells. Collagen-binding activity measured by immunosorbent assay varied according to collagen type: W1745C and S1783A were associated with a pronounced binding defect to both type I and type III collagen, whereas the principal abnormality in S1731T patients was a reduction in binding to type I collagen only. The multimer pattern and distribution of mutant proteins were indistinguishable from wild-type recombinant VWF, confirming that the defect in collagen binding resulted from the loss of affinity at the binding site and not impairment of high-molecular-weight multimer formation. Our findings demonstrate that mutations causing an abnormality in the binding of VWF to collagen may contribute to clinically significant bleeding symptoms. We propose that isolated collagen-binding defects are classified as a distinct subtype of von Willebrand disease.

Description: Background: Haemophilia A (HA), the most common inherited bleeding disorder, is well suited for gene therapy because a modest increase in the plasma factor VIII (FVIII) levels to ≥1% of normal levels will substantially ameliorate the bleeding diathesis and improve quality of life. Earlier gene transfer strategies for FVIII replacement approaches using plasmid electroporation, retroviral vector, or adenoviral vector failed to achieve persistent phenotypic correction of bleeding. We have recently shown that a single peripheral vein administration of adeno-associated viral (AAV) vectors expressing the FIX transgene results in stable long-term expression of transgenic FIX at therapeutic levels without long term toxicity in patients with severe haemophilia B (ClinicalTrials.gov:NCT00979238). However, the use of AAV vectors for HA gene therapy has been limited by inefficient expression of transgenic FVIII and the large size of the FVIII cDNA. To overcome these obstacles, we developed two AAV-FVIII expression cassettes containing a small synthetic liver specific promoter (HLP) driving the expression of codon optimized FVIII variants. These vectors mediated therapeutic expression of FVIII in murine and non-human primate models (McIntosh et al 2013). The first of these constructs, AAV-HLP-hFVIII-SQ, encoding a B-domain deleted FVIII variant, was recently shown (Rangarajan et al, 2017) to mediate sustained (〉1 year) normalisation of factor VIII activity in six of seven participants following a single intravenous infusion of AAV serotype 5 pseudotyped vector. However, high vector doses (6x1013 vector genomes/kg [vg/kg]) were required for efficacy, possibly because this product was manufactured using the insect cell/baculovirus system. In this report we describe the preliminary results of our on-going Phase I/II clinical trial (GO-8) evaluating the second FVIII cassette (AAV-HLP-hFVIII-V3), which contains a 17 amino-acid peptide comprising six N-linked glycosylation motifs from the human FVIII B-domain that are highly conserved through evolution. In murine studies, AAV-HLP-hFVIII-V3 mediated expression of FVIII at 3-fold higher levels when compared to AAV-HLP-hFVIII-SQ. Methods: The safety and efficacy of a single intravenous infusion of AAV8-HLP-hFVIII-V3, pseudotyped with AAV serotype 8 capsid was assessed in three adult men with severe hemophilia A (FVIII activity levels ≤1% of normal) in the context of an Investigator led, Phase I/II, open-label, non-randomized, dose-escalation trial (ClinicalTrials.gov: NCT03001830GO-8). The first subject received a dose of 6x1011vg/kg and the subsequent two patients each received a dose of 2x1012vg/kg. AAV8-HLP-hFVIII-V3 was manufactured in mammalian HEK 293T cells. The subjects have been followed up for 13-47 weeks after vector administration. Results: Peripheral vein administration of AAV8-HLP-hFVIII-V3 was well tolerated in all patients with no infusion-related reactions. Transgenic FVIII was detectable within two weeks and was more than 5 IU/dl by 6 weeks of gene transfer in all three subjects. Factor VIII activity (one stage clotting assay) levels have remained stable at 7±1IU/dl in patient 1 over a period of 47 weeks. The second participant is 20 weeks following administration of 2x1012 vg/kg of AAV8-HLP-hFVIII-V3 and has steady-state FVIII activity of 6±2IU/dl. In the third subject, who was also treated at a dose of 2x1012 vg/kg, the steady state FVIII activity is almost 10 times higher at 69±7 IU/dl. Elevation of serum alanine aminotransferase was observed in patients 1 and 3 at between weeks 4-6 after gene transfer, reaching peak levels that were 1.5 X upper limit of the normal range. Both patients were treated with corticosteroids within 48 hours of the onset of transaminitis with no loss of transgene expression. No participant has developed a FVIII inhibitor. Conclusion: Our preliminary results from the ongoing Phase I/II study demonstrate FVIII activity levels 〉5% in all three subjects with normalization of FVIII:C levels in one patient. These levels are sufficient to reduce/prevent spontaneous hemorrhage and have been achieved using relatively lower doses of AAV8-HLP-FVIII-V3 than reported previously with a related FVIII expression cassette. No Grade III (CTCAE v4.03) or greater adverse events have been observed over a period of 47 weeks after administration of AAV8-HLP-hFVIII-V3. Disclosures Nathwani: Freeline: Consultancy, Equity Ownership, Membership on an entity's Board of Directors or advisory committees. Tuddenham:Freeline: Consultancy; BioMarin: Consultancy, Patents & Royalties. Chowdary:Biogen: Honoraria, Membership on an entity's Board of Directors or advisory committees; Baxalta (Shire): Honoraria, Membership on an entity's Board of Directors or advisory committees; Swedish Orphan Biovitrum AB (Sobi): Honoraria; Novo Nordisk: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Bayer: Honoraria; CSL Behring: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Pfizer: Honoraria, Membership on an entity's Board of Directors or advisory committees, Research Funding; Freeline: Consultancy. McIntosh:Freeline: Consultancy.

Description: Abstract 3360 Background: Point-of-care testing (POCT) is widely used for monitoring of the international normalized ratio (INR) in patients on oral anticoagulation with a vitamin-K antagonist (VKA) and numerous clinical studies have assessed the accuracy of this method in comparison with INR results from venous blood samples analysed in the laboratory. There is however a paucity of clinical data to support the use of POCT in patients on dual anticoagulation with low molecular weight heparin (LMWH) and a VKA during initiation of anticoagulation or bridging after a surgical procedure. Aim: To test the hypothesis whether therapeutic doses of LMWH interfere with INR measurements when using a POCT system during times of dual anticoagulation with LMWH and a VKA. To further investigate whether the effect is most pronounced once LMWH has reached peak plasma levels and less evident 10 hours and more after administration of LMWH. Methods: We prospectively collected 160 consecutive venous blood samples from patients on therapeutic doses of LMWH - Tinzaparin (175 IU/kg once daily) and a VKA commonly warfarin for INR testing in our laboratory. At the same time all patients had their INR determined on capillary blood collected by finger prick using a CoaguChek XS Pro and INR test strips with the same lot number (Roche Diagnostics Ltd, UK). 60 blood samples were collected within 3–6 hours after administration of LMWH (group 1) and 100 samples were collected 10 hours or more after the last injection of LMWH (group 2). For each sample the dose and time of the last injection of LMWH was recorded along with the time of the venepuncture and the result of the capillary INR. To ensure that we had a wide variation in the plasma concentrations of LMWH we carried out anti-Xa testing on a cross-section of venous samples The dosing advice for Warfarin was based on the INR result of the venous blood sample processed in the laboratory. Results: The correlation coefficient between the POCT INR and the laboratory INR was 0.98 in group 1 and 0.97 in group 2. In the Bland Altman analysis for group 1 the mean 95% confidence interval (CI) was 0.03 (range+/− 1.96 SD: −0.26 to +0.32) and for group 2 the mean 95% CI was 0.00 (range −0.28 to +0.29). These results are comparable to results of our internal quality control between POCT INR and laboratory INR in patients on VKA alone with a mean 95% CI of −0.02 (range −0.26 to +0.29). The mean INR was 1.8 by both methods in group 1 and 1.7 by both methods in group 2 and anti-Xa levels ranged from 0 to1.19 U/mL. A variation in the result of the POCT INR and laboratory INR of 0.5 or greater is thought to affect dosing decisions for Warfarin. Such a variation was observed in 3% (2/60) in group 1 and 2% (2/100) in group 2. Conclusion: There was good accuracy of the INR obtained with the POCT system used and this was not affected by the timing of the administration of LMWH in relation to testing. Disclosures: No relevant conflicts of interest to declare.