Your search keyword '"Preijers, T"' showing total 25 results

1. Desmopressin testing in von Willebrand disease: Lowering the burden

Author

Heijdra, Jessica M., Atiq, Ferdows, Al Arashi, Wala, Kieboom, Quincy, Wuijster, Esmee, Meijer, Karina, Kruip, Marieke J.H.A., Leebeek, Frank W.G., Cnossen, Marjon H., Fijnvandraat, K., Mathôt, R.A.A., Polinder, S., Coppens, M., Tamminga, R.Y.J., Meijer, K., Laros‐van Gorkom, B.A.P., Brons, P., Schols, S.E.M., van der Meer, F.J.M., Eikenboom, H.C.J., Schutgens, R.E.G., Fischer, K., Heubel‐Moenen, F., Nieuwenhuizen, L., Ypma, P., Driessens, M.H.E., Zwaan, C.M., van Vliet, I., Collins, P.W., Liesner, R., Chowdary, P., Keeling, D., Lock, J., Hazendonk, H.C.A.M., van Moort, I., Preijers, T., de Jager, N.C.B., Goedhart, M.C.H.J., Bukkems, L.H., Cloesmeijer, M.E., and Janssen, A.

Published

2022

2. One piece of the puzzle: Population pharmacokinetics of FVIII during perioperative Haemate P®/Humate P® treatment in von Willebrand disease patients

Author

de Jager, Nico C.B., Bukkems, Laura H., Heijdra, Jessica M., Hazendonk, Carolien H.C.A.M., Fijnvandraat, Karin, Meijer, Karina, Eikenboom, Jeroen, Laros - van Gorkom, Britta A.P., Leebeek, Frank W.G., Cnossen, Marjon H., Mathôt, Ron A.A., Collins, P.W., Kruip, M.J.H.A., Polinder, S., Lock, J., van Moort, I., Goedhart, M.C.H.J., Coppens, M., Peters, M., Preijers, T., Brons, P., van der Meer, F.J.M., Schutgens, R.E.G., Fischer, K., Driessens, M.H.E., Zwaan, C.M., van Vliet, I., Liesner, R., Chowdary, P., and Keeling, D.

Published

2020

3. Population pharmacokinetics of factor IX in hemophilia B patients undergoing surgery

Author

Preijers, T., Hazendonk, H.C.A.M., Liesner, R., Chowdary, P., Driessens, M.H.E., Hart, D., Keeling, D., Laros‐van Gorkom, B.A.P., van der Meer, F.J.M., Meijer, K., Fijnvandraat, K., Leebeek, F.W.G., Collins, P.W., Cnossen, M.H., Mathôt, R.A.A., Kruip, M.J.A.H., Polinder, S., Lock, J., van Moort, I., Heijdra, J.M., Nederlof, A., de Jager, N., Coppens, M., Peters, M., Tamminga, R.Y.J., Brons, P., Eikenboom, H.C.J., Schutgens, R.E.G., Fischer, K., Zwaan, C.M., and van Vliet, I.

Published

2018

4. In silico evaluation of limited blood sampling strategies for individualized recombinant factor IX prophylaxis in hemophilia B patients

Author

Preijers, T., Hazendonk, H.C.A.M., Fijnvandraat, K., Leebeek, F.W.G., Cnossen, M.H., and Mathôt, R.A.A.

Published

2017

5. 1184P Improving the tolerability of osimertinib by identifying its toxic limit

Author

Agema, B.C., primary, Veerman, M.G.D., additional, Lanser, D., additional, Steendam, C.M.J., additional, Preijers, T., additional, Van Der Leest, C., additional, Koch, B., additional, Dingemans, A-M.C., additional, Mathijssen, R.H., additional, and Koolen, S.L., additional

Published

2022

6. Perioperatief farmacokinetisch-gestuurd doseren van factor VIII-concentraat bij hemofilie A (OPTI-CLOT-studie): een open-label, gerandomiseerd, gecontroleerd, multicenteronderzoek

Author

Moort, I. van, Preijers, T., Bukkems, L.H., Hazendonk, H.C.A.M., Bom, J.G. van der, Laros-van Gorkom, B.A.P., Schols, S., Beckers, E.A., Nieuwenhuizen, L., Meer, F.J. van der, Ypma, P.F., Coppens, E., Fijnvandraat, K., Schutgens, R.E., Meijer, K, Leebeek, F.W.G., Mathôt, R.A.A., Cnossen, M.H., Moort, I. van, Preijers, T., Bukkems, L.H., Hazendonk, H.C.A.M., Bom, J.G. van der, Laros-van Gorkom, B.A.P., Schols, S., Beckers, E.A., Nieuwenhuizen, L., Meer, F.J. van der, Ypma, P.F., Coppens, E., Fijnvandraat, K., Schutgens, R.E., Meijer, K, Leebeek, F.W.G., Mathôt, R.A.A., and Cnossen, M.H.

Abstract

Item does not contain fulltext

Published

2022

7. In silico evaluation of limited sampling strategies for individualized dosing of extended half-life factor IX concentrates in hemophilia B patients

Author

Preijers, T., van Spengler, M. W.F., Meijer, K., Fijnvandraat, K., Fischer, K., Leebeek, F. W.G., Cnossen, M. H., Mathôt, R. A.A., Preijers, T., van Spengler, M. W.F., Meijer, K., Fijnvandraat, K., Fischer, K., Leebeek, F. W.G., Cnossen, M. H., and Mathôt, R. A.A.

Abstract

Purpose: Hemophilia B is a bleeding disorder, caused by a factor IX (FIX) deficiency. Recently, FIX concentrates with extended half-life (EHL) have become available. Prophylactic dosing of EHL-FIX concentrates can be optimized by assessment of individual pharmacokinetic (PK) parameters. To determine these parameters, limited sampling strategies (LSSs) may be applied. The study aims to establish adequate LSSs for estimating individual PK parameters of EHL-FIX concentrates using in silico evaluation. Methods: Monte Carlo simulations were performed to obtain FIX activity versus time profiles using published population PK models for N9-GP (Refixia), rFIXFc (Alprolix), and rIX-FP (Idelvion). Fourteen LSSs, containing three or four samples taken within 8 days after administration, were formulated. Bayesian analysis was applied to obtain estimates for clearance (CL), half-life (t1/2), time to 1% (Time1%), and calculated weekly dose (Dose1%). Bias and precision of these estimates were assessed to determine which LSS was adequate. Results: For all PK parameters of N9-GP, rFIXFc and rIX-FP bias was generally acceptable (range: −5% to 5%). For N9-GP, precision of all parameters for all LSSs was acceptable (< 25%). For rFIXFc, precision was acceptable for CL and Time1%, except for t1/2 (range: 27.1% to 44.7%) and Dose1% (range: 12% to 29.4%). For rIX-FP, all LSSs showed acceptable bias and precision, except for Dose1% using LSS with the last sample taken on day 3 (LSS 6 and 10). Conclusion: Best performing LSSs were LSS with samples taken at days 1, 5, 7, and 8 (N9-GP and rFIXFc) and at days 1, 4, 6, and 8 (rIX-FP), respectively.

Published

2022

8. In silico evaluation of limited sampling strategies for individualized dosing of extended half-life factor IX concentrates in hemophilia B patients

Author

Poli Van Creveldkliniek Medisch, Child Health, Circulatory Health, Preijers, T, van Spengler, M W F, Meijer, K, Fijnvandraat, K, Fischer, K, Leebeek, F W G, Cnossen, M H, Mathôt, R A A, Poli Van Creveldkliniek Medisch, Child Health, Circulatory Health, Preijers, T, van Spengler, M W F, Meijer, K, Fijnvandraat, K, Fischer, K, Leebeek, F W G, Cnossen, M H, and Mathôt, R A A

Published

2022

9. Dosing of factor VIII concentrate by ideal body weight is more accurate in overweight and obese haemophilia A patients

Author

Moort, I. van, Preijers, T., Hazendonk, H., Schutgens, R.E., Laros-van Gorkom, B.A.P., Nieuwenhuizen, L., Meer, F.J. van der, Fijnvandraat, K., Leebeek, F.W.G., Meijer, K, Mathôt, R.A.A., Cnossen, M.H., Moort, I. van, Preijers, T., Hazendonk, H., Schutgens, R.E., Laros-van Gorkom, B.A.P., Nieuwenhuizen, L., Meer, F.J. van der, Fijnvandraat, K., Leebeek, F.W.G., Meijer, K, Mathôt, R.A.A., and Cnossen, M.H.

Abstract

Contains fulltext : 245042.pdf (Publisher’s version ) (Open Access), AIMS: Under- and, especially, overdosing of replacement therapy in haemophilia A patients may be prevented by application of other morphometric variables than body weight (BW) to dose factor VIII (FVIII) concentrates. Therefore, we aimed to investigate which morphometric variables best describe interindividual variability (IIV) of FVIII concentrate pharmacokinetic (PK) parameters. METHODS: PK profiling was performed by measuring 3 FVIII levels after a standardized dose of 50 IU kg(-1) FVIII concentrate. A population PK model was constructed, in which IIV for clearance (CL) and central volume of distribution (V1) was quantified. Relationships between CL, V1 and 5 morphometric variables (BW, ideal BW [IBW], lean BW, adjusted BW, and body mass index [BMI]) were evaluated in normal weight (BMI < 25 kg m(-2) ), overweight (BMI 25-30 kg m(-2) ) and obese haemophilia A patients (BMI > 30 kg m(-2) ). RESULTS: In total, 57 haemophilia A patients (FVIII≤0.05 IU mL(-1) ) were included with median BW of 83 kg (range: 53-133) and median age of 48 years (range: 18-77). IBW best explained observed variability between patients, as IIV for CL and V1 was reduced from 45.1 to 37.6 and 26.% to 14.1%, respectively. CL, V1 and half-life were similar for all BMI categories. The national recommended dosing schedule did not result in adequate trough levels, both in case of dosing based on BW and IBW. However, dosing based on IBW prevented unnecessary high FVIII peaks. CONCLUSION: IBW is the most suitable morphometric variable to explain interindividual FVIII PK variability and is more appropriate to dose overweight and obese patients.

Published

2021

10. Validation of a perioperative population factor VIII pharmacokinetic model with a large cohort of pediatric hemophilia a patients

Author

Preijers, T., Liesner, R., Hazendonk, H., Chowdary, P., Driessens, M.H.E., Hart, D.P., Laros-van Gorkom, B.A.P., Meer, F.J. van der, Meijer, K, Fijnvandraat, K., Leebeek, F.W.G., Mathôt, R.A.A., Cnossen, M.H., Preijers, T., Liesner, R., Hazendonk, H., Chowdary, P., Driessens, M.H.E., Hart, D.P., Laros-van Gorkom, B.A.P., Meer, F.J. van der, Meijer, K, Fijnvandraat, K., Leebeek, F.W.G., Mathôt, R.A.A., and Cnossen, M.H.

Abstract

Contains fulltext : 244121.pdf (Publisher’s version ) (Open Access), AIMS: Population pharmacokinetic (PK) models are increasingly applied to perform individualized dosing of factor VIII (FVIII) concentrates in haemophilia A patients. To guarantee accurate performance of a population PK model in dose individualization, validation studies are of importance. However, external validation of population PK models requires independent data sets and is, therefore, seldomly performed. Therefore, this study aimed to validate a previously published population PK model for FVIII concentrates administrated perioperatively. METHODS: A previously published population PK model for FVIII concentrate during surgery was validated using independent data from 87 children with severe haemophilia A with a median (range) age of 2.6 years (0.03-15.2) and body weight of 14 kg (4-57). First, the predictive performance of the previous model was evaluated with MAP Bayesian analysis using NONMEM v7.4. Subsequently, the model parameters were (re)estimated using a combined dataset consisting of the previous modelling data and the data available for the external validation. RESULTS: The previous model underpredicted the measured FVIII levels with a median of 0.17 IU mL(-1) . Combining the new, independent and original data, a dataset comprising 206 patients with a mean age of 7.8 years (0.03-77.6) and body weight of 30 kg (4-111) was obtained. Population PK modelling provided estimates for CL, V1, V2, and Q: 171 mL h(-1) 68 kg(-1) , 2930 mL 68 kg(-1) , 1810 mL 68 kg(-1) , and 172 mL h(-1) 68 kg(-1) , respectively. This model adequately described all collected FVIII levels, with a slight median overprediction of 0.02 IU mL(-1) . CONCLUSIONS: This study emphasizes the importance of external validation of population PK models using real-life data.

Published

2021

11. Perioperative pharmacokinetic-guided factor VIII concentrate dosing in haemophilia (OPTI-CLOT trial): an open-label, multicentre, randomised, controlled trial

Author

Moort, I. van, Preijers, T., Bukkems, L.H., Hazendonk, H., Bom, J.G. van der, Laros-van Gorkom, B.A.P., Beckers, E.A., Nieuwenhuizen, L., Meer, F.J. van der, Ypma, P., Coppens, M., Fijnvandraat, K., Schutgens, R.E., Meijer, K, Leebeek, F.W.G., Brons, P.P., Schols, S.E.M., Mathôt, R.A.A., Cnossen, M.H., Moort, I. van, Preijers, T., Bukkems, L.H., Hazendonk, H., Bom, J.G. van der, Laros-van Gorkom, B.A.P., Beckers, E.A., Nieuwenhuizen, L., Meer, F.J. van der, Ypma, P., Coppens, M., Fijnvandraat, K., Schutgens, R.E., Meijer, K, Leebeek, F.W.G., Brons, P.P., Schols, S.E.M., Mathôt, R.A.A., and Cnossen, M.H.

Abstract

Item does not contain fulltext, BACKGROUND: Dosing of replacement therapy with factor VIII concentrate in patients with haemophilia A in the perioperative setting is challenging. Underdosing and overdosing of factor VIII concentrate should be avoided to minimise risk of perioperative bleeding and treatment costs. We hypothesised that dosing of factor VIII concentrate on the basis of a patient's pharmacokinetic profile instead of bodyweight, which is standard treatment, would reduce factor VIII consumption and improve the accuracy of attained factor VIII levels. METHODS: In this open-label, multicentre, randomised, controlled trial (OPTI-CLOT), patients were recruited from nine centres in Rotterdam, Groningen, Utrecht, Nijmegen, The Hague, Leiden, Amsterdam, Eindhoven, and Maastricht in The Netherlands. Eligible patients were aged 12 years or older with severe or moderate haemophilia A (severe haemophilia was defined as factor VIII concentrations of <0·01 IU/mL, and moderate haemophilia as 0·01-0·05 IU/mL), without factor VIII inhibitors, and planned for elective low or medium risk surgery as defined by surgical risk score. Patients were randomly assigned (1:1) using a web-based randomisation system and treatment minimisation, stratified by method of administration of factor VIII concentrate (continuous infusion vs bolus administration) and risk level of surgery (low and medium risk surgery), to the pharmacokinetic-guided or standard treatment group. The primary endpoint was total amount of infused factor VIII concentrate (IU per kg bodyweight) during perioperative period (from day of surgery up to 14 days after surgery). Analysis was by intention to treat and the safety analysis population comprised all participants who underwent surgery with factor VIII concentrate. This study is registered with the Netherlands Trial Registry, NL3955, and is now closed to accrual. FINDINGS: Between May 1, 2014, and March 1, 2020, 98 patients were assessed for eligibility and 66 were enrolled in the trial and rand

Published

2021

12. In silico comparison of pharmacokinetic properties of three extended half-life factor IX concentrates

Author

Preijers, T., Bukkems, L. (Laura), van Spengler, M. (Max), Leebeek, F.W.G. (Frank), Cnossen, M.H. (Marjon), Mathot, R.A. (Ron), Preijers, T., Bukkems, L. (Laura), van Spengler, M. (Max), Leebeek, F.W.G. (Frank), Cnossen, M.H. (Marjon), and Mathot, R.A. (Ron)

Abstract

Purpose: Pharmacokinetic (PK) differences between the extended half-life (EHL) factor IX (FIX) concentrates for hemophilia B exist, which may influence hemostatic efficacy of replacement therapy in patients. Therefore, we aimed to evaluate the PK properties of three EHL-FIX concentrates and compare them to a standard half-life (SHL) recombinant FIX (rFIX) concentrate. Methods: Activity-time profiles of PEGylated FIX (N9-GP), FIX linked with human albumin (rIX-FP), FIX coupled to human IgG1 Fc-domain (rFIXFc), and SHL rFIX were simulated for 10,000 patients during steady-state dosing of 40 IU/kg once weekly (EHL-FIX) and biweekly (rFIX) using published concentrate specific population PK models. Results: Half-lives were respectively 80, 104, and 82 h for N9-GP, rIX-FP, and rFIXFc versus 22 h for rFIX. Between the EHL concentrates, exposure was different with area under the curve (AUC) values of 78.5, 49.6, and 12.1 IU/h/mL and time above FIX target values of 0.10 IU/mL of 168, 168, and 36 h for N9-GP, rIX-FP, and rFIXFc, respectively. N9-GP produced the highest median in vivo recovery value (1.70 IU/dL per IU/kg) compared with 1.18, 1.00, and 1.05 IU/dL per IU/kg for rIX-FP, rFIXFc, and rFIX, respectively. Conclusions: When comparing EHL products, not only half-life but also exposure must be considered. In addition, variation in extravascular distribution of the FIX concentrates must be taken into account. This study provides insight into the different PK properties of these concentrates and may aid in determination of dosing regimens of EHL-FIX concentrates in real-life.

Published

2021

13. Dosing of factor VIII concentrate by ideal body weight is more accurate in overweight and obese haemophilia A patients

Author

Moort, I. (Iris) van, Preijers, T., Hazendonk, H.C.A.M. (Carolien), Schutgens, R. (Roger), Laros-Van Gorkom, B.A.P. (Britta), Nieuwenhuizen, L. (Laurens), Meer, F.J.M. (Felix) van der, Fijnvandraat, K., Leebeek, F.W.G. (Frank), Meijer, K. (Karina), Mathot, R.A. (Ron), Cnossen, M.H. (Marjon), Moort, I. (Iris) van, Preijers, T., Hazendonk, H.C.A.M. (Carolien), Schutgens, R. (Roger), Laros-Van Gorkom, B.A.P. (Britta), Nieuwenhuizen, L. (Laurens), Meer, F.J.M. (Felix) van der, Fijnvandraat, K., Leebeek, F.W.G. (Frank), Meijer, K. (Karina), Mathot, R.A. (Ron), and Cnossen, M.H. (Marjon)

Abstract

Aims: Under- and, especially, overdosing of replacement therapy in haemophilia A patients may be prevented by application of other morphometric variables than body weight (BW) to dose factor VIII (FVIII) concentrates. Therefore, we aimed to investigate which morphometric variables best describe interindividual variability (IIV) of FVIII concentrate pharmacokinetic (PK) parameters. Methods: PK profiling was performed by measuring 3 FVIII levels after a standardized dose of 50 IU kg−1 FVIII concentrate. A populati

Published

2020

14. Pharmacokinetic-guided dosing of factor VIII concentrate in a morbidly obese severe haemophilia A patient undergoing orthopaedic surgery

Author

Preijers, T., Laros-van Gorkom, B.A.P., Mathot, R.A.A., Cnossen, M.H., Preijers, T., Laros-van Gorkom, B.A.P., Mathot, R.A.A., and Cnossen, M.H.

Abstract

Item does not contain fulltext, A 58-year-old morbidly obese male (body mass index: 38 kg/m(2)) with severe haemophilia A underwent total knee replacement surgery. Perioperatively, factor VIII (FVIII) levels were measured daily and maximum a posteriori (MAP) Bayesian estimation was used to calculate the individual pharmacokinetic (PK) parameters and doses required to obtain prescribed FVIII target levels. In the MAP Bayesian procedure, a population PK model was used in which PK parameters were normalised using body weight. In this specific case, ideal body weight was used to scale the PK parameters instead of actual body weight. Except for the preoperative FVIII level, adequate FVIII levels were achieved during the 10-day perioperative period. During follow-up visits, the knee prosthesis was reported to function adequately.

Published

2019

15. One piece of the puzzle: Population pharmacokinetics of FVIII during perioperative Haemate P®/Humate P® treatment in von Willebrand disease patients

Author

de Jager, N.C.B. (Nico C. B.), Bukkems, L.H. (Laura H.), Heijdra, J.M. (Jessica), Hazendonk, C.H.C.A.M. (Carolien H. C. A. M.), Fijnvandraat, K., Meijer, K. (Karina), Eikenboom, J.C.J. (Jeroen), Laros-Van Gorkom, B.A.P. (Britta), Leebeek, F.W.G. (Frank), Cnossen, M.H. (Marjon), Mathot, R.A. (Ron), Collins, P.W., Kruip, M.J.H.A. (Marieke), Polinder, S. (Suzanne), Lock, J. (J.), Moort, I. (Iris) van, Goedhart, M.C.H.J. (M. C.H.J.), Coppens, M., Peters, M.A.D. (Marjolein), Preijers, T., Brons, P.P., Meer, F.J.M. (Felix) van der, Schutgens, R. (Roger), Fischer, K. (Kathelijn), Driessens, M.H.E. (M. H.E.), Zwaan, C.M. (Michel), van Vliet, I. (I.), Liesner, R. (Ri), Chowdary, P. (P.), Keeling, D. (D.), de Jager, N.C.B. (Nico C. B.), Bukkems, L.H. (Laura H.), Heijdra, J.M. (Jessica), Hazendonk, C.H.C.A.M. (Carolien H. C. A. M.), Fijnvandraat, K., Meijer, K. (Karina), Eikenboom, J.C.J. (Jeroen), Laros-Van Gorkom, B.A.P. (Britta), Leebeek, F.W.G. (Frank), Cnossen, M.H. (Marjon), Mathot, R.A. (Ron), Collins, P.W., Kruip, M.J.H.A. (Marieke), Polinder, S. (Suzanne), Lock, J. (J.), Moort, I. (Iris) van, Goedhart, M.C.H.J. (M. C.H.J.), Coppens, M., Peters, M.A.D. (Marjolein), Preijers, T., Brons, P.P., Meer, F.J.M. (Felix) van der, Schutgens, R. (Roger), Fischer, K. (Kathelijn), Driessens, M.H.E. (M. H.E.), Zwaan, C.M. (Michel), van Vliet, I. (I.), Liesner, R. (Ri), Chowdary, P. (P.), and Keeling, D. (D.)

Abstract

Introduction: Many patients with von Willebrand disease (VWD) are treated on demand with von Willebrand factor and factor VIII (FVIII) containing concentrates present with VWF and/or FVIII plasma levels outside set target levels. This carries a risk for bleeding and potentially for thrombosis. Development of a population pharmacokinetic (PK) model based on FVIII levels is a first step to more accurate on-demand perioperative dosing of this concentrate.

Published

2019

16. Perioperative replacement therapy in haemophilia B: An appeal to 'B' more precise

Author

Hazendonk, H.C.A.M., Preijers, T., Liesner, R., Chowdary, P., Hart, D., Keeling, D., Driessens, M.H.E., Laros-van Gorkom, B.A.P., Meer, F.J.M. van der, Meijer, K., Fijnvandraat, K., Leebeek, F.W.G., Mathot, R.A.A., Collins, P.W., Cnossen, M.H., OPTI-CLOT Study Grp, AGEM - Digestive immunity, AGEM - Endocrinology, metabolism and nutrition, Graduate School, Amsterdam Reproduction & Development (AR&D), ACS - Pulmonary hypertension & thrombosis, Paediatric Infectious Diseases / Rheumatology / Immunology, Pharmacy, Pediatrics, Hematology, and Real World Studies in PharmacoEpidemiology, -Genetics, -Economics and -Therapy (PEGET)

Subjects

Male, PHARMACOKINETICS, SURGERY, Vascular damage Radboud Institute for Health Sciences [Radboudumc 16], 030204 cardiovascular system & hematology, PROPHYLAXIS, Factor IX, 0302 clinical medicine, individualized treatment, perioperative replacement therapy, Child, Genetics (clinical), RISK, Perioperative management, FACTOR-VIII, A PATIENTS, Hematology, General Medicine, Middle Aged, Treatment characteristics, Child, Preschool, Female, Median body, Adult, medicine.medical_specialty, Red Blood Cell Transfusion, Hemorrhage, haemophilia B, Hemophilia B, PATIENT, Young Adult, 03 medical and health sciences, All institutes and research themes of the Radboud University Medical Center, AGE, medicine, Humans, Haemophilia B, Dosing, clotting factor concentrates, Perioperative Period, Retrospective Studies, business.industry, Thrombosis, Perioperative, Surgical procedures, medicine.disease, Surgery, surgical procedures, haemostasis, business, RECOMBINANT FACTOR-IX, 030215 immunology

Abstract

Introduction\ud \ud Haemophilia B is caused by a deficiency of coagulation factor IX (FIX) and characterized by bleeding in muscles and joints. In the perioperative setting, patients are treated with FIX replacement therapy to secure haemostasis. Targeting of specified FIX levels is challenging and requires frequent monitoring and adjustment of therapy. \ud \ud \ud Aim\ud \ud To evaluate perioperative management in haemophilia B, including monitoring of FIX infusions and observed FIX levels, whereby predictors of low and high FIX levels were assessed.\ud \ud \ud Methods\ud \ud In this international multicentre study, haemophilia B patients with FIX < 0.05 IU mL−1 undergoing elective, minor or major surgical procedures between 2000 and 2015 were included. Data were collected on patient, surgical and treatment characteristics. Observed FIX levels were compared to target levels as recommended by guidelines. \ud \ud \ud Results\ud \ud A total of 255 surgical procedures were performed in 118 patients (median age 40 years, median body weight 79 kg). Sixty percent of FIX levels within 24 hours of surgery were below target with a median difference of 0.22 IU mL−1 [IQR 0.12‐0.36]; while >6 days after surgery, 59% of FIX levels were above target with a median difference of 0.19 IU mL−1 [IQR 0.10‐0.39]. Clinically relevant bleeding complications (necessity of a second surgical intervention or red blood cell transfusion) occurred in 7 procedures (2.7%). \ud \ud \ud Conclusion\ud \ud This study demonstrates that targeting of FIX levels in the perioperative setting is complex and suboptimal, but although this bleeding is minimal. Alternative dosing strategies taking patient and surgical characteristics as well as pharmacokinetic principles into account may help to optimize and individualize treatment.

Published

2018

17. Population pharmacokinetics of factor IX in hemophilia B patients undergoing surgery

Author

Poli Van Creveldkliniek Medisch, Circulatory Health, Child Health, Preijers, T., Hazendonk, H. C.A.M., Liesner, R., Chowdary, P., Driessens, M. H.E., Hart, D., Keeling, D., Laros-van Gorkom, B. A.P., van der Meer, F. J.M., Meijer, K., Fijnvandraat, K., Leebeek, F. W.G., Collins, P. W., Cnossen, M. H., Mathôt, R. A.A., the OPTI-CLOT study group, Poli Van Creveldkliniek Medisch, Circulatory Health, Child Health, Preijers, T., Hazendonk, H. C.A.M., Liesner, R., Chowdary, P., Driessens, M. H.E., Hart, D., Keeling, D., Laros-van Gorkom, B. A.P., van der Meer, F. J.M., Meijer, K., Fijnvandraat, K., Leebeek, F. W.G., Collins, P. W., Cnossen, M. H., Mathôt, R. A.A., and the OPTI-CLOT study group

Published

2018

18. Population pharmacokinetics of factor IX in hemophilia B patients undergoing surgery

Author

Preijers, T, Hazendonk, H, Liesner, R, Chowdary, P, Driessens, MHE, Hart, D, Keeling, D, Laros-Van Gorkom, BAP, Meer, F, Meijer, K, Fijnvandraat, K, Leebeek, Frank, Collins, PW, Cnossen, Marjon, Mathot, RAA, Polinder, Suzanne, van Moort, Iris, Preijers, T, Hazendonk, H, Liesner, R, Chowdary, P, Driessens, MHE, Hart, D, Keeling, D, Laros-Van Gorkom, BAP, Meer, F, Meijer, K, Fijnvandraat, K, Leebeek, Frank, Collins, PW, Cnossen, Marjon, Mathot, RAA, Polinder, Suzanne, and van Moort, Iris

Published

2018

19. Fifteen years of external quality assessment in leukemia/lymphoma immunophenotyping in the Netherlands and Belgium: A way forward

Author

Preijers, F.W.M.B., Velden, V.H. van der, Preijers, T., Brooimans, R.A., Marijt, E., Homburg, C., Montfort, K. van, Gratama, J.W., Preijers, F.W.M.B., Velden, V.H. van der, Preijers, T., Brooimans, R.A., Marijt, E., Homburg, C., Montfort, K. van, and Gratama, J.W.

Abstract

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Published

2016

20. In silicoevaluation of limited blood sampling strategies for individualized recombinant factor IX prophylaxis in hemophilia B patients

Author

Preijers, T., Hazendonk, H.C.A.M., Fijnvandraat, K., Leebeek, F.W.G., Cnossen, M.H., and Mathôt, R.A.A.

Abstract

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Published

2017

21. Population pharmacokinetics of nadroparin for thromboprophylaxis in COVID-19 intensive care unit patients.

Author

Romano LGR, Hunfeld NGM, Kruip MJHA, Endeman H, and Preijers T

Subjects

Humans, Nadroparin pharmacokinetics, Anticoagulants, Intensive Care Units, Inflammation, Critical Illness, Anti-Bacterial Agents, Venous Thromboembolism prevention & control, COVID-19

Abstract

Aims: Nadroparin is administered to COVID-19 intensive care unit (ICU) patients as thromboprophylaxis. Despite existing population pharmacokinetic (PK) models for nadroparin in literature, the population PK of nadroparin in COVID-19 ICU patients is unknown. Moreover, optimal dosing regimens achieving anti-Xa target levels (0.3-0.7 IU/mL) are unknown. Therefore, a population PK analysis was conducted to investigate different dosing regimens of nadroparin in COVID-19 ICU patients., Methods: Anti-Xa levels (n = 280) from COVID-19 ICU patients (n = 65) receiving twice daily (BID) 5700 IU of subcutaneous nadroparin were collected to perform a population PK analysis with NONMEM v7.4.1. Using Monte Carlo simulations (n = 1000), predefined dosing regimens were evaluated., Results: A 1-compartment model with an absorption compartment adequately described the measured anti-Xa levels with interindividual variability estimated for clearance (CL). Inflammation parameters C-reactive protein, D-dimer and estimated glomerular filtration rate based on the Chronic Kidney Disease Epidemiology Collaboration equation allowed to explain the interindividual variability of CL. Moreover, CL was decreased in patients receiving corticosteroids (22.5%) and vasopressors (25.1%). Monte Carlo simulations demonstrated that 5700 IU BID was the most optimal dosing regimen of the simulated regimens for achieving prespecified steady-state t = 4 h anti-Xa levels with 56.7% on target (0.3-0.7 IU/mL)., Conclusion: In our study, clearance of nadroparin is associated with an increase in inflammation parameters, use of corticosteroids, vasopression and renal clearance in critically ill patients. Furthermore, of the simulated regimens, targeted anti-Xa levels were most adequately achieved with a dosing regimen of 5700 IU BID. Future studies are needed to elucidate the underlying mechanisms of found covariate relationships., (© 2022 The Authors. British Journal of Clinical Pharmacology published by John Wiley & Sons Ltd on behalf of British Pharmacological Society.)

Published

2023

22. Improving the tolerability of osimertinib by identifying its toxic limit.

Author

Agema BC, Veerman GDM, Steendam CMJ, Lanser DAC, Preijers T, van der Leest C, Koch BCP, Dingemans AC, Mathijssen RHJ, and Koolen SLW

Abstract

Background: Osimertinib is the cornerstone in the treatment of epidermal growth factor receptor-mutated non-small cell lung cancer (NSCLC). Nonetheless, ±25% of patients experience severe treatment-related toxicities. Currently, it is impossible to identify patients at risk of severe toxicity beforehand. Therefore, we aimed to study the relationship between osimertinib exposure and severe toxicity and to identify a safe toxic limit for a preventive dose reduction., Methods: In this real-life prospective cohort study, patients with NSCLC treated with osimertinib were followed for severe toxicity (grade ⩾3 toxicity, dose reduction or discontinuation, hospital admission, or treatment termination). Blood for pharmacokinetic analyses was withdrawn during every out-patient visit. Primary endpoint was the correlation between osimertinib clearance (exposure) and severe toxicity. Secondary endpoint was the exposure-efficacy relationship, defined as progression-free survival (PFS) and overall survival (OS)., Results: In total, 819 samples from 159 patients were included in the analysis. Multivariate competing risk analysis showed osimertinib clearance ( c.q. exposure) to be significantly correlated with severe toxicity (hazard ratio 0.93, 95% CI: 0.88-0.99). An relative operating characteristic curve showed the optimal toxic limit to be 259 ng/mL osimertinib. A 50% dose reduction in the high-exposure group, that is 25.8% of the total cohort, would reduce the risk of severe toxicity by 53%. Osimertinib exposure was not associated with PFS nor OS., Conclusion: Osimertinib exposure is highly correlated with the occurrence of severe toxicity. To optimize tolerability, patients above the toxic limit concentration of 259 ng/mL could benefit from a preventive dose reduction, without fear for diminished effectiveness., Competing Interests: Conflict of interest statement: The authors declare that there is no conflict of interest., (© The Author(s), 2022.)

Published

2022

23. Validation of a perioperative population factor VIII pharmacokinetic model with a large cohort of pediatric hemophilia a patients.

Author

Preijers T, Liesner R, Hazendonk HCAM, Chowdary P, Driessens MHE, Hart DP, Laros-van Gorkom BAP, van der Meer FJM, Meijer K, Fijnvandraat K, Leebeek FWG, Mathôt RAA, and Cnossen MH

Subjects

Bayes Theorem, Body Weight, Child, Child, Preschool, Cohort Studies, Factor VIII, Humans, Hemophilia A drug therapy

Abstract

Aims: Population pharmacokinetic (PK) models are increasingly applied to perform individualized dosing of factor VIII (FVIII) concentrates in haemophilia A patients. To guarantee accurate performance of a population PK model in dose individualization, validation studies are of importance. However, external validation of population PK models requires independent data sets and is, therefore, seldomly performed. Therefore, this study aimed to validate a previously published population PK model for FVIII concentrates administrated perioperatively., Methods: A previously published population PK model for FVIII concentrate during surgery was validated using independent data from 87 children with severe haemophilia A with a median (range) age of 2.6 years (0.03-15.2) and body weight of 14 kg (4-57). First, the predictive performance of the previous model was evaluated with MAP Bayesian analysis using NONMEM v7.4. Subsequently, the model parameters were (re)estimated using a combined dataset consisting of the previous modelling data and the data available for the external validation., Results: The previous model underpredicted the measured FVIII levels with a median of 0.17 IU mL -1 . Combining the new, independent and original data, a dataset comprising 206 patients with a mean age of 7.8 years (0.03-77.6) and body weight of 30 kg (4-111) was obtained. Population PK modelling provided estimates for CL, V1, V2, and Q: 171 mL h -1  68 kg -1 , 2930 mL 68 kg -1 , 1810 mL 68 kg -1 , and 172 mL h -1  68 kg -1 , respectively. This model adequately described all collected FVIII levels, with a slight median overprediction of 0.02 IU mL -1 ., Conclusions: This study emphasizes the importance of external validation of population PK models using real-life data., (© 2021 The Authors. British Journal of Clinical Pharmacology published by John Wiley & Sons Ltd on behalf of British Pharmacological Society.)

Published

2021

24. Dosing of factor VIII concentrate by ideal body weight is more accurate in overweight and obese haemophilia A patients.

Author

van Moort I, Preijers T, Hazendonk HCAM, Schutgens REG, Laros-van Gorkom BAP, Nieuwenhuizen L, van der Meer FJM, Fijnvandraat K, Leebeek FWG, Meijer K, Mathôt RAA, and Cnossen MH

Subjects

Adolescent, Adult, Aged, Humans, Ideal Body Weight, Middle Aged, Obesity drug therapy, Overweight drug therapy, Young Adult, Factor VIII, Hemophilia A drug therapy

Abstract

Aims: Under- and, especially, overdosing of replacement therapy in haemophilia A patients may be prevented by application of other morphometric variables than body weight (BW) to dose factor VIII (FVIII) concentrates. Therefore, we aimed to investigate which morphometric variables best describe interindividual variability (IIV) of FVIII concentrate pharmacokinetic (PK) parameters., Methods: PK profiling was performed by measuring 3 FVIII levels after a standardized dose of 50 IU kg -1 FVIII concentrate. A population PK model was constructed, in which IIV for clearance (CL) and central volume of distribution (V1) was quantified. Relationships between CL, V1 and 5 morphometric variables (BW, ideal BW [IBW], lean BW, adjusted BW, and body mass index [BMI]) were evaluated in normal weight (BMI < 25 kg m -2 ), overweight (BMI 25-30 kg m -2 ) and obese haemophilia A patients (BMI > 30 kg m -2 )., Results: In total, 57 haemophilia A patients (FVIII≤0.05 IU mL -1 ) were included with median BW of 83 kg (range: 53-133) and median age of 48 years (range: 18-77). IBW best explained observed variability between patients, as IIV for CL and V1 was reduced from 45.1 to 37.6 and 26.% to 14.1%, respectively. CL, V1 and half-life were similar for all BMI categories. The national recommended dosing schedule did not result in adequate trough levels, both in case of dosing based on BW and IBW. However, dosing based on IBW prevented unnecessary high FVIII peaks., Conclusion: IBW is the most suitable morphometric variable to explain interindividual FVIII PK variability and is more appropriate to dose overweight and obese patients., (© 2020 The Authors. British Journal of Clinical Pharmacology published by John Wiley & Sons Ltd on behalf of British Pharmacological Society.)

Published

2021

25. Pharmacokinetic-guided dosing of factor VIII concentrate in a morbidly obese severe haemophilia A patient undergoing orthopaedic surgery.

Author

Preijers T, Laros-vanGorkom BA, Mathôt RA, and Cnossen MH

Subjects

Aftercare, Arthroplasty, Replacement, Knee methods, Coagulants pharmacokinetics, Factor VIII therapeutic use, Hemophilia A prevention & control, Humans, Knee Prosthesis standards, Male, Middle Aged, Obesity, Morbid epidemiology, Orthopedic Procedures, Perioperative Period, Treatment Outcome, Arthroplasty, Replacement, Knee instrumentation, Factor VIII pharmacokinetics, Hemophilia A drug therapy

Abstract

A 58-year-old morbidly obese male (body mass index: 38 kg/m 2 ) with severe haemophilia A underwent total knee replacement surgery. Perioperatively, factor VIII (FVIII) levels were measured daily and maximum a posteriori (MAP) Bayesian estimation was used to calculate the individual pharmacokinetic (PK) parameters and doses required to obtain prescribed FVIII target levels. In the MAP Bayesian procedure, a population PK model was used in which PK parameters were normalised using body weight. In this specific case, ideal body weight was used to scale the PK parameters instead of actual body weight. Except for the preoperative FVIII level, adequate FVIII levels were achieved during the 10-day perioperative period. During follow-up visits, the knee prosthesis was reported to function adequately., Competing Interests: Competing interests: BLvG has received unrestricted educational grants from Baxter and CSL Behring. MHC has received unrestricted research grants for investigator-initiated studies and educational as well as travel grants from Pfizer, Shire, Bayer, Novo Nordisk, CSL Behring, Novartis and Roche. RAAM has received travel grants from Shire and Bayer. The remaining authors declare no competing financial interests., (© BMJ Publishing Group Limited 2019. No commercial re-use. See rights and permissions. Published by BMJ.)

Published

2019