Purpose The development and implementation of a pharmacist-managed Clinical Pharmacogenetics service is described. Summary Therapeutic drug monitoring (TDM) is a well-accepted role of the pharmacist. Pharmacogenetics, the study of genetic factors that influence the variability in drug response among patients, is a rapidly evolving discipline that integrates knowledge of pharmacokinetics and pharmacodynamics with modern advances in genetic testing. There is growing evidence for the clinical utility of pharmacogenetics, and pharmacists can play an essential role in the thoughtful application of pharmacogenetics to patient care. A pharmacist-managed Clinical Pharmacogenetics service was designed and implemented. The goal of the service is to provide clinical pharmacogenetic testing for gene products important to the pharmacodynamics of medications used in our patients. The service is modeled after and integrated with an already established Clinical Pharmacokinetics service. All clinical pharmacogenetic test results are first reported to one of the pharmacists, who reviews the result and provides a written consult. The consult includes an interpretation of the result and recommendations for any indicated changes to therapy. In 2009, 136 clinical pharmacogenetic tests were performed, consisting of 66 TPMT tests, 65 CYP2D6 tests, and 5 UGT1A1 tests. Our service has been met with positive clinician feedback. Conclusion Our experience demonstrates the feasibility of the design and function of a pharmacist-managed Clinical Pharmacogenetics service at an academic specialty hospital. The successful implementation of this service highlights the leadership role that pharmacists can take in moving pharmacogenetics from research to patient care, thereby potentially improving patient outcomes.
Background High-dose methotrexate (HDMTX)-induced acute kidney injury is a rare but life-threatening complication. The methotrexate rescue agent glucarpidase rapidly hydrolyzes methotrexate to inactive metabolites. We retrospectively reviewed glucarpidase use in pediatric cancer patients at our institution and evaluated whether subsequent resumption of HDMTX was tolerated. Methods Clinical data and outcomes of all patients who received glucarpidase after HDMTX administration were reviewed. Results Of 1,141 patients treated with 4,909 courses of HDMTX, 20 patients (1.8% of patients, 0.4% of courses) received 22 doses of glucarpidase. The median glucarpidase dosage was 51.6 units/kg (range, 13 – 65.6 units/kg). At the time of administration, the median plasma methotrexate concentration was 29.1 µM (range, 1.3 – 590.6 µM). Thirteen of the 20 patients received a total of 39 courses of HDMTX therapy after glucarpidase. The median time to complete methotrexate excretion was 355 hours (range, 244 – 763 hours) for the HDMTX course during which glucarpidase was administered, 90 hours (range, 66 – 268 hours) for the next HDMTX course, and 72 hours (range, 42 – 116 hours) for subsequent courses. The median peak serum creatinine during these HDMTX courses was 2.2 mg/dL (range, 0.8 – 9.6 mg/dL), 0.8 mg/dL (range, 0.4 – 1.6 mg/dL), and 0.6 mg/dL (range, 0.4 – 0.9 mg/dL), respectively. One patient experienced nephrotoxicity upon rechallenge with HDMTX. Renal function eventually returned to baseline in all patients and no patient died as a result of methotrexate toxicity. Conclusion It is possible to safely resume HDMTX therapy after glucarpidase treatment for HDMTX-induced acute kidney injury.
PURPOSE Pegaspargase (PEG-ASP) has largely replaced native Escherichia coli asparaginase (L-ASP) in the treatment of acute lymphoblastic leukemia because of its longer half-life and lower immunogenicity. Risk factors for allergic reactions to PEG-ASP remain unclear. Here, we identify risk factors for reactions in a front-line acute lymphoblastic leukemia trial and assess the usefulness of serum antibodies for diagnosing allergy and predicting rechallenge outcome. PATIENTS AND METHODS PEG-ASP was administered to 598 patients in St Jude’s Total XVI study. Results were compared with Total XV study ( ClinicalTrials.gov identifiers: NCT00549848 and NCT00137111 ), which used native L-ASP. Serum samples (n = 5,369) were analyzed for anti–PEG-ASP immunoglobulin G by enzyme-linked immunosorbent assay. Positive samples were tested for anti–polyethylene glycol (PEG) and anti–L-ASP. We analyzed potential risk factors for reactions and associations between antibodies and reactions, rechallenge outcomes, and PEG-ASP pharmacokinetics. RESULTS Grade 2 to 4 reactions were less common in the Total XVI study with PEG-ASP (81 [13.5%] of 598) than in the Total XV study with L-ASP (169 [41.2%] of 410; P = 1.4 × 10−23). For Total XVI, anti-PEG, not anti–L-ASP, was the predominant component of anti–PEG-ASP antibodies (96%). In a multivariable analysis, more intrathecal therapy (IT) predicted fewer reactions ( P = 2.4 × 10−5), which is consistent with an immunosuppressant contribution of IT. Anti–PEG-ASP was associated with accelerated drug clearance ( P = 5.0 × 10−6). Failure of rechallenge after initial reactions was associated with anti–PEG-ASP ( P = .0078) and was predicted by the occurrence of angioedema with first reaction ( P = .01). CONCLUSION Less IT therapy was the only independent clinical risk factor for reactions to PEG-ASP. PEG, and not L-ASP, is the major antigen that causes allergic reactions. Anti–PEG-ASP has utility in predicting and confirming clinical reactions to PEG-ASP as well as in identifying patients who are most likely to experience failure with rechallenge.
Background Glucocorticoids and asparaginase, used to treat acute lymphoblastic leukemia (ALL), can cause hypertriglyceridemia. We compared triglyceride levels, risk factors, and associated toxicities in two ALL trials at St. Jude Children's Research Hospital with identical glucocorticoid regimens, but different asparaginase formulations. In Total XV (TXV), native Escherichia coli l‐asparaginase was front‐line therapy versus the pegylated formulation (PEG‐asparaginase) in Total XVI (TXVI). Procedure Patients enrolled on TXV (n = 498) and TXVI (n = 598) were assigned to low‐risk (LR) or standard/high‐risk (SHR) treatment arms (ClinicalTrials.gov identifiers: NCT00137111 and NCT00549848). Triglycerides were measured four times and were evaluable in 925 patients (TXV: n = 362; TXVI: n = 563). The genetic contribution was assessed using a triglyceride polygenic risk score (triglyceride‐PRS). Osteonecrosis, thrombosis, and pancreatitis were prospectively graded. Results The largest increase in triglycerides occurred in TXVI SHR patients treated with dexamethasone and PEG‐asparaginase (4.5‐fold increase; P <1 × 10−15). SHR patients treated with PEG‐asparaginase (TXVI) had more severe hypertriglyceridemia (>1000 mg/dL) compared to native l‐asparaginase (TXV): 10.5% versus 5.5%, respectively (P = .007). At week 7, triglycerides did not increase with dexamethasone treatment alone (LR patients) but did increase with dexamethasone plus asparaginase (SHR patients). The variability in triglycerides explained by the triglyceride‐PRS was highest at baseline and declined with therapy. Hypertriglyceridemia was associated with osteonecrosis (P = .0006) and thrombosis (P = .005), but not pancreatitis (P = .4). Conclusion Triglycerides were affected more by PEG‐asparaginase than native l‐asparaginase, by asparaginase more than dexamethasone, and by drug effects more than genetics. It is not clear whether triglycerides contribute to thrombosis and osteonecrosis or are biomarkers of the toxicities.
Aim Our objective was to describe the association between voriconazole concentrations and CYP2C19 diplotypes in pediatric cancer patients, including children homozygous for the CYP2C19*17 gain-of-function allele. Materials & methods A linear mixed effect model compared voriconazole dose-corrected trough concentrations (n = 142) among CYP2C19 diplotypes in 33 patients (aged 1–19 years). Voriconazole pharmacokinetics was described by a two-compartment model with Michaelis−Menten elimination. Results Age (p = 0.05) and CYP2C19 diplotype (p = 0.002) were associated with voriconazole concentrations. CYP2C19*17 homozygotes never attained therapeutic concentrations, and had lower dose-corrected voriconazole concentrations (median: 0.01 µg/ml/mg/kg; p = 0.02) than CYP2C19*1 homozygotes (median: 0.07 µg/ml/mg/kg). Modeling indicates that higher doses may produce therapeutic concentrations in younger children and in those with a CYP2C19*17/*17 diplotype. Conclusion Younger age and the presence of CYP2C19 gain-of-function alleles were associated with subtherapeutic voriconazole concentrations. Starting doses based on age and CYP2C19 status could increase the number of patients achieving therapeutic voriconazole exposure.
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