Strategies for Implementing Pediatric Dose Standardization: Considerations From the Vizient University Health System Consortium Pharmacy Network Pediatric Pharmacy Committee

Pediatric patients are at a heightened risk for medication errors due to variability in medication ordering and administration. Dose rounding and standardization have been 2 practices historically used to reduce variability and improve medication safety. This article will describe strategies for implementing pediatric dose standardization. Local practice often dictates the operational decisions made at an institutional level, leading to a lack of a standard methodology. Vizient survey results demonstrate there is wide variation in dose standardization and ready-to-use (RTU) practices although most responding institutions have attempted to limit bedside manipulation to reduce medication error. There are many barriers to consider before pursuing dose standardization at an institution. These include selecting medications to standardize, calculating appropriate standardized doses, preparing RTU products, and supplying the products to the patient. Strategies to overcome implementation issues are described as well as identification of knowledge gaps related to the preparation and use of RTU products in the pediatric population. There is opportunity to enhance an institution's ability to provide RTU medications. Although there are several barriers, those that have had successful implementation have leveraged their information technology systems, garnered multidisciplinary support, and customized their practice to meet their operational demands.

How bilastine is used to treat allergic rhinitis and urticaria in children

Management guidelines for allergic rhinitis and urticaria recommend oral second-generation antihistamines as first-line treatment. The efficacy and safety of bilastine, the newest nonsedating second-generation antihistamine, are well established in adolescents/adults with these allergic conditions. The bilastine development program for pediatric use (2–<12 years) followed EMA-authorized processes. Pharmacokinetic/pharmacodynamic simulation and modeling and a pharmacokinetic study were conducted to identify and confirm the pediatric dose (10 mg/day). A Phase III, multicenter, double-blind, randomized, placebo-controlled, parallel-group study was performed to confirm the safety of bilastine 10 mg/day in children. In this article, evidence is reviewed for use of bilastine in children with allergic rhinoconjunctivitis or urticaria. Several cases are presented which demonstrate its role in routine clinical practice.

Cytokine release syndrome after CAR infusion in pediatric patients with refractory/relapsed B-ALL: is there a role for diclofenac?

Background: Cytokine release syndrome (CRS) is a major complication after chimeric-antigen receptor T-cell treatment, characterized by an uncontrolled systemic inflammatory reaction. We investigated the potential role of diclofenac in the management of CRS in five pediatric patients treated for relapsed/refractory B-lineage acute lymphoblastic leukemia. Methods In case of persistent fever with fever-free intervals shorter than 3 hours, diclofenac continuous infusion was initiated, at the starting dose of 0.5 mg/Kg/day, the lowest effective pediatric dose in our experience, possibly escalated up to 1 mg/Kg/day, as per institutional guidelines. Results: CRS occurred at a median of 20 hours (range 8–27) after tisagenlecleucel infusion. Diclofenac was started at a median of 20 hours (range 13–33) after fever onset. A mean of 3.07 febrile peaks without diclofenac and 0.95 with diclofenac were reported ( p = 0.02). Clinical benefit was achieved by hampering the progression of tachypnea and tachycardia. Despite fever control, CRS progressed in four of the five patients, and hypotension requiring vasopressors and fluid retention, as well as hypoxia, occurred. Vasopressors were followed by 1–2 doses of tocilizumab (one in patient 2 and two in patients 3, 4, and 5), plus steroids in patients 4 and 5. Conclusion: Based on a limited number of patients, diclofenac leads to better fever control, which translates into symptom relief and improvement of tachycardia, but could not prevent the progression of CRS.

Renal 99mTc-DMSA pharmacokinetics in pediatric patients

99mTc-DMSA is one of the most commonly used pediatric nuclear medicine imaging agents. Nevertheless, there are no pharmacokinetic (PK) models for 99mTc-DMSA in children, and currently available pediatric dose estimates for 99mTc-DMSA use pediatric S values with PK data derived from adults. Furthermore, the adult PK data were collected in the mid-70’s using quantification techniques and instrumentation available at the time. Using pediatric imaging data for DMSA, we have obtained kinetic parameters for DMSA that differ from those applicable to adults. Methods We obtained patient data from a retrospective re-evaluation of clinically collected pediatric SPECT images of 99mTc-DMSA in 54 pediatric patients from Boston’s Children Hospital (BCH), ranging in age from 1 to 16 years old. These were supplemented by prospective data from twenty-three pediatric patients (age range: 4 months to 6 years old). Results In pediatric patients, the plateau phase in fractional kidney uptake occurs at a fractional uptake value closer to 0.3 than the value of 0.5 reported by the International Commission on Radiological Protection (ICRP) for adult patients. This leads to a 27% lower time-integrated activity coefficient in pediatric patients than in adults. Over the age range examined, no age dependency in uptake fraction at the clinical imaging time was observed. Female pediatric patients had a 17% higher fractional kidney uptake at the clinical imaging time than males (P < 0.001). Conclusions Pediatric 99mTc-DMSA kinetics differ from those reported for adults and should be considered in pediatric patient dosimetry. Alternatively, the differences obtained in this study could reflect improved quantification methods and the need to re-examine DMSA kinetics in adults.