Your search keyword '"Jacqueline A. Hannam"' showing total 9 results

1. Cover

Author

Jacqueline A. Hannam, Kimmo T. Murto, Brian J. Anderson, Gregory Dembo, and Evan D. Kharasch

Subjects

Anesthesiology and Pain Medicine, Pediatrics, Perinatology and Child Health

Published

2023

2. Oxycodone target concentration dosing for acute pain in children

Author

Merja Kokki, Jacqueline A. Hannam, Brian J. Anderson, Hannu Kokki, and James D Morse

Subjects

Adult, Adolescent, Loading dose, Young Adult, Pharmacokinetics, medicine, Humans, Pain Management, Dosing, Child, Adverse effect, Maintenance dose, business.industry, Infant, Newborn, Infant, Acute Pain, Analgesics, Opioid, Anesthesiology and Pain Medicine, Child, Preschool, Pharmacodynamics, Anesthesia, Pediatrics, Perinatology and Child Health, Toxicity, Analgesia, business, Oxycodone, medicine.drug

Abstract

BACKGROUND Oxycodone pharmacokinetics have been described in premature neonates through to obese adults. Covariate influences have been accounted for using allometry (size) and maturation of oxycodone clearance with age. The target concentration is dependent on pain intensity that may differ over pain duration or between individuals. METHODS We assumed a target concentration of 35 mcg.L-1 (acceptable range ±20%) to be associated with adequate analgesia without increased risk of adverse effects from respiratory depression. Pharmacokinetic simulation was used to estimate dose in neonates through to obese adults given intravenous or parenteral oxycodone. RESULTS There were 84% of simulated oxycodone concentrations within the acceptable range during maintenance dosing. Variability around the simulated target concentration decreased with age. The maturation of oxycodone clearance is reflected in changes to context-sensitive halftime where clearance is immature in neonates compared with older children and adults. The intravenous loading and maintenance doses for a typical 5-year-old child are 100 mcg.kg-1 and 33 mcg.kg-1 .h-1 . In a typical adult, the loading dose is 100 mcg.kg-1 and maintenance dose 23 mcg.kg-1 .h-1 . CONCLUSION Simulation was used to suggest loading and maintenance doses to attain an oxycodone concentration of 35 mcg.L-1 predicted in adults. Although the covariates age and weight contribute 92% variability for clearance, there remains variability accounting for 16% of concentrations outside the target range. Duration of analgesic effect after ceasing infusion is anticipated to be longer in neonates where context-sensitive halftime is greater than older children and adults.

Published

2021

3. Compliance with perioperative prophylaxis guidelines and the use of novel outcome measures

Author

Lesley Voss, Jacqueline A. Hannam, Brian J. Anderson, Lee Blackburn, and James D Morse

Subjects

0301 basic medicine, medicine.medical_specialty, Quality management, medicine.drug_class, 030106 microbiology, Antibiotics, Perioperative Care, Medication Adherence, 03 medical and health sciences, 0302 clinical medicine, Outcome Assessment, Health Care, medicine, Humans, Surgical Wound Infection, 030212 general & internal medicine, Antibiotic prophylaxis, Child, Intensive care medicine, Out of hospital, business.industry, Incidence (epidemiology), Outcome measures, Perioperative, Antibiotic Prophylaxis, Length of Stay, Anti-Bacterial Agents, Anesthesiology and Pain Medicine, Pediatrics, Perinatology and Child Health, Guideline Adherence, business, Hospital stay

Abstract

Postoperative wound infections represent an important source of morbidity and mortality in children. Perioperative antibiotic prophylaxis has been shown to decrease the risk of developing infections and hospital guidelines surrounding antibiotic use exist to standardize patient care. Despite supporting evidence, rates of compliance with guidelines vary. Quality improvement initiatives have been introduced to improve compliance with intraoperative antibiotic guidelines. Thorough infection surveillance, including antibiotic provision in presurgical checklists, computerized voice antibiotic administration prompts, and national feedback systems are now increasingly common. Few studies have been conducted investigating the effectiveness of prophylactic antibiotics in children. Outcome measures such as morbidity and mortality and return to the operating room can be used to examine the relationship between antibiotic use and patient outcome but these measures are limited in that they occur infrequently or are subjective and difficult to measure. Metrics such as days alive out of hospital and length of hospital stay may be useful alternatives for ongoing monitoring of infections and identifying improvements in patient outcomes. Guidelines on antibiotic prophylaxis have facilitated an increase in the correct provision of perioperative antibiotics and a reduction in the incidence of postoperative infection. Measures of patient outcome such as days alive out of hospital and length of hospital stay are easy to collect and calculate but further work is needed to confirm the utility of these measures for monitoring infection rates.

Published

2018

4. Oral morphine dosing predictions based on single dose in healthy children undergoing surgery

Author

Brian J. Anderson, Katherine A. Brand, Katarina Aleksa, Gideon Koren, Erin Cooke, Bruce Carleton, Michael J. Rieder, Pamela Winton, Gillian R. Lauder, Carolyne J. Montgomery, Ricardo Jimenez-Mendez, Joy Dawes, and Jacqueline A. Hannam

Subjects

Oral, Male, medicine.medical_specialty, Cmax, Administration, Oral, Opioid, Pediatrics, Enteral administration, Mass Spectrometry, Dose-Response Relationship, 03 medical and health sciences, 0302 clinical medicine, Pharmacokinetics, 030202 anesthesiology, 030225 pediatrics, medicine, Humans, Dosing, Child, Preschool, Analgesics, Chromatography, Liquid, Surgical Procedures, Morphine, Dose-Response Relationship, Drug, business.industry, Codeine, Operative, 3. Good health, Surgery, Analgesics, Opioid, Anesthesiology and Pain Medicine, Child, Preschool, Surgical Procedures, Operative, Anesthesia, Administration, Pediatrics, Perinatology and Child Health, Female, Drug, business, Chromatography, Liquid, medicine.drug, Blood sampling

Abstract

Background Oral morphine has been proposed as an effective and safe alternative to codeine for after-discharge pain in children following surgery but there are few data guiding an optimum safe oral dose. Aims The aim of this study was to characterize the absorption pharmacokinetics of enteral morphine in order to simulate time–concentration profiles in children given common oral morphine dose regimens. Methods Children (2–6 years, n = 34) undergoing elective surgery and requiring opioid analgesia were randomized to receive preoperative oral morphine (100 mcg·kg−1, 200 mcg·kg−1, 300 mcg·kg−1). Blood sampling for morphine assay was performed at 30, 60, 90, 120, 180, and 240 min. Morphine serum concentrations were determined by liquid chromatography–mass spectroscopy and pharmacokinetic parameters were calculated using nonlinear mixed effects models. Current data were pooled with published time–concentration profiles from children (n = 1059, age 23 weeks postmenstrual age – 3 years) administered intravenous morphine, to determine oral bioavailability (F), absorption lag time (TLAG), and absorption half-time (TABS). These parameter estimates were used to predict concentrations in children given oral morphine (100, 200, 300, 400, 500 mcg·kg−1) at different dosing intervals (3, 4, 5, 6, 8, 12 h). Results The oral morphine formulation had F 0.298 (CV 36.5%), TLAG 0.45 (CV 63.6%) h and TABS 0.71 (CV 55%) h. A single-dose morphine 100 mcg·kg−1 achieved a mean CMAX 10 mcg·l−1. Repeat 4-hourly dosing achieved mean steady-state concentration 13–18 mcg·l−1; concentrations associated with good analgesia after intravenous administration. Serum concentration variability was large ranging from 5 to 55 mcg·l−1 at steady state. Conclusions Oral morphine 200 mcg·kg−1 then 100 mcg·kg−1 4 h or 150 mcg·kg−1 6 h achieves mean concentrations associated with analgesia. There was high serum concentration variability suggesting that respiration may be compromised in some children given these doses.

Published

2016

5. Pharmacokinetics and analgesic effectiveness of intravenous parecoxib for tonsillectomy ± adenoidectomy

Author

Brian J. Anderson, Elsa Taylor, Lesley Salkeld, Lena Tan, Jacqueline A. Hannam, and Sam Salman

Subjects

Male, Adolescent, medicine.medical_treatment, Population, Analgesic, 030226 pharmacology & pharmacy, Fentanyl, Adenoidectomy, 03 medical and health sciences, 0302 clinical medicine, Parecoxib, medicine, Humans, Child, education, Tonsillectomy, Pain, Postoperative, education.field_of_study, Cyclooxygenase 2 Inhibitors, business.industry, Isoxazoles, Valdecoxib, Treatment Outcome, Anesthesiology and Pain Medicine, Child, Preschool, Pharmacodynamics, Anesthesia, Pediatrics, Perinatology and Child Health, Female, Tramadol, Analgesia, business, 030217 neurology & neurosurgery, medicine.drug

Abstract

SummaryBackground Few pharmacokinetic (PK) and pharmacodynamic (PD) data exist for COX-2 selective inhibitors in children. We wished to characterize the PKPD of parecoxib and its active metabolite, valdecoxib, in this population. Methods Children (n = 59) were randomized to parecoxib 0.25 mg·kg−1, 1 mg·kg−1, and 2 mg·kg−1 during tonsillectomy ± adenoidectomy. Samples (4–6 per child) were obtained from indwelling cannula over 6 h. A second group of inpatient children (n = 15) given 1 mg·kg−1 contributed PK data from 6 to 24 h. Pain scores and rescue medication for the first group were recorded postoperatively for up to 24 h. PK data were pooled with those (10 samples/24 h) from a published study of children (n = 38) who underwent surgery. A three-compartment parent and one-compartment metabolite model with first-order elimination was used to describe data using nonlinear mixed effects models. An EMAX model described the relationship between dose and rescue morphine equivalents during recovery. Results Parecoxib PK parameter estimates were CLPARECOXIB 19.1 L·h−1·70 kg−1, V1PARECOXIB 4.2 L·70 kg−1, Q2PARECOXIB 6.29 L·h−1·70 kg−1, V2PARECOXIB 130 L·70 kg−1, Q3PARECOXIB 6.02 L·h−1·70 kg−1, and V3PARECOXIB 2.03 L·70 kg−1. We assumed all parecoxib was metabolized to valdecoxib with CLVALDECOXIB 9.53 L·h−1·70 kg−1 and VVALDECOXIB 51 L·70 kg−1. There was no maturation of clearance over the age span studied. There were no differences in pain scores between groups on waking, discharge, 12 h, or 24 h. There were no differences in analgesia consumption over 24 h between groups for tramadol, fentanyl, and morphine rescue use. Fentanyl and morphine consumption, expressed as morphine equivalents (0.13 mg·kg−1) in the 0.25 mg·kg−1 group, was greater than that observed in the 1 or 2 mg·kg−1 groups (0.095 mg·kg−1) in PACU. Conclusions Parecoxib 0.9 mg·kg−1 in a 2-year-old, 0.75 mg·kg−1 in a 7-year-old, and 0.65 mg·kg−1 in a 12-year-old child achieves dose equivalence of 40 mg in a standard 70 kg person. Clearance maturation may occur in infants younger than the current cohort. Parecoxib doses above 1 mg·kg−1 add no additional analgesia.

Published

2016

6. Postoperative analgesia using diclofenac and acetaminophen in children

Author

Brian J. Anderson, Jacqueline A. Hannam, Nicholas H. G. Holford, and Murali Mahadevan

Subjects

Male, Diclofenac, Placebo, Double-Blind Method, Pharmacokinetics, medicine, Humans, Dosing, Child, Acetaminophen, Pain Measurement, Tonsillectomy, Pain, Postoperative, Dose-Response Relationship, Drug, business.industry, Anti-Inflammatory Agents, Non-Steroidal, Hazard ratio, Infant, Analgesics, Non-Narcotic, Elixir, stomatognathic diseases, Treatment Outcome, Anesthesiology and Pain Medicine, Child, Preschool, Anesthesia, Pharmacodynamics, Pediatrics, Perinatology and Child Health, Drug Therapy, Combination, Female, business, medicine.drug

Abstract

Background Diclofenac dosing in children for analgesia is currently extrapolated from adult data. Oral diclofenac 1.0 mg·kg(-1) is recommended for children aged 1-12 years. Analgesic effect from combination diclofenac/acetaminophen is unknown. Methods Children (n = 151) undergoing tonsillectomy (c. 1995) were randomized to receive acetaminophen elixir 40 mg·kg(-1) before surgery and 20 mg·kg(-1) rectally at the end of surgery with diclofenac suspension 0.1 mg·kg(-1) , 0.5 mg·kg(-1) , or 2.0 mg·kg(-1) before surgery or placebo. A further 93 children were randomized to receive diclofenac 0.1 mg·kg(-1) , 0.5 mg·kg(-1) , or 2.0 mg·kg(-1) only. Postoperative pain was assessed (visual analogue score, VAS 0-10) at half-hourly intervals from waking until discharge. Data were pooled with those from a further 222 children and 30 adults. One-compartment models with first-order absorption and elimination described the pharmacokinetics of both medicines. Combined drug effects were described using a modified EMAX model with an interaction term. An interval-censored model described the hazard of study dropout. Results Analgesia onset had an equilibration half-time of 0.496 h for acetaminophen and 0.23 h for diclofenac. The maximum effect (EMAX ) was 4.9. The concentration resulting in 50% of EMAX (C50 ) was 1.23 mg·l(-1) for diclofenac and 13.3 mg·l(-1) for acetaminophen. A peak placebo effect of 6.8 occurred at 4 h. Drug effects were additive. The hazard of dropping out was related to pain (hazard ratio of 1.35 per unit change in pain). Diclofenac 1.0 mg·kg(-1) with acetaminophen 15 mg·kg(-1) achieves equivalent analgesia to acetaminophen 30 mg·kg(-1) . Conclusions Combination therapy can be used to achieve similar analgesia with lower doses of both drugs.

Published

2014

7. Ketofol simulations for dosing in pediatric anesthesia

Author

Brian J. Anderson, Finn L. S. Coulter, and Jacqueline A. Hannam

Subjects

Analgesics, medicine.drug_class, business.industry, Sedation, Analgesic, Loading dose, Drug Combinations, Anesthesiology and Pain Medicine, Child, Preschool, Anesthesia, Pharmacodynamics, Ketofol, Pediatrics, Perinatology and Child Health, medicine, Humans, Antiemetic, Computer Simulation, Ketamine, medicine.symptom, Propofol, business, Anesthetics, Intravenous, medicine.drug

Abstract

Background Propofol mixed with racemic ketamine (or 'ketofol') is popular for short procedural sedation and analgesia. Use is creeping into anesthesia, yet neither the optimal combination nor infusion rate is known. The EC(50) of propofol's antiemetic effect is reported to be 0.343 mg·l(-1), while ketamine analgesia is thought to persist with concentrations above 0.2 mg·l(-1). We aimed to determine a ketofol dosing regimen for anesthesia 30-min and 1.5-h duration in a healthy child that did not unduly compromise recovery. Methods Pharmacokinetic-pharmacodynamic parameters were used to simulate drug concentration and effect profiles over time for different ratios of propofol to ketamine ratios (1 : 1 to 10 : 1) and rates. The target effect was the 95% probability of loss of response to a 5-s transcutaneous tetanus (P05). Combined effects were additive, with a propofol EC(50) of 3.1 mg·l(-1), ketamine EC(50) of 0.64 mg·l(-1), and slope of 5.4. The time to predicted 50% probability of return of this response after ceasing infusion (P(50)) was determined for a 5-year-old 20-kg healthy child. Results The addition of ketamine to propofol infused using a manual infusion regimen (loading dose 3 mg·kg(-1), then 15 mg·kg(-1) ·h(-1) for 15 min, 13 mg·kg(-1) ·h(-1) for 15 min, 11 mg·kg(-1) ·h(-1) for 30 min, and 10 mg·kg(-1) ·h(-1) for 1-2 h) caused prolonged postoperative sedation. The P(50) after a 1.5-h infusion using a 1 : 1 mixture was 4.5 h, 2 : 1 mixture was 3.25 h, 5 : 1 mixture was 1.6 h, and 10 : 1 mixture was 40 min. These P(50) estimates could be reduced by slowing administration infusion rates to 20%, 33%, 50%, 67%, 80%, and 90% for mixtures 1 : 1, 2 : 1, 3 : 1, 5 : 1, 6.7 : 1, and 10 : 1, respectively. These rates achieve a P(50) of approximately 20 min for 30-min duration anesthesia and 60 min for 1.5-h duration anesthesia. Conclusions The addition of ketamine to propofol infusion will prolong recovery unless infusion rates are decreased. We suggest an optimal ratio of racemic ketamine to propofol of 1 : 5 for 30-min anesthesia and 1 : 6.7 for 90-min anesthesia. Delivery of these ratios achieves propofol concentrations above an antiemetic threshold for longer than the ketamine concentration above the analgesic threshold during, potentially reducing postoperative nausea incidence.

Published

2014

8. Explaining the acetaminophen–ibuprofen analgesic interaction using a response surface model

Author

Brian J. Anderson and Jacqueline A. Hannam

Subjects

Adult, Combination therapy, Analgesic, Ibuprofen, Placebo, Models, Biological, Double-Blind Method, Pharmacokinetics, medicine, Humans, Pain Management, Computer Simulation, Drug Interactions, Child, Acetaminophen, Pain Measurement, Pain, Postoperative, Dose-Response Relationship, Drug, business.industry, Analgesics, Non-Narcotic, Drug interaction, Drug Combinations, Anesthesiology and Pain Medicine, Pharmacodynamics, Anesthesia, Tooth Extraction, Pediatrics, Perinatology and Child Health, business, medicine.drug

Abstract

Summary Background: The value of acetaminophen–ibuprofen combination therapy over single therapy is uncertain in acute pediatric pain management. A model describing the interaction between these two drugs would be useful both for understanding current literature and for future study design. Methods: Published pooled time–effect profiles in adults given combination or single therapy after dental extraction were used to construct an interaction model. Pain was measured using pain intensity differences (PRID, 0–10) from zero to eight hours postoperatively. Pharmacodynamic parameter estimates were assumed the same in adults as children. Pediatric pharmacokinetic estimates were scaled using allometric theory. Curve fitting was performed using nonlinear mixed effects models. Results: Pooled data were available in adults given eight single and multiple dose combinations as well as placebo. The ibuprofen dose range was 100–400 mg, and acetaminophen dose range was 500–1000 mg. Pharmacodynamic parameter estimates, expressed using the Hill equation, were maximum effect (EMAX) 4.06 (95% CI: 3.24, 5.51), the concentration of acetaminophen associated with 50% of the maximal drug effect (EC50,ACET) 11.9 (95% CI: 6.0, 49.5) mg·l−1, the ibuprofen EC50 (EC50,IBU) 5.07 (95% CI: 3.50, 8.26) mg·l−1, and Hill coefficient 2 (95% CI: 1.3, 2.8). An interaction term was fixed at zero (additive interaction). Simulation showed that the addition of acetaminophen to ibuprofen when less than 5 mg·kg−1 was effective; acetaminophen had minimal effect when given with ibuprofen at doses greater than 5 mg·kg−1 in the immediate postoperative period. A more sustained analgesic effect was noted at 4–8 h after combination dosing. Conclusions: This drug interaction modeling example is useful to explain combination therapy nuances and impacts on study design. Differences in effect between single drug therapy and combination therapy should be sought at lower doses and beyond the immediate postoperative period. Combination therapy may prolong the duration of analgesia. The maximum effect (EMAX) limits the early additional analgesic gain from combination therapy beyond commonly used doses.

Published

2011

9. Tears at breakfast

Author

Jacqueline A. Hannam, Brian J. Anderson, and Francis Veyckemans

Subjects

medicine.medical_specialty, Anesthesiology and Pain Medicine, Analgesics.non-narcotic, business.industry, Anesthesia, Pediatrics, Perinatology and Child Health, Tears, Medicine, Ambulatory Surgical Procedure, business, Acetaminophen, medicine.drug, Surgery

Published

2012