Determination of toxic (harmful) dose in children: an industry approach Soraya Madani, PhD...
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Transcript of Determination of toxic (harmful) dose in children: an industry approach Soraya Madani, PhD...
Determination of toxic (harmful) dose in children:
an industry approach
Soraya Madani, PhD
Exploratory Clinical Development
Novartis Pharmaceuticals
ANEC Konferenz Kindersichere Verpackungen Conference on 23 Sept 04
Packaging of Medicines and the Safety of Children
Background
Child resistant packaging mandatory in US to fullfill requirements of the Poison Prevention Packaging Act 1970 and amended 1995 to include ‘senior-friendly’ packaging
Similar regulation are discussed in the EU
Legislation application: certain house hold substances, and oral prescription drug products
Legislation aim: prevent children from serious injury or illness as a result of handling or accidental ingestion of drugs
Failure definition (according to CFR title 16, part 1700) for solid oral drugs packed in unit dose packs: any child of 11.4 kg* who opens or gains access to the number of individual units which constitute the “harmful dose”, or a child who opens or gains access to more than 8 individual units
The CFR title 16, part 1700 discusses packaging test procedures extensively. But it is not precized how the harmful dose should be established
* based on CDC growth chart an 11.4 kg child: manily 1.5-2.5 yr (2 year-old 50th percentile)
Harmful dose should be the lowest dose that may cause toxicity. However, this is rarely known in practice. What is more generally determined and is used as a basis is the MTD (maximum Tolerated Dose) in adults
MTD: the largest dose of a drug a patient can take without unacceptable adverse side effects
In Drug Development: usually the top dose in the single-dose escalation human safety-tolerability trail that does not cause unacceptable acute serious adverse event
Often have information about maximum tested dose in humans, but lack maximum tolerated dose (MTD)
Lack paediatric information (unless target population is children)
Degree of child resistance is linked with toxicity of the drug (the lower the unit #s the more difficult to access the pharmaceutical)
Is lower # of units necessarily safer?
Compliance may decrease not safe
Bypassing the packaging increase possibility of accidental ingestion
General challenges
Limited human information: Drug A
Some human information: Drug B
Information rich: Drug C
The toxicity of concern is acute (single dose) toxicity, not chronic toxicity
The single dose data from single dose escalation. The top dose is considered MTD.
The nature of toxicity is similar in adults and children
Assumptions for the harmful dose determination?
Examples
Drug A: Lack of comparable human systemic exposure as a reference Stage of development: Phase 2
Route of administration: inhalation, with capsule inhaler
Drug product packed looks like oral solid dosage forms: capsules and blisters
Particular challenge: accidental ingestion oral vs. human exposure information via inhalation
In healthy volunteers: SD escalation (inhaled) up to 2000 μg (no SAE observed)
MTD: N/A. Therapeutic dose: not known (400 μg or 800 μg) in form of 400 μg capsules
Pediatric data: N/A
Animal Toxicology : NOAEL (Not Observed Adverse Event Level) in two species rat and dog
Drug A: calculation Safety margin approach applied: NOAEL from animal toxicology
used as the reference
Normally, uncertainty factors for interspecies (10x) and intraspecies (x10) differences are taken into account in risk assessment of xenobiotics
Safety margin of ≥10-fold criteria
Safety margin = AUC NOAEL/ AUC human
AUC comparison not preferred, Toxicokinetics via oral but human PK via inhalation
Safety margin = NOAEL (mg/m2) / Dosechild (mg/m2)
Dose comparison was preferred (mg/m2). Using the NOAEL dose in most sensitive species (ref) and 0.4, 2 and 4mg accidental ingestion in a child (1, 5 and 10 capsules of 400 μg) as the comparator (conversion factor is 23 for a child and 37 for an adult)
Safety margins were: 200x, 45x, 23x respectively
Scaling: adult to children BWT vs. BSA
Body Weight (BWT) approach:
Child dose = Adult dose (mg/kg)*/child WT (11.4 kg)
Body surface area (BSA) approach : Rowland and Tozer
The SA of a child can be determined from its BWT using the observation that SA is proportional to BW to the 0.7 power (this is shown in humans). Hence the below mathematical relationship exists:
Child dose = 1.4** x (Child WT/70 kg)0.7 x adult dose1
•Assume 70 kg adult•** conversion factor1 Rowland and Tozer Clinical Pharmacokinetics.3rd Edition. Lippinot Williams & Wilkins
Scaling: BWT vs. BSA from systemic exposure (PK) perspectiveBody Weight (BWT) approach: predicting drug clearance (CL) using per kg model will
underestimate clearance, error increases as the WT decreases (e.g 10% for a 47kg, but 200% for 3.4 kg new born)1
Simple, Commonly used, produces the most conservative estimate, results in the lowest unit #s in the blister package compliance, bypassing the packaging Safer?!
Body surface area (BSA) approach : Predicting CL based SA model gives a better prediction but leads
to an over prediction of about 10% at BWT < 20 kg Research shows that dosage regimen, cardiac output and renal
blood flow as well as GFR (Glomerular Filtration Rate) in children and adults of different sizes correlate better with BSA than BWT
Because CL relates dose to systemic exposure (AUC) and the physiological factors above are related to CL, using SA as a method of calculation has its justification
1 Anderson et al., (1997) Clinical PK 33 (5). Pharmacokinetics of ingested xenobiotics in children: A comparison with adults. De Zwart et al, RIVM report 623860011/2002
Drug B: sub-MTD in adults
Stage of development: 2b
SD escalation in HV (healthy Volunteers): up to 40 mg
MTD: N/A. At 40 mg observed mild AE (Adverse Event, but no SAE (Serious Adverse Events) was observed.
Therapeutic dose: Not Available N/A. 1.25, 2.5 and 5 mg are the possibilities
Pre-clinical information in animal species: NOAEL (Not Observed Adverse Event Level) was not defined under acute oral conditions. 100 mg/kg was well tolerated.
Pediatric data: (N/A)
Drug B: calculation
Only human data utilized. 40 mg was assumed as the MTD and the reference
Two scaling approaches were considered: BWT Body Weight) and BSA (Body Surface Area) normalization
a)BWT:
MTD (mg/kg)/11.4 kg = 7 mg 1 tablet/ blister
b)BSA*:
Child dose = 1.6 x (Child WT/70 kg)0.7 x adult dose = 18 mg 3 tablet/blister
Final decision pending after pediatric data available
*Rowland and Tozer Formula (Clinical Pharmacokinetics text book). 1.6 is the conversion factor for a 11.4 kg child
Drug C: information rich! Stage of development: Marketed. New formulation
development
Therapeutic dose : 250-mg qd (125 mg and 250-mg tablets)
Single dose escalation safety-tolerability trial in HV: up to 1500-mg qd (No SAE observed)
MTD: not reached in human subjects, below-MTD: 1500-mg
Clinical studies up to 2000 mg had similar AE as the 250 and 500 mg
Data in children: available
Post-marketing reports of acute overdose: available
Tox data: both short and long term studies available
Toxicology estimation
Acute oral studies (SD)in rat and mice lethal dose > 4000 mg/kg
in monkey well tolerated up to 300 mg/kg
Chronic dosing (26 wk): No marked toxic effects in rats or monkey up to 300 mg/kg
Juvenile rats similar exposure to adults studied up to 100 mg/kg
Safety margin 10-fold : NOAEL (not observed adverse event level) in most sensitive species as the reference
The harmful dose would be 1100 mg
PK estimation: children and adults
N= 36, ages 4-12 years, sparse sampling, steady state data
Doses based on WT < 20 kg (62.5 mg), 20-40 kg (125 mg)
Population PK (popPK) applied BWT a covariate influencing the CL/f of the drug (CL/F = 22.4 + 0.172 (BWT – 43.6))
CL/f in a child of 11.4 kg is about 16.4 L/h compared to 26 L/h in a 70 kg adult (~ 30% lower)
If to only use human PK data: using the AUC from maximum SD trail in adults as reference (1500 mg) and the above mathematical relationship Harmful dose : 760 mg (below harmful dose)
Post-marketing reports of dug overdose in children ≤ 18 y
4/9 cases were children < 6 years of age.
Overdose ranged from 600-2000 mg
All but one case were asymptomatic
in the case of a 5-year old female that displayed ataxia and abnormal coordination after ingestion of 700 mg of Drug C by accident
At 700 mg the symptoms abated within six hours
If to use post marketing data: harmful dose 700mg -2000 mg
Drug C: Summary
Preclinical tox: lethal dose is 4000 mg/kg. Absence of acute or chronic toxicity at 100 mg/kg (NOAEL) in most sensitive animal species 1100 mg (none toxic dose)
Clinical PK in adult and children: CL/f in a child of 11.4 kg is 30% lower. Using SD adult AUC at 1500 mg (maximum tested dose) as reference 750 mg (none toxic dose)
Clinical experience: Wide margin of safety based on the clinical experience (up to 2000 mg chronic dosing)
Lack of SAE upon accidental ingestion of up to 2000 mg in children
750 mg was determined as sub-harmful dose in children of 11.4 kg blister packaging of 3 or 6 units based on the dosage strength
Drug C
In the absence of the wealth of the data:
simple Body weight (mg/kg) scaling approach:
Maximum tested dose from the SD escalation study in adults= 1500 mg
MTD (mg/kg) = 1500/70= 21 mg/kg
21 mg/kg x 11.4 = 244 mg
244 mg is a value below therapeutic dose! and 3-fold lower than 750 mg
Lessons learned for determination of toxic dose
A single method can not be applied for all drugs
Consider whether compound has special developmental toxicity (e.g. bone metabolism, cognitive functions). Consider juvenile Tox and Reprotox data if available, and relevance for acute dosing
If no specific toxicity, scale the single dose adult MTD down to a 11.4 kg child (based on BW, BSA, or more sophisticated approaches (e.g., PK-PD)).
Use lower dose if specific toxicity is expected, or higher dose if side effects are benign.
If paediatric data are available, consider tolerability and PK results to refine scaling.
Where applicable, integrated approach. If possible, Include data from: clinical, human PK, animal PK and toxicology
Proposed decision tree for determination of harmful (toxic) dose
Maximum tolerated dose (MTD) in adults (oral)
BSA1,2
yes no
Maximum tested dose (oral)
no yes
Pediatric dataScaling to children
BWT conversion1
Safety margin approach using animal data1
yesno
Establish a mathematical relationship between adult and children data. Use it as scaling factor (eg, popPK, Pk-PD, exposure-response etc.)
BSA scaling from max. Tested dose
Pediatric data
yes
no
Establish a mathematical relationship between adult and children data. Use it as scaling factor (eg, popPK, Pk-PD, exposure-response etc.)
Reference 1: Pharmacokinetics of ingested xenobiotics in children: A comparison with adultsDe Zwart et al, RIVM report 623860011/2002*Rowland and Tozer Formula (Clinical Pharmacokinetics text book)
or
For NTI drugs (narrow theapeutic index). Toxic drugs
For most drugs