Active Pharmaceutical Ingredient (API)
Download
Report
Transcript Active Pharmaceutical Ingredient (API)
Active pharmaceutical ingredients
Evaluation of quality and interchangeability of medicinal products
Training workshop for evaluators from National Medicines
Regulatory Authorities in East Africa Community
10-14 September 2007, Dar Es Salaam, Tanzania
Presented by
Rutendo Kuwana
What is an API?
Active Pharmaceutical Ingredient (API)
A substance or compound that is intended to be used in
the manufacture of a pharmaceutical product as a
therapeutically active compound (ingredient)
2|
Active Pharmaceutical Ingredients
Presentation approach
Collect and interpret available information on the APIs (pre dossier studies),
such as:
Literature, all aspects (chemical/physical)
Monographs in pharmacopoeia (example: ARVs)
3|
Active Pharmaceutical Ingredients
Some definitions
Enantiomer
cpds with same molecular formula as substance but differ in spatial
arrangement of atoms and are non-superimpossable mirror images
Polymorphism – occurrence of different crystalline forms of the same
substance
Degradation product – molecule resulting from chemical change in
substance due to e.g. light, temperature, pH, water, reaction with
excipient, immediate container/closure
4|
Active Pharmaceutical Ingredients
Some definitions (2)
Impurity – any component of the medicinal product which
is not the chemical entity defined as the active
substance or an excipient of the product
Identified Impurity – an impurity for which structural
characterisation has been achieved
Unidentified degradation product – an impurity defined
only by qualitative properties e.g. Rt
5|
Active Pharmaceutical Ingredients
Available information on API
Applicants should collect and analyse available
information of the API in a systematic approach
Some outcomes:
6|
Sound scientific understanding of the API, with respect to
properties, stability, specifications, etc.
Assists in API manufacture and DMF compilation
Sound choice of API manufacturer (source)
Assists in dossier compilation
Important for FPP pharmaceutical development
Reduction of time / cost
Active Pharmaceutical Ingredients
Literature information on API
Standard works / series / books – such as:
(Analytical) Profiles of Drug Substances and Excipients [eds:
Florey / Brittain – 31 volumes]
The Merck Index (for structures, properties)
Pharmaceutical Codex (12th edition) (“old” APIs)
Journals through search facilities such as
International Pharmaceutical Abstracts, Chemical Abstracts,
Analytical Abstracts & internet
Pharmacopoeial monographs (current)
Analysis of structure & stereochemistry
7|
Active Pharmaceutical Ingredients
Information from
literature and structures
APIs which are organic compounds, have unique
chemical structures & stereochemistry
These structures, together with the solid/liquid state
conditions, are basically responsible for chemical and
physical properties of the APIs
8|
Active Pharmaceutical Ingredients
Information from literature & structure:
Rifampicin
hydrolysis (to 25-desacetyl)
Oxidation
to N oxide
light sensitive
oxidation
(to quinone)
9|
Active Pharmaceutical Ingredients
hydrolysis
(to 3-formyl)
Information from literature & structure
Rifampicin (discussion - 1)
Oxidation
Hydroquinone group
Tertiary amine
Moderately prone towards oxidation (to N-oxide)
Enhances solubility in acid medium
Oxidation enhanced by
10 |
Main degradation of API (to rifampicin quinone)
Enhances solubility in alkaline medium
Metal ions
Low pH
Active Pharmaceutical Ingredients
Information from literature & structure
Rifampicin (discussion - 2)
Hydrolysis
Hydrazone (imine) group
Hydrolysis to 3-formyl rifamycin
25-acetyl (ester) group
Hydrolysis to 25-desacetyl rifampicin (minor)
Light sensitive
Due to conjugation in molecule (unsaturated)
Storage of bulk raw material (BP/Ph.Eur.):
11 |
Store under nitrogen in an airtight container, protected from light at
temperature of ≤ 25ºC
Active Pharmaceutical Ingredients
Information from literature & structure
Isoniazid
Small molecule (quite stable)
12 |
Basic amino functions
Primary amine - reacts with aldehydes/lactose
see presentation: FPPs – formulation problems?
Can hydrolyze under stress conditions to e.g. isonicotinic acid & hydrazine
Oxidize in presence of strong oxidants (e.g. permanganate), with metals as
catalyst
Active Pharmaceutical Ingredients
Information from literature & structure
Indinavir sulfate
Basic amino atoms (2)
forms H2SO4 salt
ethanol in crystal
Unstable
2 main degradation products
– moisture and temp. sensitive
– acid / base enhanced
– Intra-molecular reaction
+
Kreutz, J. Pharm. Biomed. Anal., 19,
725-735 (1999) and Crixivan® EPAR
13 |
Active Pharmaceutical Ingredients
Literature support
Literature information used in the dossier should always be
accompanied by
Full traceable reference citations, for instance:
Devani, M.B., Shishoo, C.J., Doshi, K.J. & Patel, H.B. Kinetic
studies of the interaction between isoniazid and reducing sugars.
Journal of Pharmaceutical Sciences, 74, 427-432 (1985)
Photocopies of publication or relevant pages
14 |
Active Pharmaceutical Ingredients
Properties of APIs
Scenarios:
API not described in BP, Ph., JP, Ph.Eur., or USP (non compendial)
API described in BP, Int.Ph., JP, Ph.Eur.,or USP
(compendial)
Information from literature (important)
15 |
Active Pharmaceutical Ingredients
Properties: non-compendial APIs
Proof of structure/stereochemistry correctness
– Single crystal X-ray structure (sufficient) or
– Spectrometric data (IR, 1H & 13C NMR, MS, etc.): QA certified
copies of the spectra and tabulated data with
• assignments against structure
or
• correlation against API spectral data from peer reviewed literature,
preferable innovator publication (in tabulated form!!). Strongly
recommended
Physico-chemical properties
16 |
Active Pharmaceutical Ingredients
Properties: Compendial APIs
Physico-chemical and other relevant properties, e.g.
– Solubility in water (effect of pH), other solvents such as ether,
ethanol, acetone and dichloromethane
– pKa, partition coefficient
– Existence/absence of polymorphs and pseudo-polymorphs e.g.
solvates (with XRPD, DSC, IR)
• e.g. Rifampicin polymorphs I and II
• See Nevirapine (later in this presentation)
– Hygroscopicity e.g. Ethambutol hydrochloride in FDC tablet
– Particle size
17 |
Active Pharmaceutical Ingredients
Properties for Compendial APIs
Example: solubility of TB APIs
API
Water
CHCl3*
Ethanol
Rifampicin
Water: Slightly 1,2
pH 7.5: 0.3% 2
pH 5.3: 0.4% 2
pH 2.0: 10% 2
Freely 1,2
Slightly 2
Ethambutol 2HCl
50% 2
0.1% 2
20% 2
Ethambutol base
Sparingly 2
Very 2
Isoniazid
14% 1
0.1% 1
2% 1
Pyrazinamide
1.5% 1
0.7% 1
0.6% 2
1 Merck Index 13th ed
2
Pharmaceutical Codex 12th ed
* Dichloromethane has similar properties to chloroform as solvent, but preferred for safety
reasons
18 |
Active Pharmaceutical Ingredients
Properties APIs
Example: solubility protease inhibitors (mg/ml)
Medium
Saquinavir
Ritonavir
Indinavir
Nelfinavir
Amprenavir
Water
mesilate
2.2
0.001
sulfate
>100
mesilate
4.5
mesilate
0.19
pH 7.4
0.036
0.005
0.07
very low
0.06
pH 6.8
pH 6.5
0.19
0.073
pH 4.8
pH 4.0
pH 3.5
pH 2.6
19 |
Active Pharmaceutical Ingredients
0.3
0.007
60
0.5
4.5
Properties Compendial APIs
Pseudo-polymorphism nevirapine
Int. Ph. monograph Nevirapine (anhydrous & hemihydrate)
Identification test C
Carry out the examination as described under “Spectrophotometry
in the infrared region”.
–
–
20 |
For the anhydrous substance, the infrared (IR) absorption spectrum
is concordant with the spectrum obtained from anhydrous
nevirapine RS or with the reference spectrum of anhydrous
nevirapine
For the hemihydrate, the IR absorption spectrum shows a
characteristic sharp absorbance at about 3503 cm−1; after heating
the test substance for one hour at 140°C and cooling, the IR
absorption spectrum is concordant with the spectrum obtained from
anhydrous nevirapine RS or with the reference spectrum of
anhydrous nevirapine
Active Pharmaceutical Ingredients
Properties Compendial APIs
Pseudo-polymorphism nevirapine (2)
Interpretation of this IR identification test:
Nevirapine anhydrous (one test)
–
IR spectrum against nevirapine anhydrous RS
Nevirapine hemihydrate (two tests, conform to both)
1. IR spectrum shows signal at 3503 cm-1 (water) and
2.
Heat converts the hemihydrate to the anhydrous form
•
IR spectrum against nevirapine anhydrous RS
- ½H20
Nevirapine, ½H20
————>
Nevirapine
heat
The reaction is not reversible at room temperature
21 |
Active Pharmaceutical Ingredients
no O-H signal
22 |
Active Pharmaceutical Ingredients
4 000
10
3 000
1415.32
2 000
W av e num be rs (c m -1 )
789.12
1 000
761.66
621.49
697.56
829.44
803.62
436.32
655.88
551.88
540.26
499.65
523.67
1 000
462.39
576.06
710.87
999.24
975.13
965.33
956.63
830.56
794.26
464.43
780.82
767.11
844.92
819.45
894.68
1144.79
1168.40
698.40
434.50
588.58
711.86
500.03
548.23
619.51
652.23
939.89
1117.27
1107.16
1092.50
1071.57
1050.96
1027.00
998.51
979.36
1272.70
1244.44
1221.94
1295.94
1491.86
1459.55
1411.84
1381.78
1351.84
1600.74
1582.33
1654.00
959.84
60
941.75
1107.27
1091.16
1074.82
1048.30
1167.32
1153.13
40
1025.40
1258.94
1210.77
1950.21
2 000
885.03
1289.19
1243.06
1384.34
1354.95
30
2088.38
2065.49
3 000
1487.86
80
2320.66
40
1465.35
20
2916.77
2861.41
55
1568.92
50
3062.78
3007.45
2218.44
1983.68
2070.73
2599.59
2515.27
1961.46
1945.48
1913.05
70
1586.57
60
1927.40
(do not match)
3502.85
75
2583.59
2505.28
2456.46
Spectra not concordant
2698.58
4 000
2914.76
2861.26
45
3011.59
O-H signal (water)
1647.72
no crystal water
50
3124.51
3503 cm-1
3062.45
3193.26
Nevirapine ½H20
3294.95
%Trans mittanc e
3893.86
85
3189.89
Nevirapine anhydrous
%Trans mittanc e
IR-spectra
95
90
80
65
W av e num be rs (c m -1 )
5 00
11 0
10 0
90
70
5 00
Route(s) of synthesis
Scenarios:
API not described in BP, Int.Ph., JP,Ph.Eur., or USP (noncompendial APIs)
Specifications of raw materials and intermediates used in the
synthesis of non-compendial APIs
API described in BP, Int.Ph., JP, Ph.Eur.,
or USP (compendial APIs)
23 |
Active Pharmaceutical Ingredients
Route(s) of synthesis (cont.)
Requirements: The synthesis should
–
–
–
24 |
lead to the correct structure, stereochemistry and crystal
form & size (if relevant)
be well controlled and validated (GMP)
produce an API which meets acceptable standards of
quality, including limits of impurities (organic, inorganic,
residual solvents)
Active Pharmaceutical Ingredients
The information required for the synthesis of the API may depend on
25 |
Is a valid CEP is available? - no synthesis information
required. CEP must however have all appendices and
applicant to submit other info not covered by CEP
Is the quality of the API controlled by a monograph in an
acknowledged pharmacopoeia?
No official monograph is available for quality control
- Detailed information required e.g. Open Part of DMF (from API
manufacturer)
- Also signed declaration from API manuf that synthesis and purification
are as described in the dossier
Active Pharmaceutical Ingredients
Synthesis non-compendial APIs
A flow diagram of the synthesis process
including structures & stereochemistry of starting materials & intermediates;
reagents; catalysts; solvents
A full description of each step / process, including:
26 |
Reaction conditions (temp., time, moisture control, etc.)
Quantities of reagents/solvents
Size of production scale
Purification of intermediates
Final API purification method / crystallisation / solvent(s)
Reprocessing (has to be justified, validated)
Process controls
Validation of critical steps, e.g. aseptic processes
Discussion of (possible) process impurities
Organic, residual solvents and catalysts/inorganic
Active Pharmaceutical Ingredients
Specifications of raw materials and intermediates used in synthesis
Provide specifications for
starting materials and intermediates (if isolated)
reagents, solvents & catalysts
Class 1 solvents should not be used (ICH Q3C)
Benzene, Carbon tetrachloride, 1,2-Dichloroethane,
1,1-Dichloroethene & 1,1,1-Trichloroethane
Provide a declaration on the use/non-use of material of animal or
human origin (TSE)
Risk of Transmitting Animal Spongiform Encephalopathy Agents
(WHO TRS 908, Annex 1 or EMEA/410/01 Rev.2)
To limit impurities in the API (Safety reasons)
27 |
Active Pharmaceutical Ingredients
WHAT IS A STARTING MATERIAL?
Contributes an important structural part of the API
Available in free trade
Compound well defined in chemical literature (name, chemical
structure, chemical and physical properties, and impurity profile)
Synthesized by commonly known process
28 |
Active Pharmaceutical Ingredients
RE-DEFINITION OF STARTING MATERIAL
MARKS THE START OF THE MANUFACTURING
PROCESS DESCRIBED IN AN APPLICATION
Manufacturing steps before are not described
Manufacturing steps before need not be performed in accordance
with GMP
Changes in manufacturing steps before need not be reported to
Agency
EACH BRANCH OF A SYNTHESIS WILL BEGIN WITH
ONE OR MORE STARTING MATERIALS
29 |
Active Pharmaceutical Ingredients
INDINAVIR
30 |
Active Pharmaceutical Ingredients
CHEMICAL SYNTHESIS
•
Indinavir is a chiral molecule with 5 stereogenic centers
•
Only stereoisomer observed in the API is the 4-(R)-epimer.
•
It is stereoselectively prepared in six steps.
•
The enantiomeric purity of the API and other ingredients is
ensured by the route of manufacture and quality control on
intermediate products (starting materials and intermediate
indinavir free base) rather than a test for specific rotation.
31 |
Active Pharmaceutical Ingredients
CHEMICAL EQUIVALENCE (1)
The stereochemistry is well under control during the synthesis
Racemization after the synthesis is extremely unlikely
Formation of epimers cannot be excluded but should be detectable by
the purity tests applied.
Potential impurities from synthesis, stereoisomeric impurities and
degradants have been identified. Minimised or removed by control on
the reaction parameters and in-process controls
High humidity, which leads to formation of degradants, is avoided.
32 |
Active Pharmaceutical Ingredients
CHEMICAL EQUIVALENCE (2)
The API is very pure
The limit for any single impurity is not more than 0.1 %
limit for the sum of all impurities is not more than 0.5 %
Due to the high doses to be given in clinical use (> 2 g/day),
the qualification threshold as defined in the ICH guideline on
impurities, is 0.05 %.
33 |
Active Pharmaceutical Ingredients
PHYSICOCHEMICAL EQUIVALENCE
Indinavir Sulfate Ethanolate
Freely Soluble In Aqueous Solutions
PARTICLE SIZE Not Critical
No POLYMORPHISM
POOR FLOWABILITY
Relatively Loose Bulk Density
34 |
Active Pharmaceutical Ingredients
API STABILITY TESTS
Indinavir is highly hygroscopic at relative humidity above 60
%
In the presence of moisture and/or elevated temperatures, the
API undergoes conversion to an amorphous material or to a
hydrate crystal form and to the formation of degradation
products i.e. lactone and several unidentified impurities occur
HVAC SYSTEM SHOULD MAINTAIN A RELATIVE
HUMIDITY OF ≤ 33% AT 25OC
35 |
Active Pharmaceutical Ingredients
NEVIRAPINE
CHEMICAL STRUCTURE
H3C
N
37 |
Active Pharmaceutical Ingredients
O
H
N
N
N
CHEMICAL STRUCTURE
Nevirapine does not contain an assymetric carbon
atom (a chiral centre)
The nitrogen in position 11 shows weekly basic
properties
Other functional groups are not very reactive under
everyday manufacturing environmental conditions
38 |
Active Pharmaceutical Ingredients
CHEMICAL INFORMATION
C15H14N4O (anhydrate for tablets)
266.30
C15H14N4O·1/2 H2O (hemihydrate
for oral suspension)
275.35
CAS number: 129618-40-2
NEVIRAPINE is lipophilic (partition coefficient 83) and is
essentially nonionized at physiologic pH. As a weak base
(pKa 2.8), NEVIRAPINE is known to be soluble at acidic pH
values.
39 |
Active Pharmaceutical Ingredients
PHYSICO-CHEMICAL INFORMATION
Aqueous solubility (anhydrate) (90 μg/ml at 25°C).
NEVIRAPINE anhydrous is a white to off-white
crystalline powder.
No potential toxicity was found in intermediates found in
the synthesis of NEVIRAPINE
NEVIRAPINE is milled in order to obtain an acceptable
particle size distribution.
40 |
Active Pharmaceutical Ingredients
SPECIFICATION, STABILITY
Innovator results showed that Nevirapine is highly stable even
under stressed conditions over a 24 month study period
No degradants were detected and all the results remained
within the specifications.
41 |
Active Pharmaceutical Ingredients
DESK CONCLUSION
Critical API parameters:
42 |
Particle size of the micronized drug substance
Active Pharmaceutical Ingredients
API specifications
API not described in BP, Int.Ph., JP, Ph.Eur., or USP (non-compendial
APIs)
API described in BP, Int.Ph., JP, Ph.Eur.,
or USP (compendial APIs)
General note
An API has only one set of specifications applicable at release
and throughout the re-test period
–
43 |
an FPP may have two sets of specifications – release and shelf-life
Active Pharmaceutical Ingredients
Specifications: Non-Compendial APIs
ICH Q6A (new APIs and products) – for instance:
Requires justification for proposed specifications
Impurities to be characterised and limits set
synthesis and degradation according to ICH Q3A(R)
residual solvents according to ICH Q3C
Analytical methods with validation
Preparation and potency determination/specification of primary
and secondary (working) standards, with CoAs
Valid CoAs for at least 2 batches
44 |
Active Pharmaceutical Ingredients
Non-compendial APIs
Typical set of specifications
Appearance/description
Identification (at least one specific, e.g. IR spectrum)
Moisture content (or LOD: moisture + residual solvents)
Impurities
- Related organic substances (synthesis or degradation)
specified
unspecified and
total organic impurities
- Inorganic impurities, including catalysts
- Residual solvent(s)
Assay
Additional parameters important for specific API
45 |
such as particle size, polymorphic form, microbial limits
Active Pharmaceutical Ingredients
Specs: Compendial APIs
The current monograph always applicable
Additional critical specifications that are not included in
monograph e.g.
–
–
–
particle size & polymorphic form
synthesis related impurities resulting from specific process which
may be additional to monograph
residual solvents (specific to process)
Valid CoAs for at least 2 batches required
CEP normally states tests additional to the monograph
–
46 |
e.g. residual solvents & impurities
Active Pharmaceutical Ingredients
IMPURITIES
Extraneous contaminant (foreign substances)
Toxic impurities
Concomitant components
Signal impurities
47 |
Active Pharmaceutical Ingredients
Classes of Impurities
Organic
Inorganic
Residual solvents
48 |
Active Pharmaceutical Ingredients
Organic Impurities
May arise during manufacturing process and storage
Starting materials
By products
Intermediates
Degradation products
Reagents, ligands and catalysts
49 |
Active Pharmaceutical Ingredients
Inorganic Impurities
May be from manufacturing process and are normally
known and identified:
Reagents, ligands and catalysts
Heavy metals
Inorganic salts
other materials (e.g. filter aids, charcoal etc.)
50 |
Active Pharmaceutical Ingredients
Solvents
Organic or inorganic liquids used during the manufacturing
process
Toxicity generally known, therefore controls achievable
Limits to be based on pharmacopoeial standards or known
safety data
51 |
Active Pharmaceutical Ingredients
IMPURITIES
Identified impurity
Unidentified impurity
Specified impurity
Unspecified impurity
52 |
Active Pharmaceutical Ingredients
IMPURITY THRESHOLDS
Maximum
daily dose
<= 2g/day
Reporting Identification Qualification
threshold
threshold
threshold
0.10% or
0.15% or
1mg/day
1mg/day
0.05%
intake
intake
>= 2g/day
53 |
Active Pharmaceutical Ingredients
0.03%
0.05%
0.05%
IMPURITY EQUIVALENCE
No new impurity is observed in the intermediate
above 0.1%
No new impurity is observed in api above the
qualification threshold
Each existing impurity is within its stated limit
Total impurities are within the stated limit
54 |
Active Pharmaceutical Ingredients
IMPURITY EQUIVALENCE
Each existing residual solvent is within its stated limit
New residual solvents, in either an intermediate or the
api, are at or below the levels recommended in the ich
guide
55 |
Active Pharmaceutical Ingredients
IMPURITY EQUIVALENCE
Ideally, impurities should be evaluated in isolated
intermediates immediately following the process step in
which they are produced
The impurity search can be extended to the next
downstream intermediate and the evaluation process
repeated until the final intermediate, even to the api
56 |
Active Pharmaceutical Ingredients
Stability testing
Stress testing of API (forced degradation) helps
to identify the likely degradation products and pathways
to establish stability of the molecule
To verify specificity of stability assay method
Diode array detection for API peak purity !
Stability testing (regulatory) to provide evidence on
57 |
how the quality of an API varies with time
under the influence of a variety of environmental factors such as temperature,
humidity, and light; and
to establish a re-test period for the API and
to recommended storage conditions
Active Pharmaceutical Ingredients
Stress testing (forced degradation)
Typical conditions
The conditions should
partially (e.g. 10-30%)
decompose the API to
primary degradation
products
Conditions can be
changed to get required
degree of degradation
**
Temperature should not
come closer than 10°C
from melting point
58 |
Active Pharmaceutical Ingredients
Stress factor
Conditions (e.g.)
Humidity
≥ 75% RH (solid)
Heat **
≥ 60°C (solid)
Heat
water
Acid
0.1 M HCl
Base
0.1 M NaOH
Oxidative
3% H2O2
Photolytic
ICH Q1B
Metal ions
(optional)
0.05 M Fe2+ or Cu2+
Stress testing (forced degradation)
Literature
Literature information and/or CEP
–
–
in support of and/or
to replace experimental data
Examples of literature information
1.
2.
3.
59 |
Rifampicin (earlier slides)
Oxidation, hydrolysis, light sensitivity
Indinavir sulfate (earlier slide)
Intra-molecular reaction – heat, moisture, acid, base
Efavirenz (see next slides)
Hydrolysis – pH dependent
Active Pharmaceutical Ingredients
Stress testing (forced degradation)
Efavirenz (1)
Non-hygroscopic
4 Polymorphs
• Form 1 pharmaceutical
(EPAR Sustiva®)
Hydrolysis main degradation
– pH dependent
– Maximum stability at pH 4
– 2 Degradants isolated
• structures elucidated
– Pathways postulated
Maurin, Pharm. Res. 19, 517 (2002)
60 |
Active Pharmaceutical Ingredients
Stress testing (forced degradation)
Efavirenz (2)
The data (generated at 60°C) shows that
61 |
–
Efavirenz is quite stable
–
–
Maximum stability at pH 4 (Suspension possible?)
Carbon dioxide formation
(30 mg/ml solution, 100 ml bottle:
1% decomposition ≈ 2 ml CO2
Active Pharmaceutical Ingredients
Efavirenz main route of
degradation
Maurin (2002)
2nd route
+
2
62 |
Active Pharmaceutical Ingredients
1
CO2 (g)
Important Elements
The API must be of required structure & stereochemistry
The physical properties must be well understood, e.g.
–
The synthesis process must be according to GMP to
–
–
63 |
hygroscopicity, crystal properties and solubility
consistently produce an API of required chemical and physical
quality
limit impurities according to defined standards
Active Pharmaceutical Ingredients
Important Elements (2)
The set of specifications should
64 |
be based on validated analytical methods
with appropriate acceptance criteria
to which an API should conform to be considered acceptable
for its intended use throughout the retest period in the
proposed packaging
Active Pharmaceutical Ingredients