Tablet Components and Additives Comprehensive Study Notes

Active Pharmaceutical Ingredients (APIs)

Two Broad Classes of APIs in Tablets:

Insoluble drugs intended to exert a local effect in the GIT such as Antacids, Polymeric resins – Non-systemic drugs
Soluble drugs intended to exert a systemic drug effect following their dissolution in the gut and subsequent absorption

API Characteristics That Can Affect Formulation:

Particle Size

Affects dissolution rate, flow properties, and content uniformity

Solubility

Determines dissolution characteristics and bioavailability

Crystalline Structure

Impacts stability, compressibility, and dissolution properties

Polymorphic Form

Different crystalline forms with varying properties

Bulk & Tapped Density

Affects flow properties and tablet weight uniformity

Non-active Ingredients/Excipients

Definition:

A pharmaceutical excipient is defined as an inactive ingredient or any component other than the active ingredient added intentionally to the medicinal formulation or everything in the formulation except the active drug. Pharmaceutical excipients are also called additives, pharmaceutical ingredients, or inactive pharmaceutical ingredients.

Role of Excipients:

                Ease of administration to the target patient population(s) by the intended route
Improved dosing compliance
Consistency and control of drug bioavailability
To enable bioavailability
Improved API stability including protection from degradation
To ensure a robust and reproducible physical product

            

Criteria for Selection of Additives/Excipients:

Criterion	Description
Safety	No harmful or toxicological effect and listed as GRAS (generally recognized as safe)
Stability	Good stability with drug – excipient incompatibility and by any impurities in the excipients
Analytical Compatibility	No interference in quality validation and analytical tests
Regulatory Compliance	Satisfaction of regulatory issues and guidelines in all countries where the product is to be marketed
Accessibility & Cost	Ease of accessibility, distribution, and economical cost
Environmental Considerations	Satisfaction for environmental issues
Physiological Inertness	Be physiologically inert
Compatibility	Be physically and chemically compatible with the active substance and the other excipients in the formulation
Microbiological Quality	No unacceptable microbiological burden

Classification of Tablet Additives

Two Major Classifications of Additives:

1. Compression Characteristics Affectors

Affect the compressional characteristics of the tablet:

Diluents - Increase bulk of tablet
Binders and Adhesives - Provide cohesiveness
Lubricants - Reduce friction
Antiadherents - Prevent sticking
Glidants - Improve flow

2. Biopharmaceutics & Stability Affectors

Affect the biopharmaceutics, chemical and physical stability & marketing considerations:

Disintegrants - Facilitate breakup
Colors - Aesthetic appeal
Flavors - Taste improvement
Sweeteners - Taste enhancement
Buffers - pH control

Diluents/Fillers

Definition:

Diluents are the inert substance added to increase the bulk of the tablet.

Objectives of Incorporating Diluents:

Size Adjustment: To produce tablets of reasonable size
Bulk Increase: Diluent increases the bulk to make the tablet a practical size for compression
Chewable Tablets: Certain diluents (mannitol, lactose, sorbitol, sucrose, inositol) when present in sufficient quantity can impart properties that help in disintegration of the tablet in the mouth by chewing
Flow and Compression: Diluents used for direct compression formulas give the powder mixture necessary flowability and compressibility
Release Control: To delay or control the rate of release of drug from the tablet

Characteristics of Ideal Diluents:

Nontoxic and acceptable to drug-regulatory agencies worldwide
Commercially available in acceptable grade in all manufacturing countries
Cheap compared to the active ingredients
Physiologically inert
Chemically stable alone and/or in combination with drug(s) and other components
Free of unacceptable microbiologic "load"
Color-compatible
No negative effects on bioavailability of the drug(s)

Different Types of Diluents:

Category	Examples
Sugars	Dextrose, Lactose, Sucrose, Mannitol, Sorbitol, Inositol
Polysaccharides	Starches, Modified starch (e.g. Pregelatinized Starch, Starch 1500, Sta-RX 1500, Celutab etc.)
Cellulose	Cellulose, Cellulose derivatives, Microcrystalline cellulose (MCC)
Inorganic Compounds	Calcium phosphate dihydrate, Calcium sulfate dihydrate, Calcium lactate trihydrate, Calcium carbonate, Magnesium carbonate, Magnesium oxide

Key Diluents in Detail

Lactose:

Lactose is the most widely used diluent in tablet formulation.

Different Grades of Lactose:

Lactose Monohydrate
Anhydrous Lactose
Lactose (Fine) #100 mesh, #200 mesh
Lactose Coarse (suitable for direct compression)
Spray-dried Lactose

Important Note:

Lactose may discolor in the presence of amine drug bases or salts and alkaline lubricants. Brownley and Lachman reported that care must be taken in using spray-dried lactose since it tends to become brown due to the presence of 5-(hydroxymethyl)-2-furaldehyde, when combined with moisture, amines, phosphates, lactates, and acetates.

The employment of neutral or acid lubricants such as stearic acid appears to retard the discoloration, while alkaline lubricants (e.g., Magnesium stearate) accelerate the darkening. Bases as well as drugs which release radicals (e.g., amino salts) can bring about this browning, known as the Maillard reaction.

Microcrystalline Cellulose (MCC):

Trade Name: Avicel – is a directly compression material

Two Grades Available: PH 101 (powder) and PH 102 (granules)

Advantages: Widely used as diluent and disintegrating agents

Starch:

Starch may come from corn, wheat or potatoes and is used as a tablet diluent. It is one of the most widely used diluents in tablet formulation.

Types:

The USP grade of starch has poor flow and compression characteristics and possesses a high typical moisture content of between 11 and 14%
Specially dried types of starch have a standard moisture level of 2 to 4% (available at a premium price)
Directly compressible starches are now available commercially (e.g., Sta-Rx1500, Starch 1500)

Properties:

Free-flowing
Directly compressible
Used as a diluent, binder, disintegrating agent
Also used as self-lubricating
Contains about 10% moisture and is prone to softening when combined with excessive amount (more than 0.5%) of Magnesium Stearate

Hydrolyzed Starches:

Two hydrolyzed starches are Emdex and Celutab, which are basically 90 to 92% Dextrose and about 3 to 5% Maltose.

Properties:

Free-flowing and directly compressible
Used in place of Mannitol in chewable tablets because of their sweetness and smooth feeling in the mouth
Contain about 8 to 10% moisture and may increase in hardness after compression

Binders

Definition:

Agents used to impart cohesive qualities to the powdered material are referred to as binders or granulators.

Objectives of Incorporating Binders:

Cohesiveness: Impart cohesiveness to the tablet formulation (both direct compression and wet-granulation method) which ensures the tablet remaining intact after compression
Flow Improvement: Improve the free-flowing qualities by the formation of granules of desired size and hardness

Selection Criteria:

The primary criterion when choosing a binder is its compatibility with the other tablet components. Secondarily, it must impart sufficient cohesion to the powders to allow for normal processing (sizing, lubrication, compression, and packaging), yet allow the tablet to disintegrate and the drug to dissolve upon ingestion, releasing the active ingredients for absorption.

Examples of Typical Granulating Systems:

Material	System Normally Used (% of granulating)	Concentration Used (% of formula)
Acacia	10-25	2-5
Cellulose derivatives	5-10	1-5
Gelatin	10-20	1-5
Gelatin-acacia	10-20	2-5
Glucose	25-50	2-25
Polymethacrylates	5-15	5-20
Polyvinylpyrrolidone (PVP)	3-15	2-5
Starch paste	5-10	1-5
Sucrose	50-75	2-25
Sorbitol	10-25	2-10
Pregelatinized starch	2-5	1-10
Tragacanth	3-10	1-4
Sodium alginate	3-5	2-5

Key Binders in Detail:

Starch Paste:

Starch as a paste forms tablets which are generally soft and brittle. It requires heat to facilitate manufacture. Depending on the amount of heat employed, starch undergoes hydrolysis to dextrin and then to glucose. Thus, care in preparation of starch paste is necessary to produce a correct and consistent ratio of starch and its hydrolysis products, as well as to prevent charring.

Polyvinylpyrrolidone (PVP):

PVP is an alcohol-soluble material which is used in concentrations between 3 and 15%. Granulations using a PVP-Alcohol system process (granulate) well, dry rapidly, and compress extremely well. PVP finds particular application in multivitamin chewable formulations where moisture sensitivity can be a problem.

Hydroxypropylmethylcellulose (HPMC) and Hydroxypropylcellulose (Klucel):

These are soluble in various organic solvents or cosolvent systems, as well as water. L-HPC is a low molecular weight, cross-linked form of Klucel. It functions not only as a tablet binder but also a tablet disintegrant. Unlike Klucel, it is not soluble in water. It has tremendous swelling capability which accounts for its disintegration property. L-HPC may be used in both direct-compression as well as wet granulation tablet formulas. Various grades of L-HPC may be used depending on whether the tablet is to be wet-granulated or directly compressed.

Pregelatinized Starch:

Pregelatinized starch (National 1551 and Starch 1500) can be blended dry with the various components of a tablet formula and activated with water at the desired time of granulation. In a direct-compression formulation, no more than 0.5% Magnesium Stearate should be used to prevent softening of the tablets.

Lubricants, Antiadherents and Glidants

Lubricants:

Objectives:

Prevent adhesion of the tablet material to the surface of dies and punches
Reduce inter-particular friction; improve the rate of flow of tablet granulation
Facilitate ejection of the tablets from the die cavity

Examples: Talc, Magnesium Stearate, Calcium Stearate, Stearic Acid, Hydrogenated Vegetable Oils and Polyethylene Glycols (PEG)

Lubricants are included to reduce the friction during tablet ejection between the walls of the tablet and the wall of the die in which the tablet was formed.

Antiadherents:

Antiadherents are used for the purpose of reducing the sticking or adhesion of any of the tablet ingredients or powder to the faces of the punches or to the die wall.

Glidants:

Glidants are intended to promote flow of the tablet granulation or powder materials by reducing the friction between the particles.

Water Insoluble Lubricants:

Lubricant	Percentage
Stearates (Mg, Ca & Na)	0.25-2
Stearic acid	0.25-2
Sterotex	0.25-2
Talc	1-5
Wax	1-5

Water Soluble Lubricants:

Lubricant	Percentage
Boric acid	1
Sodium benzoate	5
Sodium acetate	5
Sodium oleate	5
PEG 4000, 6000	1 – 4

Antiadherent Materials:

Materials	Usual Range (%)
Talc	1-5
Corn starch	3-10
Cab-O-Sil	0.1-0.5
Syloid	0.1-0.5
DL-leucine	3-10
Sodium Lauryl sulphate	< 1
Metallic Stearates	< 1

Glidant Materials:

Materials	Usual Range (%)
Talc	5
Cab-O-Sil	0.1-0.5
Syloid	0.1-0.5
Aerosil 200	1-3

Disintegrants

Purpose:

The purpose of a disintegrant is to facilitate the breakup of a tablet after administration in the GIT.

Addition Methods:

Disintegrating agent may be added:

Prior to granulation (Intra-granular)
During the lubrication step prior to compression (Extra-granular)
At both processing steps

Role of Disintegrants:

Disintegrating agents are substances included in tablet formulations and in some hard shell capsule formulations to promote moisture penetration and dispersion of the matrix of the dosage form in dissolution fluids. An oral solid dosage form should ideally disperse into the primary particles from which it was prepared.

Characteristics of Ideal Disintegrant:

Poor solubility
Poor gel formation
Good hydration capacity
Good compressibility and flow properties
No tendency to form complexes with the drugs

Factors Affecting Action of Disintegrants:

Percentage of disintegrants present

Types of substances present

Combination of disintegrants

Presence of surfactants

Hardness of the tablets

Nature of Drug substances

Starch as Disintegrant:

Traditionally, starch has been the disintegrant of choice in tablet formulations, and it is still widely used. Starch generally has to be present at levels greater than 5% to adversely affect compactibility, especially in direct compression. Moreover, intra granular starch in wet granulations is not as effective as dry starch.

Mode of Action:

Starch has a great affinity for water and swells when moistened, thus facilitating the rupture of the tablet matrix. Others have suggested that the spherical shape of the starch grains increases the porosity of the tablet, thus promoting capillary action.

Concentration: Normally 5% w/w is suggested. For rapid disintegration 10 – 15% w/w may be taken.

Superdisintegrants:

                Three Major Types:
                Crosscarmelose - cross linked cellulose
Crospovidone - cross linked polyvinyl pyrrolidone
Sodium starch glycolate - cross linked starch

            

Mode of Action:

Superdisintegrant	Mode of Action
Croscarmelose	Swelling (4 to 8 fold in less than 10 seconds)
Crospovidone	Wicking or capillary action
Sodium starch glycolate	Swelling (7 to 12 folds in less than 30 seconds)

Classification of Superdisintegrants:

Type	Description	Trade Names
Modified Starches (Sodium starch glycolate, NF)	Sodium carboxy methyl starch; the carboxy methyl groups induces hydrophilicity and cross-linking reduces solubility	Explotab®, Primojel®, Tablo®
Modified Cellulose (Croscarmellose, NF)	Sodium carboxymethyl cellulose which has been cross-linked to render the material insoluble	AcDiSol®, Nymcel ZSX®, Primellose®
Cross-linked PVP (Crospovidone, NF)	Cross-linked poly vinyl pyrrolidone; cross-linking render the material insoluble in water	Crospovidone M®, Kollidon CL®

Colouring Agents

Objectives of Using Colors:

                Impart color to the tablets
Make the tablet more aesthetic in appearance
Help the manufacturer to identify the product during its preparation

            

Regulatory Note:

All colorants used in pharmaceuticals must be approved and certified by the FDA (Food & Drug Administration). Dyes are generally listed as FD&C (Food, Drug & Cosmetic Dyes) and D&C (Drug & Cosmetic Dyes).

Common Colorants:

Colour	Other Names	Color Index (CI, 1971)
D&C Red 22	Eosin Y	45380
FD&C Yellow 5	Tartrazine	15985
FD&C Yellow 6	Sunset Yellow FCF	19140
FD&C Blue 1	Brilliant Blue FCF	42090
FD&C Blue 2	Indigocarmine	73015
FD&C Green 3	Fast Green FCF	42035
Caramel	Burnt sugar	-
Titanium dioxide	-	77891

Forms of Colorants:

Dyes

Dyes are dissolved in the binding solution prior to the granulating process. However, during drying their color may migrate to the surface and may produce mottling of the tablet. Another approach is to adsorb the dye on starch or calcium sulfate from its aqueous solution; the resultant powder is dried and blended with other ingredients.

Color Lakes

Color lakes are dyes which are adsorbed onto a hydrous oxide of a heavy metal (like aluminium) resulting in an insoluble form of the dye.

Flavours and Sweeteners

Flavours:

Flavours are usually limited to chewable & effervescent tablets or other tablets intended to dissolve in the mouth.

Purposes:

Improve acceptability among pediatric and geriatrics patients
Enhance patient compliance

Application Methods:

Added to tablet granulations in solvents
Dispersed on clays and other adsorbents
Emulsified in aqueous granulating agents (i.e., binder)

Concentration: Should be used only in the concentration range of 0.5 to 0.75% w/v.

Examples: Citrus oil, Cardamom tincture, etc.

Sweeteners:

Mainly used in chewable, effervescent & mouth dissolving tablets for improvement of taste.

Common Sweeteners:

Sweetener	Properties
Sugar	Natural sweetener
Mannitol	72% as sweet as sugar, cooling & mouth filling effect
Saccharin	Artificial sweetener (500 times sweeter than sucrose). Disadvantages: bitter after taste, potential carcinogenic concerns
Cyclamate	Either alone or with saccharin – it is banned
Aspartame (Searle)	Widely replacing saccharin & approved by FDA. Disadvantage: lack of stability in presence of moisture & discoloration in presence of ascorbic acid & tartaric acid

Co-processed Excipients

Definition:

Co-processed excipients are mixtures of one or more excipients used in combination to improve their characteristics.

Advantages:

                Reduces the number of excipients in a formulation
Reduces the overall cost and time for processing
Improves functionality and performance

            

Examples of Co-processed Excipients:

Co-processed Excipients	Brand Name
Cellulose and Lactose	Cellactose
Lactose and MCC	Microcelac 100
Lactose and Maize starch	Starlac
Lactose and PVP	Ludipress
MCC and Sodium CMC	Avicel CL-611

Formulation Strategy:

The selection and combination of appropriate excipients is critical to developing a successful tablet formulation. Understanding the properties, functions, and interactions of each excipient type allows formulators to create robust, effective, and patient-friendly tablet products.