Polysaccharides (Sugars, Gums) Used

Polysaccharides (Sugars, Gums) Used in Cosmetics
Polysaccharides form another important group of
polymers. As the name suggests, polysaccharides
are composed of multiple saccharides (sugars)
forming a large, branched or unbranched chain.
The vast majority of polysaccharides used in
cosmetics are natural or semi-natural. Based on
their unique multifunctionality they play a very
important role in cosmetic formulation technology.
For example, polysaccharides act as thickeners,
suspending agents, hair conditioners, moisturizers,
emulsifiers, emollients, and even wound-healing
agents. However, this multifunctionality of
polysaccharides may sometimes make formulation
difficult as, for example, a polysaccharide that
conditions may do so at the expense of its
thickening ability.
Traditionally, polysaccharides are classified based
on their electrochemical charges (see table below).
Classification of Polysaccharides
Anionic Polysaccharides
Natural: alginic acid, pectin, xanthan gum,
hyaluronic acid, chondroitin sulfate, gum
arabic, gum karaya, gum tragacanth
Semi-Natural: carboxymethyl-chitin, cellulose gum
Cationic Polysaccharides
Natural: chitosan
Semi-Natural: cationic guar gum, cationic
hydroxyethylcellulose (HEC)
Nonionic Polysaccharides
Natural: starch, dextrins, guar gum
Semi-Natural: cellulose ethers (e.g. hydroxyethylcellulose, methylcellulose, nitrocellulose)
Amphoteric Polysaccharides
Semi-Natural: carboxymethylchitosan, Nhydroxy-dicarboxyethyl-chitosan, modified
potato starch
Hydrophobic Polysaccharides
Semi-Natural: cetyl hydroxyethylcellulose,
poly-quaternium 24
Anionic Polysaccharides (negative charge) The
cosmetically interesting anionic polysaccharides
are predominantly comprised of naturally occurring
materials. A major compound in this group is
xanthan gum. It occurs on the cell walls of bacteria
and is isolated by bacterial fermentation. In water
xanthan polymerizes to form viscous liquids with
crystals with the unique ability to form emulsifierfree suspensions. Although the viscosity
of xanthan solutions is influenced by cationic salts,
xanthan does not require salts to build a viscous
solution since it forms a rigid backbone that is
remarkable stable at increasing temperatures.
Xanthan also helps to reduce the quantity of
primary emulsifiers. Due to these properties
xanthan gum is widely used as thickening agent in
the cosmetic industry.
Hyaluronic acid and chondroitin sulfate are two
other major components among anionic polysaccharides. Both of them are primarily used as
moisturizer based on their great water-binding
capacity (see also Newsletter No. 17, November
2005).
Gum arabic, gum karaya, and gum tragacanthis are
some of the oldest and commerically wellestablished anionic polysaccharides. They are
isolated from the sap of specific trees and bushes.
Gum arabic consists of a chain of galactose sugars.
Because of its low molecular weight, gum arabic is
mainly used in applications where high levels of
sugar solids are desired without significant viscosity
buildup. The maximum viscosity effect occurs at ph
6, but disappears quickly at higher or lower ph
values. Gum arabic dissolves in water and can bind
fat particles. It is thus classified an emulsifier. It is of
note that anionic polysaccharides are only
compatible with anionic, nonionic or amphoteric
surfactants (e.g. sulfosuccinate, polyglucose or
cocamidopropyl betaine), but not cationic surfactants like quaternium-containing agents (used as
conditioners). For example, the addition of
quaternium 87 to a solution containing xanthan gum
will make the xanthan to flocculate and settle out of
solution.
Cationic Polysaccharides (positive charge) The
cationic polysaccharides of cosmetic interest
consist mainly of synthetically altered polyglycans.
They have the unique advantage to bind tightly to
proteins (negatively charged) of the human skin
and hair. Cationic polysaccharides have therefore
been found to be very useful as film-forming and
damage control agents in conditioning hair and skin
preparations. Cationic polysaccharides are also
widely used in hair fixative formulations.
The two most used cationic polysaccharides are
cationic hydroxyethylcellulose (HEC) and cationic
guar gum. There are two major cationic HEC
available: HEC 27 (polyquaternium 10) and HEC
28 (polyquaternium 4). Both are widely used as
thickener and hair repairing agents for bleached,
i.e. heavily damage hair. The thickening effect
depends largely on the molecular weight of the
cationic HEC. The higher the molecular weight, the
more intense is the thickening effect. Cationic guar
gum has very similar properties to cationic HEC as
it thickens and repairs damaged hair cuticles. One
of guar gum’s distinctive features, however, is the
lubricious, creamy feel it lends to the formulations.
Nonionic Polysaccharides (no charge) Nonionic
polysaccharides are not charged and thus less
affected by negatively or positively charged
compounds as surfactants. Starch as one of the
most used and least expensive natural nonionic
polysaccharides is mainly used as thickener. By the
addition of inorganic thickeners (e.g. bentonite) the
thickening effect of starch can be increased
significantly. A disadvantage of starch is that the
solutions become hazy. Guar gum, another nonionic
polysaccharide, has found broader appeal as a
natural thickener. Guar is isolated from the seeds of
various bean-growing plants and consists of two
sugars, mannose and galactose. Together with
metal ions (e.g. borate) guar gum is able to create
thick gels if the pH does not become acidic. Seminatural nonionic polysaccharides are mainly ethers
of cellulose or guar-based materials like hydroxyethylcellulose, methylcellulose, nitrocellulose, or
hydroxypropylguar. They are used either as
thickeners, film-formers or nail polishers.
Amphoteric Polysaccharides (2 charges)
Amphoteric polysaccharides carry both positive and
negative charges on the same molecule. There are
very few natural amphoteric polysaccharides barely
used in cosmetics. Similarly, the semi-natural
amphoteric polysaccharides, as carboxymethylchitosan or hydroxydicarboxyethylchitosan are
relatively unknown and underutilized in cosmetics.
They are challenging to formulate as they can
change their solubility and show complex behaviours in the presence of surfactants or salts.
Hydrophobic Polysaccharides
Hydrophobically modified (HM) polysaccharides
are of increasing interest in cosmetics. By attaching
lipophilic groups to the polysaccharides they
become less water-loving and show new, often
unusual thickening characteristics. For example,
the thickening effect of HM-HEC is no longer
dependent on water but on the concentration of
surfactant which is a great advantage to formulate
fixative gels or hair sprays.