Indian Patents
Title of Invention

A BILIQUID FOAM
Abstract A biliquid foam comprising from 10% to 98% by weight of a non-polar liquid other than a fuel and from 2 to 88% by weight of a continuous phase polar liquid comprising a C1-C4 alcohol, a liquid polyethylene glycol, ethylene glycol or propylene glycol, or mixtures thereof, in an amount of at least 65% by weight, relative to the weight of the continuous phase, wherein the biliquid foam is stabilized with an amount of from 0.05% to 2% by weight based on the total formulation of a surfactant which is selected from castor oil/poly(alkylene glycol) adducts containing from 20 to 50 alkoxy groups, a C8-C24 fatty acid or hydrogenated castor oil/poly(alkylene glycol) adducts containing from 20 to 60 alkoxy groups, or mixtures thereof. A stable dispersion having a content of at least 65% by weight with regard to C1-C4 alcohol, liquid polyethylene glycol, ethylene glycol or propylene glycol which dispersion comprises from 1-80% by weight of a biliquid foam and from 99-20% by weight of an aqueous gel.
Full Text A BILIQUID FOAMS

The present invention relates to biliquid foams with a
high alcohol content and to products which are formulated
therefrom.
Biliquid foams are known in the art in which small
droplets of a non-polar liquid such as an oil are
encapsulated in a surfactant-stabilized film of a
hydrocarbon bonded liquid, such as water, and separated from
one another by a thin film of the hydrogen bonded liquid.
The water or other hydrogen bonded liquid thus forms the
continuous phase in biliquid foam compositions.
US-A-4486333 to Sebba discloses a method for the
preparation of biliquid foam compositions which may comprise
the non-polar liquid in a total amount of about 60% to about
98% by volume, the hydrogen bonded liquid constituting the
balance. The polar liquid may comprise a petroleum
derivative, paraffin or a liquid halogenated hydrocarbon.
The biliquid foam composition prepared comprising 96% by
volume methanol and 4% by volume water had a limited
stability of only several days.
Biliquid foams are disclosed in the following
literature references by Sebba:
"Biliquid Foams", J. Colloid and Interface Science, 40
(1972) 468-474; and "The Behaviour of Minute Oil Droplets
Encapsulated in a Water Film", Colloid Polymer Sciences, 257
(1979) 392-396.
WO 97/32559 discloses a stable dispersion comprising an
oil-based biliquid foam and an aqueous gel which is suitable
for use in cosmetics, pharmaceuticals and other industries.
This patent specification does not describe the use of high
levels of alcohols in the compositions.
US Patent No. 4999198 disclosed a biliquid foam (or
polyaphron) having a continuous aqueous phase and a disperse
phase in which a drug is carried in the disperse phase.
This patent does not disclose the use of alcohol in the
aqueous phase.
There is a need to generate aqueous products with high
levels of alcohol, in particular in the cosmetic and
personal care markets. This need is not, however, addressed
by conventional emulsion science because of the instability
of emulsions containing high levels of alcohol in the
aqueous phase. There is also a need to generate topical
oil-based products with a high level of alcohol, which
increases skin permeability, but which products do not
suffer from the disadvantage of the resulting skin dryness.
We have now found that high levels of alcohol can be
incorporated into biliquid foams by formulating the
compositions using particular selected surfactants. We have
also found that these biliquid foams can be formulated with
structuring agents, such as aqueous gels, to give
compositions with a desired rheology.
Accordingly, the present invention provides a biliquid
foam comprising or consisting of from 10% to 98% by weight
of a non-polar liquid other than a fuel and from 2 to 88%,
preferably 2 to 87%, by weight of a continuous phase polar
liquid comprising a C1 - C4 alcohol, a liquid polyethylene
glycol, ethylene glycol or propylene glycol, or mixtures
thereof, in an amount of at least 65% by weight relative to
the weight of the continuous phase, wherein the biliquid
foam is stabilized with an amount of from 0.05% to 2% by
weight, preferably 0.5% to 2% by weight, based on the total
formulation of a surfactant which is selected from castor
oil/poly (alkylene glycol) adducts containing from 20 to 50
alkoxy groups, a C8-C24 fatty acid or hydrogenated castor
oil/poly (alkylene glycol) adducts containing from 20 to 60
alkoxy groups, or mixtures thereof.
The polar liquid is preferably aqueous and comprises
from 65% to 99% by weight of the C1-C4 alcohol, liquid
polyethylene glycol, ethylene glycol or propylene glycol, or
mixtures thereof. The preferred C1-C4 alcohol for use in
the invention is ethanol.
The liquid polyethylene glycol is a polyethylene glycol
which is liquid at room temperature (22°C). It may, for
example, contain from 1 to 12 ethylene oxide units or may,
for example, have a molecular weight of up to 600.
The particular classes of surfactant used in the
present invention have been selected for use because of
their ability to assist in the preparation of the biliquid
foam compositions and because they impart good stability
upon the majority of the biliquid foam compositions of the
present invention prepared using them. The castor
oil/poly(alkylene glycol) adducts generally impart a
stability of up to 45 days, whilst the hydrogenated castor
oil/poly(alkylene glycol) adducts generally impart a good
long term stability of from 30 to 90 days.
The preferred classes of surfactants for use in the
present invention are hydrogenated castor oil/polyethylene
glycol adducts containing from 25 to 60 ethoxy groups, more
preferably 40 to 60 ethoxy groups or castor oil/polyethylene
glycol adducts containing from 25 to 45 ethoxy groups.
The C8-C24 fatty acid may be saturated or unsaturated.
Preferred are C12-C13 fatty acids, especially oleic acid,
linoleic acid and linolenic acid.
It will be understood by those skilled in the art that
the choice of surfactant will also depend upon the
particular non-polar liquid and the particular polar liquid
and the amount thereof which are used in the preparation of
the biliquid foams.
The surfactant which is used in the present invention
may be used in combination with an appropriate co-
surfactant. Examples of co-surfactants which may be used
are polyoxyethylene oleyl ethers and hydrogenated castor
oil/polyethylene glycol (25) adduct.
The preferred amount of surfactant for use in the
present invention is about 1% by weight based on the total
formulation.
The biliquid foam compositionsof the present invention
may also contain other additives such as preservatives (for
instance to prevent microbiological spoilage). These
additives may be included in the non-polar liquid or the
continuous phase.
It will be understood that the inclusion of these
additives will be at the levels and with the type of
materials which are found to be effective and useful. Care
needs to be taken in the choice and amount of these
additives to prevent compromise to the other performance
advantages of the present invention.
Methods of producing biliquid foams are described in
US-A-4486333 involving the preliminary formation of a gas
foam in order to provide a sufficiently large surface area
on which the biliquid foam can subsequently be formed. It
has been found that the prior formation of a gas foam is not
required to manufacture a stable biliquid foam, provided
that a suitable stirring mechanism is provided in the
manufacturing vessel. An important aspect of the present
invention is the ability to manufacture biliquid foams
without the preliminary formation of gas foam, by the use of
a tank incorporating a suitable stirring mechanism.
Such an apparatus comprises a tank provided with a
stirrer in which the stirrer blade breaks the interface
between the liquid and air. A delivery device is provided
through which the oil phase (non-polar liquid), which will
comprise the internal phase of the dispersion is delivered
to the tank. The design of the delivery device is such that
the rate of addition of the internal phase fluid can be
controlled and varied during the production process. A
feature of the production process is that the internal (oil)
phase is added to the stirred aqueous phase slowly at first
until sufficient droplets have been formed to constitute a
large, additional surface area for the more rapid formation
of new droplets. At this point, the rate of addition of the
oil phase may be increased.
The production process consists of the following steps:
1. The addition of one or more chosen surfactants to
one or other or both phases (as previously
determined by experiment).
2. The charging of the aqueous phase into the bottom
of a process vessel.
3. The incorporation of the stirrer into the vessel
so that it stirs the surface of the aqueous phase.
4. Adjustment of the stirrer speed to a previously
determined level.
5. The slow addition of the internal phase whilst
continuing to stir at the prescribed speed.
6. The speeding up of the rate of addition of the oil
phase once a prescribed amount (usually between 5%
and 10% of the total amount to be added) has been
added.
The stirring rate and the rate of addition of the oil
phase are variables, the values of which depend upon the
detailed design of the manufacturing plant (in particular,
the ratio of tank diameter to impeller diameter), the
physico-chemical properties of the oil phase and the nature
and concentrations of the chosen surfactants. These can all
be pre-determined by laboratory or pilot plant experiment.
It will be understood by those skilled in the art that
other manufacturing methods may be used, as appropriate.
The high alcohol biliquid foams of the present
invention may be stabilized by means of an aqueous gel and,
accordingly, the present invention includes within its scope
a stable dispersion having a content of C1-C4 alcohol, a
liquid polyethylene glycol, ethylene glycol or propylene
glycol, or mixtures thereof, of at least 65% by weight,
which dispersion comprises from 1 to 80% by weight of a
biliquid foam and from 20 to 99% by weight of an aqueous
gel.
The present invention provides a process for preparing
a stable dispersion which comprises from 1 to 50% by weight
of a biliquid foam as defined above and from 99% to 20% by
weight of an aqueous gel, which process comprises mixing
together the biliquid foam and the aqueous gel. Preferably
the dispersion has a content of C1-C4 alcohol, liquid
polyethylene glycol, ethylene glycol or propylene glycol, or
mixtures thereof of at least 65% by weight.
The aqueous gel will preferably be formed from a
colloidal polymer or gum suspended in water, at a
concentration of from 0.05 to 20% by weight, more preferably
from 0.2 to 1% by weight. Suitable polymers or gums are,
for example, alginate gums or their salts, guar gum, locust
bean gum, xanthan gum, gum acacia, gelatin,
hydroxymethylcellulose or its hydroxyethylcellulose,
hydroxypropylcellulose, carboxymethylcellulose or its salts,
bentonites, magnesium aluminium silicates, "Carbomers"
(salts of cross-linked polymers of acrylic acid), or
glyceryl polymethacrylates or their dispersions in glycols,
or any appropriate mixture of any of these polymers and
gums. Preferred gelling agents are those which confer
plastic behaviour on the aqueous phase, that is, under their
influence, any shear stress applied to the product must
attain a minimum yield value before any liquid flow takes
place.
The stable dispersions of the present invention may be
used to formulate pharmaceutical or cosmetic compositions,
for example, pharmaceutical or cosmetic compositions for
topical application. Examples of active ingredients which
may be included in such compositions are acyclovir,
beclometasone, benzoyl peroxide, benzydamine, betamethasone
valerate, caffeine, calamine, cetrimide, chlortetracycline,
clobetasol, clobetasone, clotrimazole, crotamiton,
diclofenac, diethylamine salicylate, diflucortolone,
dithranol, econazole, erythromycin, fluocinolone,
fluocinonide, flucortolone, fluorouracil, fluticasone,
fusidic acid, felbinac, ketoprofen, gentamicin,
hydrocortisone, hydrocortisone acetate, ibuprofen,
isotretinoin, lactic acid, lidocaine/lignocaine, lidocaine
and chlorhexidine/lignocaine and chlorhexidine, macrogol,
methyl salicylate, metronidazole, mexenone, miconazole,
nystatin, piroxicam, potassium hydroxy-quinoline sulphate
and benzoyl peroxide, retinoic acid and its derivatives,
salicylic acid, sodium fusidate, coal tar and salicylic
acid, coal tar and zinc, tetracyclin, titanium, tretinoin,
triamcinolone, tioconazole, triamcinolone, triclosan, urea,
zinc, zinc and ichthammol, and mixtures thereof.
The drug concentration will vary, depending upon the
drug used, from about 0.01% to 10% by weight. Hence, the
compositions of the present invention comprise a safe and
effective amount of the active ingredient.
The stable dispersions of the present invention may
therefore be used to formulate the following compositions
for use in the pharmaceutical or cosmetics industry.
Topical Compositions
The alcohol which is preferably contained in the
biliquid foams used in the present invention enhances the
permeation through the skin of the active ingredient(a).
The biliquid foam delivers oils to the skin and this helps
to overcome skin dryness associated with topical
compositions containing alcohol and to restore the barrier
properties of the skin.
Topical applications may comprise the delivery of
drugs, such as NSAIDS or anti-acne compositions, in a cream
or gel preparation, or the delivery of drugs such as
nicotine, estradiol, nitroglycerin, testosterone,
scopolamine, etc., via transdermal drug delivery devices or
in a cream or gel preparation. Another topical application
comprises the delivery of cosmeceutical products, such as
anti-cellulite creams formulated with an active ingredient,
such as caffeine, to the skin. The active ingredient will
have an enhanced performance due to the skin enhancer effect
of the alcohol.
Hand Disinfectants
Hand disinfectants formulated using the stable
suspensions of the present invention have bactericidal
properties provided by the high levels of alcohol contained
in the compositions. The combination in the same product of
the alcohol and oils avoids the skin dryness which is a
disadvantage of existing high alcohol disinfectant
compositions.
The present invention will be further described with
reference to the following Examples:
Biliquid Foam Preparation
A suitable vessel is charged with the aqueous phase of
the biliquid foam. The oil phase was added at a constant
rate with stirring, using a sweep stirrer or an orbital
mixer. After completion of the oil addition, the stirring
was continued until the size of the oil droplets became
stable or reached a desired size.
Stable Dispersion Preparation
In a separate vessel the aqueous gel phase components
were combined to produce an aqueous gel. The biliquid foam
was combined with the aqueous gel under low shear stirring
until a homogenous product was produced.
EXAMPLE 1
%(w/w)
oil phase
Mineral Oil 90.0
aqueous phase
Hydrogenated Castor Oil/
Polyoxyethylene Glycol (60) adduct l.o
Ethanol 7. o
Water 2.0
100.0
Ethanol % of continuous polar phase = -78%
Surfactant % = 1
Stability - 20 months
EXAMPLE 2
%(w/w)
oil phase
Isopropyl Isostearate (IPIS) 34.67
Isoeicosane (Permethyl 102a) 43.86
Isoctahexacontane (Permethyl 104a) 10.97
aqueous phase
Hydrogenated Castor Oil/
Polyoxyethylene Glycol(25) adduct 0.50
Water 2.60
Ethanol 7.00
Polyoxyethylene(20)Oleyl Ether(Oleth20) 0.40
100.0
Ethanol % of continuous polar phase =-73%
Surfactant % = 0 . 9
Stability - 20 months
EXAMPLE 3
%(w/w
oil phase
Dimethicone Polydimethylsiloxane
(DOW Corning 200/350cs) 8.06
Dimethicone Polydimethylsiloxane
(DOW Corning 200/5cs) 32.34
Dimethicone Polydimethylsiloxane
(DOW Corning 200/20cs) 24.30
Dimethicone Polydimethylsiloxane
(DOW Coming 200/30, 000cs) 24.30
Castor Oil/Polyoxyethylene
Glycol(25) adduct 0.50
Castor Oil/Polyoxyethylene
Glycol (15) adduct 0.50
aqueous phase
Water 2.50
Ethanol 7.50
100.0
Ethanol % of continuous polar phase = 75%
Surfactant % = 1
Stability - 24 months
EXAMPLE 4
% w/w)
oil phase
Octamethylcyclopentasiloxane and
organopolysiloxane (Gransil GCM) 48.6
Dimethicone and organopolysiloxane
(Gransil TMG) 22.5
Dimethicone Polydimethylsiloxane
(DOW Corning 200/50cs) 0.9
Cetearyl isonoanoate 9.0
Isopar K 9.0
aqueous phase
Ethanol 1.0
Water 2.0
Hydrogenated castor oil/
Polyoxyethylene Glycol(25) adduct 1.0
100.0
Ethanol % of continuous polar phase = -78%
Surfactant % = 1.0
Stability - greater than 5 months
EXAMPLE 5
% w/w
oil phase
Isopropyl isostearate (IPIS) 18.56
Isoeicosane (Permethyl 102a) 23.76
Isooctahexacontane (Permethyl 104a) 5.94
Octamethylcyclotetra-siloxane and
dimethiconol (Dow Corning 1401) 11.14
Decamethylcyclopenta-siloxane
(Dow Corning 245) 11.14
Dimethicone Polydimethylsiloxane
(DOW Corning 200/1000cs) 18.56
Hydrogenated castor oil/
Polyoxyethylene Glycol(25) adduct 0.50
Castor Oil/Polyoxyethylene
Glycol(25) adduct 0.50
aqueous phase
Ethanol 7.50
Water 2.50
100.00
Ethanol % of continuous polar phase = 75%
Surfactant % = 1.0
Stability - 24 months
EXAMPLE 6
% (w/w)
oil phase
Cetearyl isonoanoate 19.230
Isoeicosane (Permethyl 102a) 23.560
Octamethylcyclotetra-siloxane
(Dow Corning 1401) 11.050
Decamethylcyclopenta-siloxane
(Dow Corning 245) 11.050
Isooctahexacontane (Permethyl 104a) 5.890
Dimethicone PolydimethylBiloxane
(DOW Corning 200/lOOcs) 19.220
aqueous phase
Ethanol 7.000
Water 2.000
Hydrogenated Castor Oil/
Polyoxyethylene Glycol(25) adduct 0.625
Castor Oil/Polyoxyethylene
Glycol (25) adduct 0.375
100.00
Ethanol % of continuous polar phase = 78%
Surfactant % = 1.0
Stability - greater than 1 month
EXAMPLE 7
% (w/w)
oil phase
Isopropoyl isostearate (IPIS) 90.0
aqueous phase
Hydrogenated castor Oil/
Polyoxyethylene Glycol(60) adduct 1.0
Ethanol 7.0
Water 2.0
100.0
Ethanol % of continuous polar phase = 78%
Surfactant % = 1
Stability - greater than 20 months
EXAMPLE 8
% (w/w)
oil phase
Dimethicone Polydimethyl-
siloxane (Dow Corning 200/350) 8.06
Dimethicone Polydimethyl-
siloxane (Dow Corning 200/5) 32.34
Dimethicone Polydimethyl-
siloxane (Dow Corning 200/20) 24.30
Dimethicone Polydimethyl-
siloxane (Dow Corning 200/30000) 24.30
Hydrogenated castor oil/Polyoxyethylene
Glycol (60) adduct 1.00
aqueous phase
Ethanol 8.00
Water 2.00
100.00
Ethanol % of continuous polar phase = 80%
Surfactant % ? 1
Stability - 20 months
EXAMPLE 9
% (w/w)
oil phase
Mineral oil 90-0
aqueous phase
Crodmet 50 special 1.0
Ethanol 7 . 0
Water 2.0
100.0
Ethanol % of continuous polar phase = 77.8%
Surfactant % = 1
Stability - > 2 months
EXAMPLE 10
% (w/w)
oil phase
Mineral oil 89.1
Oleic acid 0.9
aqueous phase
Crodmet 50 special 0.2
Ethanol 7.0
Water 2.8
100.0
Ethanol % of continuous polar phase = 71.4%
Surfactant % = 0.2
Surfactant + oleic acid % = 1.1
Stability - > 2 months
EXAMPLE 11
% (w/w)
oil phase
Mineral oil 90.0
aqueous phase
Crodmet 50 special 0.2
Ethanol 7.0
Water 2.8
100.0
Ethanol % of continuous polar phase = 71.4%
Surfactant % = 0.2
Stability - > 3 weeks
EXAMPLE 12
% (w/w)
oil phase
Mineral oil 90.0
aqueous phase
Crodmet 50 special 0.1
Ethanol 7.0
Water 2.9
100.0
Ethanol % of continuous polar phase = 70.7%
Surfactant % = 0.1%
Stability - > 2 weeks
EXAMPLE 13
% (w/w)
oil phase
Mineral oil 90.00
aqueous phase
Crodmet 50 special 0.05
Ethanol 7.00
Water 2.95
100.00
Ethanol % of continuous polar phase = 70.35%
Surfactant % - 0.05
Stability - > 2 weeks
EXAMPLE 14
% (w/w)
oil phase
Tegopren 6814 90.0
aqueous phase
Crodmet 50 special 1.0
Propylene glycol 8 .1
Water 0.9
100.0
Propylene glycol % of continuous polar phase = 90%
Surfactant % = 1
Stability - > 6 weeks
EXAMPLE 15
% (w/w)
oil phase
Tegopren 6814 89.1
Oleic acid 0 .9
aqueous phase
Crodmet 50 special 0.2
Propylene glycol 8 .8
Water 1.0
100.0
Propylene glycol % of continuous polar phase = 89.8%
Surfactant % = 0.2
Surfactant % including oleic acid =1.1
Stability - > 6 weeks
EXAMPLE 16
% (w/w)
oil phase
Mineral oil 89.1
Oleic acid 0.9
aqueous phase
Protachem CAH-25 0.2
Ethanol 7.0
Water 2.8
100.0
Ethanol % of continuous polar phase = 71.4%
Surfactant % = 0.2
Surfactant % including oleic acid =1.1
Stability - > 5 weeks
EXAMPLE 17
% (w/w)
oil phase
Soya bean oil 89.0
Hydrogenated castor oil/
polyoxyethylene glycol (40) adduct 1.0
aqueous phase
Propylene glycol 9.5
Water 0.5
100.0
Propylene glycol % of continuous polar phase = 95%
Surfactant % = 1
Stability - 3 months
EXAMPLE 18
% (w/w)
oil phase
Soya bean oil 77.27
aqueous phase
Polyoxyethylene glycol (PEG 6) 20.46
Crodmet 50 Special (2.27)
100.00
PEG 6 % of continuous polar phase = 100%
Surfactant % = 2.27
Stability - 4 weeks
EXAMPLE 19
% (w/w)
oil phase
Waglinol 3/9280 89.0
Hydrogenated castor oil/polyoxyethylene
glycol (40) adduct 1.0
aqueous phase
Propylene glycol 9.5
Water 0.5
100.0
Propylene glycol as % of continuous polar phase = 95%
Surfactant % = 1.0
Stability - > 3 months
EXAMPLE 20
% (w/w)
oil phase
Waglinol 3/9280 89.0
Castor oil/polyoxyethylene
glycol (40) adduct 1.0
aqueous phase
Propylene glycol 9.5
Water 0.5
100.0
Propylene glycol as % of continuous polar phase = 95%
Surfactant % = 1.0
Stability - > 3 months
EXAMPLE 21
% (w/w)
oil phase
Soya bean oil 89.0
Castor oil/polyoxyethylene
glycol (35) adduct 1.0
aqueous phase
Propylene glycol 9 . 0
Water 1.0
100.0
Propylene glycol as % of continuous polar phase = 90%
Surfactant % = 1.0
Stability - > 3 months
EXAMPLES 22 TO 26
Gelled Formulations
Example 22 to 26 show that there is a wide range of
polymers, which can be used to gel the biliquid foams.
These polymer systems can be prepared at different
concentrations of ethanol. Hence, the concentration of
ethanol in the final formulations can also vary. All
polymers were dispersed in a water/ethanol mixture using a
high-shear rotorstator mixer (Silverson) and neutralizers
were added as appropriate, to form polymer gels.. The
biliquid foams were prepared as discussed above. All
ingredients were mixed together at room temperature.
EXAMPLE 22
Part A: Preparation of biliquid foam
% (w/w)
oil phase
Isopropyl isostearate (IPIS) 34.17
Isoeicosane (Permethyl 102a) 43.86
Isooctahexacontane (Permethyl 104a) 10.97
aqueous phase
Hydrogenated castor oil/polyoxyethylene
glycol (25) adduct 0.50
Water 3.60
Ethanol 6.00
Polyoxyethylene (20) oleyl ether (Oleth 20) 0.40
100.00
Part B: Preparation of biliquid foam
% (w/w)
oil phase
DC 200/350 8.06
DC 200/5 32.34
DC 200/20 24.30
DC 200/30,000 24.30
aqueous phase
Castor oil/polyoxyethylene
glycol (25) Adduct 0.50
Castor oil/polyoxyethylene
glycol (15) Adduct 0.50
Water 4.00
Ethanol 6.00
100.00
Part C: Preparation of gelled formulation
% (w/w)
Klucel HF 0.30
Lubrajel DV 15.00
Ethanol 50.00
Water 22.70
Biliquid Foam of Part A 6.50
Biliquid Foam of Part B 5.50
100.00
% ethanol on aqueous phase = 68
EXAMPLE 23
% (w/w)
Carbomer 980 neutralised with TEA 0.60
Ethanol 49.90
Water 32.66
Biliquid Foam of Example 5 16.84
100.00
EXAMPLE 24
% (w/w)
Hydroxyethyl cellulose 0.30
Carbomer 980 neutralised with TEA 0.45
Ethanol 4 9.00
Water 20.25
Biliquid Foam of Example 1 30.00
100.00
EXAMPLE 25
% (w/w)
Biliquid foam of Example 6 16.68
Carbomer 980 TEA 1.20
Sepigel 0.50
Ethanol 57.16
Water 24.26
100.00
EXAMPLE 26
Part A: - Biliquid foam preparation
% (w/w)
oil phase
Isopropyl isostearate 53.46
Squalane 35.64
Laureth 4 0.90
aqueous phase
SLES in water (Sodium lauryl ether sulphate) 10.00
100.00
Part B: - Gelled formulation
% (w/w)
Water 0.79
Triclosan 0.10
Ethanol 70.00
2% Carbomer 980 (neutralised with AMP 95) 20.00
Opacifier 1.00
Sepigel 2.50
Biliquid foam of Part A 5.61
100.00
% ethanol on aqueous phase - 77%
Drug Formulations
Examples 27 and 28 were prepared from biliquid foam shown
below. The actives were in both cases formulated in the gel
phase. The Carbomer was dispersed in the water/ethanol
mixture using a high-shear rotorstator mixer (Silverson).
The drug was then added to the above mixture once the
Carbomer was fully dispersed and an aqueous solution of 20%
triethylamine (TEA) was added until a clear viscous gel at
pH 7 was obtained. The biliquid foam (Example 4) was mixed
with the polymer gel at room temperature until a semi
viscous white gel was obtained.
EXAMPLE 27
Preparation of biliquid foam A
% (w/w)
oil phase
Gransil GCM 48.60
Gransil DMG 22.50
DC200 (50 cs) 0.90
Ceterayl Isononanoate 9.00
isopar K 9.00
aqueous phase
Ethanol 5.67
Water 2.43
Hydrogenated castor oil/Polyoxyethylene
glycol (25) adduct 0.09
100.00
preparation of gelled formulation
Composition *
Biliquid foam A 3 0.000
Caffeine 3-080
1% Natrasol 0.238
1% Carbomer 0.154
Butylene glycol 2.800
Kathon CG (0.4%) 2.8800
Sodium hyaluronate (1%) 2.800
Water 29.064
Ethanol 29.064
Total 100.000
EXAMPLE 28
Preparation of biliquid foam B
% (w/w)
oil phase
Mineral Oil 90.00
aqueous phase
Ethanol 7.07
Water 2.13
Hydrogenated castor oil/Polyoxyethylene
glycol (25) adduct 0.80
100.00
preparation of gelled formulation
Composition %(w/w)
Biliquid foam B 30.000
. Water 18.4769
Ethanol 42.0400
Ibuprofen 9.3200
Aristoflex AVC 0.1625
Euxyl K400 0.0006
Total 100.0000
Footnotes to the Examples
In all cases the following were used:
Water - demineralised water
Ethanol - DEB 100
Isopar K-C13-C15 Isoparaffin
Klucel HF - Hydroxypropyl cellulose
Lubragel DV - Polymethacrylate propylene glycol
Sepigel - Polyacrylamid/C13-C14 isoparaffin laureth-7
Natrosol 250HHR - Hydroxyethyl cellulose
Kathon CG - Methylchloroisothiozolanone and
methylisothiazolinone
Crodamet 50 Special - Hydrogenated castor oil/polyethylene
glycol (40-50) adduct supplied by Croda Chemicals Limited.
TEA - Triethanolamine.
Carbomer 980 - Polyacrylic acid used as a thickener when
neutralised with a base.
Waglinol 3/9280 - Caprylic-capric triglyceride (CCT)
Protachem CAH-25 - Hydrogenated castor oil/polyethylene
glycol (25) adduct supplied by Protameen Chemicals Inc.
PEG 6 - Polyoxyethyleneglycol (6), also known as PEG 300.
Tegopren 6814 - Alkyl polydimethylsiloxane supplied by Th.
Goldschmidt AG.
AMP-95 - 2-amino-methyl-l-propanol containing 5% water.
WE CLAIM:
1. A biliquid foam comprising from 10% to 98% by weight of a non-polar liquid
such as herein described, other than a fuel and from 2 to 88% by 5 weight of a
continuous phase polar liquid comprising a C1-C4 alcohol, a liquid polyethylene glycol,
ethylene glycol or propylene glycol, or mixtures thereof, in an amount of at least 65%
by weight, relative to the weight of the continuous phase, wherein the biliquid foam is
stabilized with an amount of from 0.05% to 2% by weight based on the total
formulation of a surfactant which is selected from castor oil /poly (alkylene glycol)
adducts containing from 20 to 50 alkoxy groups, a C8-C24 fatty acid such as herein
described, or hydrogenated castor oil /poly(alkylene glycol) adducts containing from 20
to 60 alkoxy groups, or mixtures thereof such as herein described.
2. A biliquid foam as claimed in claim 1 wherein the amount of surfactant is 1 % by
weight based on the total formulation.
3 . A biliquid foam as claimed in claim 1 or claim 2 wherein die surfactant
comprises a hydrogenated castor oil/polyethylene glycol adduct containing from 40 to
60 ethoxy groups.
4. A biliquid foam as claimed in claim 1 or claim 2 wherein the surfactant
comprises a castor oil/poly(alkylene glycol) adduct containing 25 to 45 ethoxy groups.
5. A biliquid foam as claimed in any one of the preceding claims wherein the polar
liquid is aqueous and comprises from 70% to 99% by weight of the C1-C4 alcohol,
liquid polyethylene glycol, ethylene glycol or propylene glycol, or mixtures thereof
such as herein described.
6. A biliquid foam as claimed in claim 1 or claim 2 wherein the non-polar liquid
comprises a mineral oil, a siloxane, an emollient ester, a glyceride, a lanolin oil, a
natural oil, oleyl alcohol, isoeicosane or isooctahexacontane, or mixtures thereof such
as herein described.
7. A biliquid foam as claimed in claim 6 wherein the siloxane comprises
dimethicone, cyclomethicone, dimethiconol, dimethicone copolyol,
octamethylcyclotetrasiloxane, octamethylcyclo-pentasiloxane,
decamethylcyclopentasiloxane, or mixtures thereof such as herein described.
8. A biliquid foam as claimed in claim 8 wherein the emollient ester is isopropyl
isostearate, lanolate, myristate or palmitate, or octyl palmitate, or mixtures thereof
such as herein described.
9. A stable dispersion having a content of C)-C4 alcohol, a liquid polyethylene
glycol, ethylene glycol or propylene glycol, or mixtures thereof such as herein
described, of at least 65% by weight, which dispersion comprises from J to 80% by
weight of a biliquid foam as claimed in any one of the preceding claims and from 99 to
20% by weight of an aqueous gel.
10. A stable dispersion as claimed in claim 9 wherein the aqueous gel constitutes
from 50 to 99% by weight thereof.
11. A stable dispersion as claimed in claim 9 wherein the aqueous gel comprises a
colloidal polymer such as herein described, or gum suspended in water.
12. A stable dispersion as claimed in any one of claims 9 to 11 which comprises at
least one cosmetic compound therein.
13. A process for preparing a stable dispersion which comprises from 1 to 80% by
weight of a biliquid foam as claimed in any one of claims 1 to 8 and from 99 to 20% by
weight of an aqueous gel, which process mixing together the biliquid foam and the
aqueous gel.
14. A process as claimed in claim 13 wherein the stable dispersion also comprises a
cosmetic compound.
15. A process as claimed in claim 14 in which the stable dispersion is an anti-
cellulite cream or an aftershave lotion.
16. A process as claimed in claim 13 wherein the stable dispersion also comprises a
disinfectant compound.
A biliquid foam comprising from 10% to 98% by weight of a non-polar liquid other than a fuel and from 2 to 88%
by weight of a continuous phase polar liquid comprising a C1-C4 alcohol, a liquid polyethylene glycol, ethylene glycol or propylene
glycol, or mixtures thereof, in an amount of at least 65% by weight, relative to the weight of the continuous phase, wherein the
biliquid foam is stabilized with an amount of from 0.05% to 2% by weight based on the total formulation of a surfactant which is
selected from castor oil/poly(alkylene glycol) adducts containing from 20 to 50 alkoxy groups, a C8-C24 fatty acid or hydrogenated
castor oil/poly(alkylene glycol) adducts containing from 20 to 60 alkoxy groups, or mixtures thereof. A stable dispersion having
a content of at least 65% by weight with regard to C1-C4 alcohol, liquid polyethylene glycol, ethylene glycol or propylene glycol
which dispersion comprises from 1-80% by weight of a biliquid foam and from 99-20% by weight of an aqueous gel.

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Patent Number 233846
Indian Patent Application Number 206/KOLNP/2006
PG Journal Number 16/2009
Publication Date 17-Apr-2009
Grant Date 16-Apr-2009
Date of Filing 27-Jan-2006
Name of Patentee DRUG DELIVERY SOLUTIONS LIMITED
Applicant Address SUITE 13, THE LEATHERHEAD ENTERPRISE CENTRE, RANDALLS ROAD, LEATHERHEAD, SURREY KT22 7RY
Inventors:
# Inventor's Name Inventor's Address
1 WHEELER, DEREK ALFRED 3 MAYBELLE CLOSE, BEARE GREEN, SURREY RH5 4RJ
2 DIAS, MONICA THE EVERGREENS, HAMBLEDON PARK, HAMBLEDON, GUILDFORD, SURREY, GU8 4EP
3 GUFFOGG, PHILIP 16 ST. MICHAEL'S ROAD, PONSANOOTH, TRURO, CORNWALL, TR3 7EA
4 WHITBREAD-JORDAN, MARK FERNSIDE, CARN LANE, CARNKIE, REDRUTH, CORNWALL, TR16 0SL
PCT International Classification Number A61K 9/107
PCT International Application Number PCT/GB2004/003318
PCT International Filing date 2004-07-30
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 0317868.8 2003-07-30 U.K.