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1. WO2005044237 - PHARMACEUTICAL COMPOSITION HAVING A CATIONIC EXCIPIENT

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PHARMACEUTICAL COMPOSITION HAVING A CATIONIC EXCIPIENT

TECHNICAL FIELD
The present invention relates to the field of pharmaceutical compositions comprising a cationic
excipient as a carrier ingredient. More specifically, the invention relates to a new group of cationic excipients for such compositions .

BACKGROUND OF THE INVENTION
Positively charged molecules have over the years been evaluated as components of various types of drug delivery systems. Electrostatic interactions with the drug molecule, a component in the biological system or in some cases both are often essential for the mode of action of these types of excipients.
How fast a drug enters the systemic circulation after administration depends on several factors like the chemical characteristics of the substance (e.g.
solubility, membrane permeability) , the route of
administration and the composition of the formulation. Selection of excipients for formulation of biological active materials like drugs must focus on therapeutic efficiency of the dosage form but the composition of the formulation can also affect other important factors like toxicity, drug load, storage stability and production costs.
There are several examples in the literature of cationic drug delivery systems containing lipids. It has for instance been suggested that by promoting nonbilayer structures in the cell membrane, lipids facilitate the intracellular delivery of macromolecules. Encapsulation in cationic liposomes has been shown to protect proteins and peptides against degradation by enzymes in biological fluids. Cationic lipid containing systems like emulsions and microemulsions have also been used to improve
bioavailability after oral administration of sparingly water soluble drugs.
The development of novel drug formulations is often limited by the lack of safe and reliable excipients. A major problem with the use of surfactants in drug
delivery systems is the potential toxicity of surface active agents. A balance between the efficacy in a carrier system for drugs and the toxic effects is always of major concern for substances involved in drug
delivery. We have now found that a class of labile cationic substances, earlier demonstrated to have
antimicrobial activity, have unique potential to be used as cationic excipients for drug delivery. The betaine ester, viz. betaine esterified with a lipophilic alcohol, is a cationic surfactant with outstanding drug delivery properties. Furthermore, the labile bond of the betaine ester results in a cationic hydrolysis product, betaine, which is a normal human metabolite. This means that the toxicity related to the cationic surfactant is transient. The surface active betaine esters used in the present invention can together with drugs, and optionally other excipients, form aggregates like micelles,
microemulsions, emulsions, dispersions and liquid
crystalline phases in presence of water or biological fluids. Since betaine esters form complex with negatively charged polymers, like mucin, they are anticipated to retain the solubilized or dispersed drugs close to the absorption site without damaging the tissue. This is a feature that is especially interesting for transmucosal drug delivery. Transmucosal delivery at sites where enzymatic degradation can occur or which has a pH of 6.0 or higher should be of particular interest for drug delivery systems containing excipients with this type of labile esters. Drug delivery systems of negatively charged or sparingly water soluble drugs are also of special interest for this invention.

The use of a betaine ester as part of a carrier system for pharmaceutical applications is disclosed e.g. in US Patent No. 5,492,937 which describes a carrier composition which is a liquid at or below room
temperature and forms a high viscosity layer or gel at body temperature, characterized in comprising a water-soluble, nonionic cellulose ether having a cloud point not higher than 40 °C, a charged surfactant and optional additives in water, wherein said optional additives are selected from the group consisting of flavouring agents, colorants, preservatives, isotonic agents and mixtures thereof, and in that the combined concentration of the water-soluble, nonionic cellulose ether and the
surfactant is below 3% by weight, and wherein the
remainder of the composition is water and said optional additives. The origin of the gel formation is a strong hydrophobic interaction between polymer and surfactant, which is cooperative in nature and thus resembles normal micelle formation. Surfactant clusters formed in this way may then act as cross-links between different polymer chains, giving rise to an extended three-dimensional gel structure. The surfactant should contain either a
positively or a negatively charged headgroup. Examples of the former surfactants are alkyl ammonium compounds (e.g. hexadecyltrimethylammonium, tetradecylbetainate and hexadecylpyridinium salts, e.g. chloride and bromide). Thus, said carrier composition is aqueous and does not work the same way as the present invention.
US Patent No. 6,007,826 discloses a pharmaceutical or cosmetic composition comprising a pharmaceutically or cosmetically active effective amount of a hydrophobic active ingredient and a carrier, the carrier being an oil-in-water type emulsion which comprises colloid particles having an oily core surrounded by an
interfacial film, said active ingredient being
incorporated into said oily core, wherein said
interfacial film comprises a combination of three different types of surface active compounds, a cationic lipid, a nonionic surfactant and an anionic surfactant or anionic lipid. Said cationic lipid is present in a concentration of 0.05-2% by weight and is selected from the group consisting of a C10-C24 primary alkylamine, a C10-C24 primary alkanolamine and a cholesterol ester (e.g. cholosteryl betainate) . Cholesteryl betainate, a molecule with a large rigid steroid carbon ring
structured with an esterified secondary alcohol has, however, properties quite different from those of the betainates used according to the present invention.

SUMMARY OF THE INVENTION
The object of the invention is to provide a
pharmaceutical composition comprising a pharmacologically active substance, generally a drug, and a carrier
therefor comprising a new, specific type of cationic excipient which imparts good delivery or release
characteristics to said composition.
Another object of the invention is to provide a composition the excipient of which is labile in the presence of water or aqueous body fluid so as to degrade into non-toxic products in the recipient body, generally a human being.
Still another object is to provide the use of said specific type of cationic excipient in a carrier for a pharmaceutical composition.
Other objects of the invention should be apparent to the reader of the more detailed disclosure of the
invention presented herein.
The objects of the invention are achieved by a pharmaceutical composition as claimed in claim 1 and by the use as claimed in the independent use claims.
Preferable embodiments of the composition as well as the use referred to are as claimed in sub-ordinated claims or specifically disclosed in the specification below.

More specifically this means that the cationic excipient of the present invention is a labile ester of betaine and a lipophilic alcohol having at least one primary hydroxyl group.
It is preferred that the carrier or composition is substantially non-aqueous.
Said labile ester has been shown to work very well as a carrier for drug delivery and by said non-aqueous state of the carrier or composition the "lability" does not lead to any hydrolysis of the ester until in the animal (mammal) , generally human, body. When degraded the ester will then result in the hydrolysis product betaine, which is a normal human metabolite. Thus, the toxicity generally related to the cationic surfactant can be said to be transient in connection with the present invention. By "labile" in connection with the present invention is generally meant an ester which undergoes hydrolysis to more than 50% during 24 h at pH 7.4 in the presence of water or other aqueous liquid.
The term "substantially non-aqueous" generally means that such a condition does not cause any substantial hydrolysis of said labile ester, e.g. less than 10%, or less than 5%, in the composition referred to.
Another definition of "substantially non-aqueous" is that generally at most 5% by weight, preferably at most 2% by weight, most preferably at most 1% by weight, of water is present in the composition. A similar term having a similar meaning would be substantially water-free .

BRIEF DESCRIPTION OF THE DRAWINGS
Fig. 1 shows results from Example 2 below.
Fig. 2 shows results from Example 4 below.

DESCRIPTION OF PREFERABLE EMBODIMENTS
The labile betaine ester used according to the present invention is preferably an ester of betaine and an alcohol of the formula

R-CH2-OH,

Thus, firstly a primary alcohol is used.
Secondly, R is a saturated or unsaturated aliphatic hydrocarbon residue, said unsaturation generally
including double bonds only.
The carbon atom number of said symbol R is
preferably 7 - 30, more preferably 7 - 22.
This in turn means that the cationic betaine esters referred to will have the formula:

R-CH2-OCO-CH2-N (CH3) 2+X"

where X" is a suitable counterion which is selected in accordance with known principles per se for surface-active cationic surfactants.
A suitable counterion may be chloride or bromide.
Like for all ionic surfactants the physico-chemical properties of a betaine ester surfactant are mainly governed by the length of the hydrophobic tail of the molecule, i.e. by the R residue in the above formula. The water solubility and the critical micelle concentration (CMC) of the betaine ester both decrease with increasing numbers of carbon atoms of R.
Versatile esters are esters wherein R has 9 - 13 carbon atoms .
As said, the alcohol referred to is a primary alcohol. It may, however, well also contain further hydroxyl groups, primary as well as secondary hydroxyl groups. That is, R is not necessarily an unsubstituted residue, but can be substituted, provided that the objects of the invention will not be lost. Expressed in another way, the substitution may even improve the characteristics of the cationic excipient, or
composition, by the incorporation of substituents on R. Preferred substituents are primary and/or secondary hydroxyl groups, preferably one or two of each thereof.
Other substituents may be selected in accordance with known principles for cationic surfactants.
The hydrocarbon residue R need not either be a chain with carbon atoms only, i.e. a pure alkyl or alkenyl chain, but may well be interrupted by heteroatoms, such as 0 and/or N. According to a preferable embodiment of the invention at least one, preferably one or two, oxygen atom(s) is (are) present.
Preferably such oxygen atom(s) is (are) present in or as ester linkages.
More preferably said ester linkages are glyceride linkages, especially preferable examples being a
1-monoglyceride or a 2-monoglyceride .
Alternatively, the hydrocarbon residue R may
comprise more than one tail, as exemplified by a
diglyceride of the formula


Alternatively, the hydrofobic moiety of the betaine ester may comprise more than one head group, as
exemplified by a gemini surfactant

(a surfactant having two head groups and two hydrophobic tails joined by a short spacer) .
The betaine esters of fatty alcohols are most conveniently prepared in a two-step reaction exemplified by the following chloride-based reaction. In the first step the fatty alcohol is reacted with
chloroacetylchloride to form the chloroacetate. In a second step the chloroacetate is treated with
trimethylamine to give the final product:

R-CH2-0H + CI-CH2COCI → R-CH2-OCO-CH2-CI

R-CH2-OCO-CH2-CI + N(CH3)3 → R-CH2-OCO-CH2-N(CH3)3+ Cl~

Both steps usually proceed in good yields and the end product, the betaine ester, can be purified by reerystaliization.
Other alcohols than fatty alcohols can be used as starting material for synthesis of surface-active betaine esters. Non-ionic surfactants and block copolymer
surfactants, e.g. Pluronic®, which contains an alcohol group are also of interest for functionalisation with betaine. Alcohols from natural sources are of particular interest for betaine ester surfactants to be used in life science applications. Examples of such natural alcohols, besides fatty alcohols, are mono- and diglycerides .
Betaine esters of such alcohols can be synthesized by the procedure described above but the first step, the
formation of the chloroacetate intermediate, will demand higher temperature and/or longer reaction time when the alcohol is a secondary alcohol, as is the case for 1,3-diglyceride and cholesterol, or a primary alcohol with substituents on the α-carbon, as is the case for 1,2-diglyceride.
As mentioned above, betainates of straight-chain fatty alcohols can often be easily purified by
recrystallization. When betaine esters are prepared from alcohols of natural origin, e.g. mono- or diglycerides, polymers containing hydroxyl groups or other alcohols with less well-defined structure, recrystallization of the product is often not possible. In these cases
purification may be accomplished by for instance
distillation or column chromatography of the intermediate or column chromatography of the final product. When using starting alcohols where the hydroxyl group is sterically hindered, as is often the case in the afore mentioned examples of glycerides and polymers, a quite low yield can be expected in the first reaction step. By using a large stoichiometric excess of trimethylamine, however, a very high conversion (close to 100%) may still be
achievable in the second step. In such cases purification of the intermediate is an important part of the
preparation procedure.
An alternative way of synthesizing surface-active betaine esters from a fatty alcohol is to first react betaine with chloroacetyl halogenide to form the acid halogenide, which in a subsequent step is reacted with the fatty alcohol. The reaction sequence is shown below for the chloride:

C1-C0-CH2-C1 + N(CH3)3+ → C1-C0-CH2-N(CH3)3+C1_

R-CH2-OH + C1-C0-CH2-N(CH3)3+C1~ -» R-CH2-OCO-CH2-N (CH3) 3+Cl~

There exist yet other methods of preparing surface-active betaine esters . The present invention is not limited by the procedure used for the synthesis of the compound .
The betaine esters undergo alkaline hydrolysis much more readily than normal esters. On the other hand, they are more resistant to acid hydrolysis than normal esters. This pronounced pH-dependence of the hydrolysis is characteristic for this class of esters and is due to the structure of the molecules . The cationic charge in close proximity to the carbonyl carbon of the ester bond imparts electron deficiency to this carbon. Thus this carbon atom has a partial positive charge, which makes it a strong electrophile . Attack by a nucleophile at this carbon is therefore favoured compared to attack at a normal carbonyl carbon of an ester bond. An alternative or complementary way to account for the increased
reactivity in alkaline hydrolysis of betaine ester bonds is to view the hydrolysis as a way to relief the strain of having a partial positive charge just two atom-atom bonds away from a permanent positive charge. The
situation is shown below:




+0H

In these formulae it should be noted that R
corresponds to R-CH2- in previous formulae.
As is also shown in the reaction scheme, acid hydrolysis is "forbidden". It would yield a dicationic intermediate with the two positive charges close together and this is a very unfavourable arrangement. Taken together, the cationic charge in the betaine ester makes alkaline hydrolysis run very fast and acid hydrolysis extremely sluggish compared to hydrolysis of normal esters. The net effect is that betaine esters are most stable at very low pH, typically pH 2-3, and that the rate of hydrolysis is usually pH-dependent . Already at slightly alkaline conditions, there is substantial breakdown of the molecule.
Surface-active betaine esters are even more
susceptible to alkaline hydrolysis than non-surface active esters. The reason for the increased reactivity of surface-active betaine esters is that the ester bond will hydrolyse more readily when the surfactants are in the form of aggregates, i.e. micelles. Like all other
surfactants, surface-active betaine esters form micelles at a certain concentration, the CMC, and further increase of the surfactant concentration just leads to the
formation of more micelles; the concentration of free surfactant molecules stays constant. In the vast majority of applications of cationic surfactants the concentration is far above the CMC, which means that almost all
surfactants are in an aggregated form. The micelles of betaine ester surfactants are highly positively charged since all the quaternary ammonium groups are located at the surface of the aggregate. The positive charges must be compensated for by negatively charged ions, so-called counterions. All types of negative ions present in the solution, including hydroxyl ions, will accumulate at the micelle surface. This means that the local concentration of hydroxyl ions will be higher in the vicinity of the micelle than in the bulk, or, differently expressed, the local pH around the micelles will be higher than in the bulk. The higher pH will cause a more rapid ester
hydrolysis of micellized surfactants than of free, non-aggregated surfactant molecules. This is referred to as micellar catalysis and is a well-known phenomenon in physical organic chemistry. As an example, the betaine ester of dodecanol at a concentration of 7.8 mM, which is 2.5 times the CMC, has a half-life of 90 minutes in a phosphate buffer of pD 7.5 at 37 °C (pD is the equivalent to pH in deuterated water, D20) .
The extent to which micellar catalysis occurs is dependent on what other anions are present in the
micellar solution. Large polarizable anions, such as bromide and iodide, will interact strongly with the micelle surface while smaller less polarizable anions, such as acetate, will have small affinity for the
micelle. This means that hydroxyl ions will compete favourably, and be accumulated around the micelle, when the surfactant has a small anion, such as acetate, as counterion, but that they will not accumulate at the micelle surface if a large ion, such as iodide, is used as counterion. Use of different counterions for the betaine ester surfactant, and/or addition of extra salt to the surfactant solution, is therefore a way to tune the rate of hydrolysis.
In summary, the betaine ester surfactants break down rapidly on the alkaline side and are very stable on the acid side. The hydrolysis rate is unusually pH-dependent and is also governed by the type and concentration of anions in solution.
Cationic surfactants in general are known to
interact strongly with surfaces and many of their
technical applications, such as textile softener,
additive to fluff and tissue, hair conditioner, corrosion inhibitor, etc., rely on strong adsorption to a surface. The reason why cationic surfactants adsorb particularly strongly is that the majority of surfaces are negatively charged, which means that a cationic surfactant can interact with the surface by both attractive
electrostatic forces and by hydrophobic interactions. Also biological surfaces are usually negatively charged and the well documented antimicrobial action of cationic surfactants is due to a strong interaction with the lipid membranes of bacteria and other microorganisms. The strong interaction with biological lipid membranes is taken advantage of when cationic ampliphilic compounds are employed as bactericides and for gene transfection procedure mediated by cationic lipid vesicles. The strong interaction is also exploited in the use of cationic surfactants as carriers in intracellular delivery of bioactive agents, see US Patent No. 6,056,938. The interaction can also be a problem in that cationic surfactants usually have a higher dermatological toxicity than other surfactants.
Betaine ester surfactants have the same adsorption characteristics as normal cationic surfactants; thus, they adsorb strongly to negatively charged surfaces. The driving force for adsorption increases with the length of the hydrophobic tail of the surfactant, i.e. the R group of the surfactant of the formula above.
The driving force for adsorption of the betaine ester surfactants also depends on the ionic strength of the solution, the higher the electrolyte concentration, the stronger the adsorption. This is a common feature for all ionic surfactants.
The betaine esters will form aggregates such as monolayers, bilayers or hemimicelles at surfaces, including biological surfaces. It is very probable, that the ester will be subject to an increased rate of
hydrolysis in such aggregates, in the same way as in aggregates in solution, i.e. micelles. Thus, "micellar catalysis" is likely to be an important element in the determination of the life-time of adsorbed surfactants. The betaine esters adsorbed at surfaces, as well as present in micelles in solution, are likely to be
considerably more short-lived than free surfactant molecules in solution.
Various types of aggregates of the betaine esters, or small particles or droplets having a surface layer of the betaine esters, will also adsorb strongly to negatively charged surfaces. Since the cell walls are strongly negatively charged such aggregates or particles will bind strongly, and they will be retained at the cell surface. This is important for the use of these esters in drug delivery. The positively charged aggregates and small particles will also interact with negatively charged polyelectrolytes, such as cell surface mucins .
Preferable embodiments of the composition according to the invention are the following:
A water free composition which upon contact with water or other pharmaceutical relevant aqueous medium forms collodial particles and droplets.
A solid composition which upon contact with water or other pharmaceutical relevant aqueous medium forms collodial particles.
A composition which upon contact with water or other pharmaceutical relevant aqueous medium forms collodial particles, the pharmacologically active substance being a negatively charged substance or a substance having low water solubility (more than 250 ml water is needed to dissolve the highest dose strength) .
A composition which upon contact with water or other pharmaceutical relevant aqueous medium forms micelles, a microemulsion, an emulsion or a dispersion of a liquid crystalline phase.
A composition which upon contact with water or other pharmaceutical relevant aqueous medium forms a dispersion of a cubic, lamellar or hexagonal liquid crystalline phase .
In this context collodial particles generally means a particle size less than 10 μm.
Furthermore, the composition referred to here and otherwise in the specification means a composition containing the pharmacologically (biologically) active substance, the betaine ester and optionally other
conventional pharmaceutical excipients, such as non-ionic surface active compunds, and/or solvents.

The compositions of the present invention can be used for improved delivery of hydrophilic or hydrophobic pharmacologically active substances. The invention is not limited to the use of any specific substances but
preferably do the biologically active substances have low water solubility or are negatively charged substances. Examples of biologically active substances include, but are not limited to, nucleic acids such as DNA, cDNA, RNA (full length mRNA, ribozymes, antisense RNA) ,
oligodeoxynucleotides (phosphodiesters, phosphothioates, phosphoramidites, and all other chemical modifications) , oligonucleotide (phosphodiesters, etc.) or linear and closed circular plasmid DNA; negatively charged proteins and carbohydrates including polysaccharides . Suitable drugs include antivirals (acyclovir, IUdR, ganciclovir, vidarabine, AZT) , steroidal and non-steroidal anti-inflammatory drugs (dexamethasone, loteprednol,
prednisolone derivatives, diclofenac, indomethacin, piroxicam etc.), antibiotics (e.g., ampicillin and erythromycin) antifungals (e.g., miconazole) , vitamins, hormones, retinoic acid, local anesthetics, calcium channel blockers (e.g., Verapamil) , prostaglandins and prostacyclins, antineoplastic and antimetabolitic drugs, miotics, cholinergics, adrenergic antagonists,
anticonvulsants (e.g., phenytoin) , antianxiety agents, major tranquilizers, antidepressants, anabolic steroids, estrogens, progesterones, and glycosaminoglycans
(heparin, heparan, chondroitin sulfate, and low molecular weight derivatives thereof) .
"Ionic interaction" or "electrostatic interaction" refers to intermolecular interaction among two
or more molecules, each of which is positively or
negatively charged. Thus, for example, can positively charged lipids interact with negatively charged molecules like DNA. Gene transfer represents an important advance in the treatment of both genetic and acquired diseases. Cationic lipid-mediated gene transfer have advantages over viral gene transfer due to their non-immunogenic properties .
Many of the drugs listed above have low bioavailably when administered orally due to low water solubility, slowly transport through mucous, low permeability through the epithelial cells, instability in biological fluids or a combination of these factors. Low bioavailability of such drugs severely limits their applicability, usage and effectiveness .
Typical pharmaceutical applications of the invention are in oral administration or transmucosal delivery of sparingly water soluble drugs. For oral administration a composition containing the drug and the betaine ester is encapsulated in a sealed soft or hard gelatin capsule. The capsule is typically of a kind which is dissolved in a particular region of the GI tract where it releases its content. Examples of such capsules are entero-coated soft or hard gelatin capsules. Enteric coating, as known per se, is a coating consisting of a substance or a
combination of substances that resists dissolution in gastric fluid but disintegrates in the intestine. The formation of well-defined colloid drug containing
particles and droplets (e.g. liposomes, microemulsions, emulsions, Cubosome® or Hexosome® particles) when the capsule is disintegrated brings about predictable release of the drug which may offer an improvement in both the rate and extent of absorption. Esters of long chained fatty acids in lipid drug delivery dispersions will after digestion and absorption be transported via the lymphatic system in so called chylomicrons. The chylomicrons are in turn carried away from the small intestine through the ' thoracic duct, thus bypassing the liver. Such an
absorption route thus significantly reduces the first pass effect of drug absorbed together with the lipids.
Dosage forms of the compositions of
pharmacologically active substances, betaine esters and any other excipients can be fluid, semisolid or solid.

Betaine esters and biologically active substances my be combined with other excipients so that they are fluid at elevated temperature which allows for filling capsules followed by formation of a solid solution, a solid dispersion or a semisolid formulation when the capsules are stored at room temperature. The term semisolid should be interpreted in the common way in this technical field, i.e. generally a formulation that does not flow under its own weight. Normally this also means that it is semisolid at room or ambient temperature and can be liquefied at higher temperatures.
Inclusion of surfactants in lipid-based liquid crystalline drug delivery particles or precursor systems of such particles can improve loading of water soluble drugs. The enhanced loading of the negatively charged water-soluble drug ketoprofen by the inclusion of
cationic surfactants into Cubosome® particles have been demonstrated in the literature. Development of lipid-based particles like Cubosome®, Hexosome® and liposomes containing the betaine esters and water soluble drugs is an application of the invention. Another interesting application of the invention is formation of positively charged aggregates of a dispersed lamellar liquid
crystalline phase containing the betaine ester and drug that with time undergoes phase transition due to
hydrolysis of the betain ester, thereby altering the drug delivery properties of the particles.
In one embodiment of the invention the betaine ester is combined with other lipid excipients like PC in order to lower the toxicity of the drug delivery vehicle. The reduction in toxicity may be evaluated by haemolysis experiments .
DNA transfection efficiency of aggregates containing cationic lipids can be modified by co-formulating with neutral "helper lipids" like dioleoylphosphatidyl-ethanolamine (DOPE), cholesterol or poly (ethylene
glycol) -phospholipid conjugate. Of special interest is co-formulation of the betaine esters with polar lipids that promote formation of non-lamellar structures, e.g. phosphatidylethanolamine (PE) .
Cryoprotectants and polymers are examples of
components that may optionally be used in the drug delivery systems based on betaine esters. A
cryoprotectant or anticoalescent compound may be added to a formulation of betaine ester and drug prior to
dehydration/evaporation to inhibit flocculation and coalescence upon rehydration. The cryoprotectant may be of any type known in the art, including sugars and polysaccharides such as sucrose or trehalose, and
nonnatural polymers such as polyvinylpyrrolidone .
Cryoprotectants are usually present at less than 25%, commonly 10%, more commonly 5%, 4% (w/v) or less in the emulsion before lyophilization. Natural polymers,
synthetically modified natural polymers, such as
(hydroxypropyl) methylcellulose or synthetic polymers, such as polyvinylalcohol may also be included in betaine ester formulations in order to modify the release of the drug carrying aggregate/particle
The betaine ester-containing composition according to the invention may be prepared by use of water or other solvents followed by evaporation, wherein the evaporation is accomplished by spray drying, freeze drying, air drying, vacuum drying, fluidized bed drying, co-precipitation, or super-critical fluid evaporation.
A further aspect of the invention provides a
dehydrated colloidal suspension. Dehydrated suspensions may be stored for prolonged periods with minimal
degradation, and can be reconstituted with water shortly before use. The residual water content in an dehydrated emulsion is usually less than 5% (w/w) , commonly less than 2%, and often less than 1%.
Dehydration may be performed by standard methods, such as drying under reduced pressure; when the
suspension is frozen prior to dehydration, the low pressure evaporation is known as lyophilization. Freezing may be performed in a dry ice-acetone or ethyl alcohol bath. The pressure reduction may be achieved with a mechanical vacuum pump, usually fitted with a liquid nitrogen cold trap to protect the pump from
contamination. Pressures in the low millitorr range, e.g., 10-50 millitorr, are routinely achievable, but higher or lower pressures are sufficient.
Especially preferable embodiments of the invention are compositions in the form of freeze-dried powder, spry-dried powder and a pumpable mass that can be filled into a capsule.
The pharmacologically effective amount of the active substance is of course chosen, by the person skilled in the art, along known principles, while taking into consideration which specific compound is selected, the specific use therof and so on. Similarly the
concentrations of excipients, solvents, etc. are also selected in accordance with prior art so as to achieve the desired solid, semisolid or fluid state. Finally, the percentage of the betain ester is also easily determined by the skilled artisan while considering known principles concerning cationic excipients and the specific purposes to be obtained.

EXAMPLES
Example 1 :
Synthesis of dodecyl betainate
Dodecyl betainate was prepared from dodecanol, choloroacetyl chloride and trimethylamine using the two-step synthetic procedure described below:
In the first step chloroacetyl chloride (14.2 g, 126 mmol) in dichloromethane (25 ml) was drop-wise added to a stirred solution of 1-dodecanol (22.73 g, 122 mmol) in dichloromethane (100 ml) . The reaction mixture was stirred for 6 h at room temperature and then gently refluxed for 0.5 h. After being washed with a 5% solution of sodium hydrogen carbonate (3x25 ml) , to remove excess chloroacetyl chloride, the organic phase was dried over magnesium sulphate, filtered and rotary evaporated.
In the second step trimethylamine (14.0 g, 237 mmol) was slowly bubbled through an ice-cooled, stirred
solution of dodecyl chloroacetate (15.24 g, 58 mmol) in dry acetone (600 ml), whereupon the solution was allowed to attain room temperature. After 76 h the product, a white fluffy precipitate, was collected on a glass filter and washed with diethyl ether (3x20 ml) . The product weighed 16.2 g, corresponding to an overall yield of 83%. 1H-NMR (CDC13) : δ 0.88 (t, 3H) , 1.22-1.39 (m, 18H) , 1.66 (m, 2H) , 3.66 (s, 9H) ,
4.18 (t, 2H) , 5.19 (s, 2H)

Example 2 :
Concentration dependence on the hydrolysis of surface active betaine esters
Figure 1 shows the concentration dependency of the hydrolysis rate for surface active betaine esters, exemplified by the initial pseudo first-order rate constants versus concentration for a number of betaine esters ( (o) Oleyl betainate, (•) tetradecyl betainate, (□) dodecyl betainate, (■) decyl betainate, (0) ethyl betainate) in a phosphate buffer of pD=7.5 at 37 °C (pD is the equivalent to pH in deuterated water, D20) . Ethyl betainate is included as a non surface active reference. The increase in hydrolysis rate with increasing
concentration is caused by an increasing contribution from micellar catalysis, and the following decrease can be explained by the increased competition between the hydroxyl ions and the surfactant counterions at the micellar surface.
Figure 1 also shows the dramatic increase in
hydrolysis rate due to the presence of micellar catalysis for the surface active betaine esters. For instance, dodecyl betainate at a concentration of 7.8 rtiM, which is 2.5 times the CMC, has a half-life of 90 minutes, compared to a half-life of 9 h for ethyl betainate.
Exampl e 3 :
Ussing chamber experiments to show low toxicity of betainate systems
A modified Ussing diffusion chamber with an exposed tissue area 1.78 cm2 was used in the experiments. 15 to 20 cm of the small intestine, distal to the Ligament of Treitz was removed from rats (male Sprague-Dawley, 400-500 g) and used in the tests. Three rats and three segments per rat were included in each experimental group. The passage of different marker molecules, 14C-mannitol and FITC-dextran (4400 FD ) , from the mucosal to the serosal chamber were expressed as apparent
permeability coefficient (Papp) . The apparent
permeability coefficient (Papp) to mannitol and FITC-dextran 4.400 across the intestinal mucosa was calculated from the equation: Papp (cm/s) x 10-6) = dc/dt *
(V/(A*C0)), where dc/dt is the change of the serosal concentration over time (mol/L/sec) , V is the volume in the reservoir of the serosal side (cm3) , CO is the initial concentration of the marker in the mucosal reservoir (mol/L) , and A is the exposed intestinal area in the chamber (cm2) . The experiments were done on marker molecules dissolved in a dodecyl betainate (0.5 % w/w) containing solution and in a control solution (Krebs buffer) .
The Papp values for 14C-mannitol are scattered between 3 and 4 x 10-6 cm/s. There are no obvious
differences between the different treatments.
The Papp values for FD4 are scattered between 0.4 and 0.6 x 10~6 cm/s (App. 2) . There are no obvious differences between the different treatments.
The difference in electric potential over the segments was measured before and after the experiment. With respect to permeability for marker molecules, the intestinal segments were not affected by co-formulation with dodecyl betainate. Furthermore there was no
increased damage to segments in response to treatment with betaine ester containing solution as compared to control, assessed by determination of potential
difference over the segments before and after treatment.

Example 4 :
Hemolysis experiments on betaine ester surfactants
Erythrocytes from rats were washed 3 times and suspended in saline solution (0.9%) to a volume fraction of 0.025. The hemolys experiments were performed by mixing the erythrocyte suspension with surfactant
solutions in a 1:1 ratio, thereby giving a finale
erythrocyte volume fraction of 0.0125 and a surfactant concentration as stated in the figure. The samples were then incubated at 37 °C for 1 hour and centrifuged at 2000 g for 10 minutes. Aliquots of the supernatant was mixed with an equal volume of 15 mM C14TAC before the hemoglobin content was measured spectrophotometrically on a Labsystems iEMS Reader MF at 540 nm.
For the samples containing phospholipids, a liquid concentrate of dodecyl betainate, PC and ethanol in a weight ratio of 16:64:20 were prepared. The concentrate was dispersed in saline solution by gentle stirring at room temperature just before the experiment. The
resulting aqueous dispersion was tested in the same way as stated above for the surfactant solution.
Figure 2 shows the relative haemolytic effect of different cationic surfactant solultions and a cationic ionic phospolipid dispersion. The concentrations given in the figure represent the amounts of cationic surfactant in the tested solutions. OB = oleyl betainate, DDB = dodecyl betainate, DDB/PC = dodecyl betainate
coformulated with phosphatidyl choline in a weight ratio of 20 to 80 (concentration of DDB given), C14TAC = tetradecyltrimethylammonium chloride. The phosphatidyl choline used is Epikuron 200 from Degussa BioActives, a pharmaceutical grade product of soybean origin. All data are normalized to the absorbance obtained from hemolysis by the 0.5 mM tetradecyltrimethylammonium chloride
sample .
This example shows that at low concentrations the toxicity to red blood cells of dodecyl betainate is lower than that of the stable surfactant C14TAC, which has a comparable critical micelle concentration 2.5 mM (CMC for dodecylbetainate is 3.1 mM) and that the toxicity of can be further lowered by co-formulating the betaine ester with phosphatidyl choline.
Example 5 :
Aqueous particle dispersion of a sparingly water soluble substance stabilized with betaine esters.
The ability of dodecyl betainate to stabilize aqueous dispersions of hydrophobic particles was
investigated in samples containing 1 % cholesterol (of lanolin origin, Fluka) in pure water and in dodecyl betainate solutions of varying concentration. The samples were prepared by weighing the components into screw- capped glass vials that were first shaken, then kept in an ultrasonic bath for 5 minutes and finally shaken again before left for inspection. The table below presents the visual appearance of samples with different surfactant concentrations at different times.



The sample with pure water was a coarse dispersion that precipitated quickly, while samples containing more than approximately 0.1% of the surfactant were fine dispersions with prolonged stability. The table shows that particles of water insoluble particles like steroids can easily be stabilized against particle aggregation and sedimentation by betainate esters in aqueous systems.

Exampl e 6 :
Transformation from a lamellar liquid crystalline phase to a cubic phase with time in a mixture of dodecyl betainate, glycerol monooleate and a physiologically relevant medium
A solution A was made from 81% w/w glycerol
monooleate (Danisco Brabrant, Danmark) , 9% w/w dodecyl betainate and 10% w/w ethanol . Two samples were prepared by mixing solution A with simulated intestinal fluid (SIF) (pH = 7.4) and with water, respectively. The compositions of the samples are reported in the table below. The phase behaviour of the samples as a function of time was studied by visual inspection between crossed polarizers and reported in the table below. A sample of glycerol monooleate and water was used as a reference. Glycerol monooleate is known to form a cubic,
nonbirefingent liquid crystalline phase in excess water at room temperature.



This experiment shows that addition of dodecyl betainate to glycerol monooleate induces a phase shift from a cubic phase to a birefingent phase, probably a lamellar phase and that this lamellar phase at
physiological relevant conditions with time transforms into two phases, probably cubic liquid crystalline phase and an aqueous solution.