CA2127805C - Composition for nasal administration - Google Patents
Composition for nasal administration Download PDFInfo
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- CA2127805C CA2127805C CA002127805A CA2127805A CA2127805C CA 2127805 C CA2127805 C CA 2127805C CA 002127805 A CA002127805 A CA 002127805A CA 2127805 A CA2127805 A CA 2127805A CA 2127805 C CA2127805 C CA 2127805C
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- Prior art keywords
- morphine
- microspheres
- glucuronide
- agent
- sulphate
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- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61K—PREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
- A61K31/00—Medicinal preparations containing organic active ingredients
- A61K31/33—Heterocyclic compounds
- A61K31/395—Heterocyclic compounds having nitrogen as a ring hetero atom, e.g. guanethidine or rifamycins
- A61K31/435—Heterocyclic compounds having nitrogen as a ring hetero atom, e.g. guanethidine or rifamycins having six-membered rings with one nitrogen as the only ring hetero atom
- A61K31/47—Quinolines; Isoquinolines
- A61K31/485—Morphinan derivatives, e.g. morphine, codeine
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61K—PREPARATIONS FOR MEDICAL, DENTAL OR TOILETRY PURPOSES
- A61K9/00—Medicinal preparations characterised by special physical form
- A61K9/0012—Galenical forms characterised by the site of application
- A61K9/0043—Nose
Abstract
A composition for nasal administration of polar metabolites of opioid analgesics comprises a polar metabolite of an opioid analgesic and an absorption promoting agent. Preferred metabolites morphine-6-glucuronide and morphine-6-sulphate. A
preferred absorption promoting agent is chitosan but other suitable agents include cationic polymers, bioadhesive agents, surface active agents, fatty acids, chelating agents, mucolytic agents, cyclodextrin, microsphere preparations or combinations thereof.
preferred absorption promoting agent is chitosan but other suitable agents include cationic polymers, bioadhesive agents, surface active agents, fatty acids, chelating agents, mucolytic agents, cyclodextrin, microsphere preparations or combinations thereof.
Description
Wt) 93/15737 ~~'/~~93/00228 CAMP~SI?.Ii~NS FOR NASAL ADMINISTP~ATION CONTAINING POLAR METARQLI'fES
OPIOID ANALGESICS
This invention relates to a composition for nasal J administration and more particularly to a composition for the nas~.l administration of the polar metabolites of opioid analgesics.
Opioid analgesics have a useful role in pain relief, 3:0 particularly for patients in the terminal stags of cancer.
~Zorphine is a widely used agent and can be administered via injection as an oral contrblled release formul~tior~ or by suppository. Morphine hay also been given via the nasal route axed morphine snuf ~ was d~scri.bad in the last century .
The int~anasal adm~.nistratiori of opiates has been discussed by Ralley (Gan. ~.Anaesth. 36, 5 X91-493 (193) .
who suggested that~anarphine could be given by this route.
The route was relatively free c~f ide effects normally 20 associated with opioids but a possible disadvantage was the shoat dura~.ion of sedation which lasted only up to &
minutes.
. Nasal administration of morphine is discussed in EP
25 205282 where a sustained release effect is achieved through the use of a cellulosic~derivative that adheres to the mucosa. A solid unit dosage form is described.
lylJ 93/ ~ 5737 n~'/G~9~/0022~
OPIOID ANALGESICS
This invention relates to a composition for nasal J administration and more particularly to a composition for the nas~.l administration of the polar metabolites of opioid analgesics.
Opioid analgesics have a useful role in pain relief, 3:0 particularly for patients in the terminal stags of cancer.
~Zorphine is a widely used agent and can be administered via injection as an oral contrblled release formul~tior~ or by suppository. Morphine hay also been given via the nasal route axed morphine snuf ~ was d~scri.bad in the last century .
The int~anasal adm~.nistratiori of opiates has been discussed by Ralley (Gan. ~.Anaesth. 36, 5 X91-493 (193) .
who suggested that~anarphine could be given by this route.
The route was relatively free c~f ide effects normally 20 associated with opioids but a possible disadvantage was the shoat dura~.ion of sedation which lasted only up to &
minutes.
. Nasal administration of morphine is discussed in EP
25 205282 where a sustained release effect is achieved through the use of a cellulosic~derivative that adheres to the mucosa. A solid unit dosage form is described.
lylJ 93/ ~ 5737 n~'/G~9~/0022~
2~.~~~~ ~ 2 Wo 8203768 describes a system .for nasal drug delivery comprising morphine or its analogues having at least one phenolic hydroxy group with a non toxic nasal carrier.
Ointments, gel solution or suspension salts of morphine are preferably used in the sustained release products.
It is well known that the therapeutic use of morphine gives rise to various side effects, including donstipation and respiratory depression. Recently it has been da.sclosed that some, of the metabolites of morphine, namely morphine-''~~' 6-glucuronide and morphine-6-sulphate may be several times more active than the parent drug and is less likely to tiav~
the unwanted side effects (pasternak et a.~ (1987) Life Sciences 41:; 2845; Hanna et al. (1991) Hrit.J.Anaes. 66, 1~ 103; Br~wn et al 0.985) J ~'harm.Sci. 74,821) . They may also have a longer biologa.cal half-life. The use of morphine-~6-glucuronide as a drug substa~nd~ in its own right has been discussed in the pharmaaeu~ieal and medical literature (Osborne et al (1988) Lancet April 8 p.828).
Similarly, morphine°~-sulphate has been described in the literature as an analgesic agent Grown et a.I Supra).
However, the major problem facing delivery of these agent and polar metabolites of this and other opioid analges~.cs by methods other than injection, is the high water solubility of the compounds. It is unlikely that the materials will be well absorbed across mucosal surfaces, f or example from the gastrointestinal tract. It is possible that the glucu~onides would be absorbed from the WfA g311~737 ~~ ~ ~ ~ .,~ P~'T/GI~93/0022~
Ointments, gel solution or suspension salts of morphine are preferably used in the sustained release products.
It is well known that the therapeutic use of morphine gives rise to various side effects, including donstipation and respiratory depression. Recently it has been da.sclosed that some, of the metabolites of morphine, namely morphine-''~~' 6-glucuronide and morphine-6-sulphate may be several times more active than the parent drug and is less likely to tiav~
the unwanted side effects (pasternak et a.~ (1987) Life Sciences 41:; 2845; Hanna et al. (1991) Hrit.J.Anaes. 66, 1~ 103; Br~wn et al 0.985) J ~'harm.Sci. 74,821) . They may also have a longer biologa.cal half-life. The use of morphine-~6-glucuronide as a drug substa~nd~ in its own right has been discussed in the pharmaaeu~ieal and medical literature (Osborne et al (1988) Lancet April 8 p.828).
Similarly, morphine°~-sulphate has been described in the literature as an analgesic agent Grown et a.I Supra).
However, the major problem facing delivery of these agent and polar metabolites of this and other opioid analges~.cs by methods other than injection, is the high water solubility of the compounds. It is unlikely that the materials will be well absorbed across mucosal surfaces, f or example from the gastrointestinal tract. It is possible that the glucu~onides would be absorbed from the WfA g311~737 ~~ ~ ~ ~ .,~ P~'T/GI~93/0022~
colon ,but this would only occur after the glucuronide was converted back to the parent compound by the action of the . reducing conditions within the large bowel created by the microbial flora in that region. The polar nature of the c~mpound~ also means that they are likely to be poorly transported across normal mucosal surfaces such as the nasal, buccal, vaginal and rectal mucosae. However, we have now found, surprisingly, that the abs~rptioi~ of such polar metabolites across the nasal mucosa can be. greatly 1~ increased by ccimbination with an absorption promoting s r..
agent.
Thus the present invention provides a composition for nasal administration comprising a polar metabolite of an opioic3 analgesic and an a~>sorption promatin~ agent: A
preferred metabolite is a glucuronide, especially morphine-6-glucuronide, however glucuronides of o~h~r dpioid analgesics such as codeine, levorphanol, hydromorphone, o~cymorphone, r~albuph.ine, buprenorphine, nalorphine, hydrocodone, oxycod~ne and butorph~nol are also suitable.
A further preferred metabolite is a sulphate, especially morphine-6msulphate but again su~.phates of other opioid analgesics s~cla as those mentioned above are also suitable.
t~pi.oid analgesics are metabolised in the body to a variety of compounds that are more polar than morphine itself, and this is what we mean by the term metabolite as used herein. The polar nature of a compound can be VVO 93/15737 ; ~~ ,,. ~CT/~893/~022~
agent.
Thus the present invention provides a composition for nasal administration comprising a polar metabolite of an opioic3 analgesic and an a~>sorption promatin~ agent: A
preferred metabolite is a glucuronide, especially morphine-6-glucuronide, however glucuronides of o~h~r dpioid analgesics such as codeine, levorphanol, hydromorphone, o~cymorphone, r~albuph.ine, buprenorphine, nalorphine, hydrocodone, oxycod~ne and butorph~nol are also suitable.
A further preferred metabolite is a sulphate, especially morphine-6msulphate but again su~.phates of other opioid analgesics s~cla as those mentioned above are also suitable.
t~pi.oid analgesics are metabolised in the body to a variety of compounds that are more polar than morphine itself, and this is what we mean by the term metabolite as used herein. The polar nature of a compound can be VVO 93/15737 ; ~~ ,,. ~CT/~893/~022~
determined by measuring its partition caefficien~: between an aqueous buffer and an organic solvent such as octanol.
The partition coefficient of morphine, expressed as a logarithm (loge) partitioned between an aqueous buffer and octanol ranges from 0.70 to 1.03 (Hansch C. and Leo A.
°'Substituent constants for Correlation Analysis in Chemistry and Biology" Wiley, New York, 1979). The polar metabolites of morphine will~therefore have a lower loge value than that of morphine. The major metabolites of morphine are morphine-3-glucuronide,(M3G) and morphine-6 ~~ glucuronide (M-6G). Formation of the ethereal sulphates at positions 3 and 6 in the molecule may also occur.
Morphine-6-sulphate which d~.ffers from morphine itself by having an ionizable group off: Carbon-6 at physioa.ogical pH
has been shown to be a more potent analgesic than morphine following intracerebroventricular administration in mice (Brown e~ a1 (1985) J. Pharm. Sci: 74, 821). Morphine-6-sulphate and a number of its 3-O-acetyl derivatives exhibit potent antinociceptive activity in the rat when given by subcutaneous injection (Houdi, et al (1992) Pharm. Res. 9 s-z~3).
The structures of morphine-6-glucuronide and morphine-6-sulphate are shown below .
W~ 93/ ~ 5737 PdC1'/~1393/0022~
M
r G~3 0 '~-~3 C coo t-( I t C,~ J-t p ~- S ~.- ~
t~ J I
~H H O
~.q ~
O ~l .
morphine-6~glucuronide morpha.n~-~-sulphate The ab~orpti.~n pr~motinc~ agent should be such that it pr~vid~s therapeutic hovels of m~taboli.te in the plasma ~~th an absorption efficiency of greater than 10°~ acrd p~'eferably gx°~ater than 30%. '~h~ absox~ptian is measured in .
germs of the bioavail.ab~lity, wh5.eh ~.s defined as the ratio of the quaratit~ of metabolite appearing a:n the blood after intranasal a~i~aa.ni~tration compared try that found after intravenous ad~ai.nistration, expressed as a percertta~e.
The therapeutic level of the metabolite acha.eved should be a plasma concentration that is at leash a~
eguipotent as the level ree~ui,red for the opi~id anal~esi.c for anal.geaic effect. For morphine, the usual therapeutic levels in plasma are from 1-500 ng/ml, and more typically 20-100 ng/ml. Data have indicated that, for example, W4 93/15737 ~'C.'T1G~9310022~
morphine--6-glucuronide and morphine-6-sulphate could be many times more active than morphine. Thus the required therapeutic levels of morphine-6-glucuronide and morphine-6-sulphate may be in the same range as those ~or morphine or they may be much lower and it is the potency that will decade the required concentration. Although more work is required in this area, morphine-6-glucuronide and morphine-6-sulphate levels may be expected to be in the region of two times less vthan those of morphine to give the same pain relief effect.
y ,..
The composition of the ~inventi.on may be used for pain relief in a variety of situations but especially to relieve chronic pa~.h in terminal cancer patients, f~r acute pain, for example after dental surgery and for other gost-~
operative pain.
The absorption promoting agent is desirably a cationic polymer, a bioadhesive agent, a surface active agent, a 2~ fatty acid, a chelating agent, a mucolytic agent, a cyolodextrin or combinations thereof or a microsbhere preparation, and may be present in the composition as a solution in an aqueous medium, a dispersion in an aqueous medium, as a powder or as microspheres. The terms used here are not intended to be mutually exclusive.
Chitosan, a cationic polymer, i.s a preferred absorption enhancex. Chitosan is deacetylated chitin, or i~V~ 931573'7 ~ ~ ~'"~ .~ ~ ~ . Pt:.T/G~93/8~z28 poly-N-acetyl-D-glucosamine. It is available from Protan Laboratories Inc, Redmond, iJashington 98052, USA and, depending on the grade selected, can be soluble in water up to pig 6Ø A 1% solution of non-water soluble chitosan (sea Cure) may be made by making a slurry (eg 2g/100 m1) in water and adding an equal volume of organic acid (eg 100 ml of 2% acetic acid) and stirring vigorously for one hour.
Water-soluble chitosan (Sea Cured) may dissolve without organic or inorganic acids being present. The chitosan tray also be used as chitosan microspheres.
.,..
ehitosan has previoushy been used to precipitate proteinaceous material, to make surgical sutures and as an ixxnmmunostimu~.ant. It has also been employed previously in 15. oral drug formulations in order to improve the dissolution of poorly soluble drugs (Sawayanagi e~ a1, (1983) Chem.
Pharm. dull., 31, 2062-268) or for the 'sustained release of drugs (I~agai ef al, Proc. Jt. LJS- Jpn. Semin. Adv.
Chitin, Chitosan, Relat. Enzymes, 21-39. Zikakis J.P.
2~ (ed), Academic Press. Orlando (1984)) by a process of slow erosion from a hydrated compressed matrix.
I7iethylaminoethyl-dextran (DEAE-dextran) is also suitable and is a polycationic derivative of dextran 25 containing diethylaminoethyl groups coupled to the glucose residues by ether linkages. The parent dextran can have an average molecular weight of about 5,000 to ~0 x 106, but is typically about 500,000.
W~ 93/15737 PCf/G$9310022~
a Further cationic polymers which may be used in the compositions of the invention include other polycationic carbohydrates such as but not limited to inorganic or organic salts of chitosan and modified forrns of chitosan (especially more positively charged ones), polyaminoacids such as polylysine, polyquaternary compounds, protamine, polyamine, DFAE-imine, polyvinylpyridine, polythiodiethyl-aminomethylethylene (P(TDAE)), polyhistidine, DFAE-methacrylate, DF:AE-acrylamide, poly-p-aminostyrene, l0 polyoxethane, co-polymethacrylates. (e:g. copol,ymers of ~_~ ..
HPMA, N-(2-hydroxypropyl)-methacrylamide, GAFQUAT (US Pat i~o 3,910,62) and polyamidoamines. The polycatioraic substances used in the invention. typically hive a mol.ec~alar 'weight" of 1~J OOO or more. 7Che chitosan (or salt thereof) 15. preferably has.an intrinsic viscs~sity of at lest ~~0 ml~g. .
more pr~efer~bly at lest 50~, 750 or 1000 ml/g.
The co~ncentl: anon of the Galri~nic p~lymer ira a solution is preferably 0.01 to 50% w/v, more preferably O.I.
20 to Sop and more preferably 0.2 to 30~>
Amongst 'the bioadhesive agents suitable for use are included bioadhesive microspheres. ~ Preferably the microspheres are prepared from a bio-compahible material 25 that will gel in co~atact with the mucosal surface:
Substantial~.y uniform .sol~.d microspheres are preferred.
Starch microspheres (drosslinked if necessary) are a preferred material. Other materials that can be used to W~ 93/15737 ....~ ~~. :~ ~CH'/~~~3/00228 form ~microspheres include starch derivatives, modified starches such as amylod~:~arin, gelatin, albumin, collagen, dextran and dextran :ae:-ivatives, polyvinyl alcohol, polylactide-co-glycolide, hyaluronic acid and derivatives thereof such as benzyl and ethyl esters, gellan gum and derivatives thereof such as benzyl and ethyl esters and pectin and derivatives thereof such as benzyl and ethyl esters. By the term °°de~ivatives°° We particularly mean esters and ethers of the parent compound that can be 1c9 unfunctionalised or functionalised to contain, ~or example, ..
l.onlc gr~UplnCJa .
Suitable starch derivatives include hydroxyethyl starch, hydroxypropyl starch, carb~xymethyl starch, ~:5 cationic starch, ~cetylated starch, phasphorylateci starch, succzraate derivata.ves of starch and grafted starches : Such starch derivatav~s are well known and described in the art (for example Modified Starches: Properties and Uses, O.E.
Wurzburg, CRC PreSS BOGa Raton (1986)).
Suitable dextran derivatives include, diethylaxninoethyl-dex~rara (D~AE-dextran) , dextrara sulphate, dextran methyl-benzylamide sulphonates, dextran methyl-benzylamide carboxylates, carbo~ymethyl d~xtran, diphosphonate deactran, dextran hydrazide, palmitoyldextran and dextran phosphate.
Preparation of these microspheres is well described in ~V~ 9~/~5'737 '~ P'C.'flC~9~/00228 2~.~~~U~ 10 the pharmaceutical literature (see for example ~avis et a.i . , ( Eds ) , °°Microspheres anc~ Drag Therapy°° , Elsevier Biomedical Press, 1984, which is incorporated herein by reference). Emulsion and phase separation methods are both .5 suitable. For example, albumin microspheres may be made using the water-in-oil emulsification method where a dispersion of albumin is produced in a suitable oil by homogenization techniques or stirring techniques, with the addition if necessary of small amounts ~f an appropriate surface active agent. The size of the microspheres is .., .
largely di.ctated.by the speed of stirring or homogenization conditions. The agitation can be provided by a sample laboratory st~:rrer or by more sophisticated devices such as a microfluidizer or homogenizer. Emulsification techniques are also used to produce starch microspheres as described in ~B 1 518 121 and EP 223 30~ as well as for the preparation of microspheres of gelatin. Proteinaceous microspheres may also be prepared by coacervation methods such as simple or complex coacerva~ion or by phase separation techniques using an appropriate solvent or electrolyte solution. Full details of the methods of preparing these systems can be obta~.ned from standard text books (see for example Florence and Attwood, Physicochemical Principles og Pharmacy 2nd Ed., MacMillan Press, 1988, Chapter 8).
For example, microspheres were prepared as follows:
W~ 93/15737 ~ P~'1G~93/0022~
The pret~aration of starch micros hares usin emulsification A loo starch gel was prepared by heating (70°c) 5 g of starch with 40 ml of water until a clear gel was formed.
After cooling water was added to a volume of 50 ml. 20 ml of the starch gel was added to 100 ml of Soya oil containing antioxidant and lm v/v Span 80 and homogenised at 7000 rpm for 3 minutes» This emulsion was added to 100 ml hot (80°C) Soya oil BP (cantaining antioxidant) and stirred at 1500 rpm while heated to 115°C over 15 minutes.
The emulsion was left stirring at 115°C for 15 minutes and y , ..
then rapidly cooled. 100 ml of acetone was added and the microspheres were centrifuged at 4500 rpm for l5 minutes.
They were then washed with acetone and air dried. The microspheres can be separated into the desired size 25 fraction (for example 1~-10 ~,m) using appropriate sieves.
Pre aration of h aluronic acid ester micros hares b solvent extraction An emulsion was formed by mixing a 6%~w/v solutipn of 2o the polymer eg benzyl hyaluronic acid ester fHyaff - 11) in dimethylsulphoxide with white mineral oil containing 0.5%
Arlacel A. The inner phase was added to the outer oil phase (their respective ratio ~aeing 1 . 16 v/v) with continuous stirring for 10 minutes. (1000 rpm). Ethyl 25 acetate, the extraction solvent, was then 'added to the emulsion at a retie of 2.: 1 v/v. The extraction proceeded for 15 minutes at a stirring rata of 700 rpm until the microparticles were formed. The microsphere suspension was 'W~ 93/15737 , . PC'T/~B9310022~
filtered and extensively washed with n-hexane and dried.
Drug can be incorporated into the microspheres by addition to the initial polymer solution.
The obtained microsphere size was 2-l0~axn.
The re aration of alb~.xmin micros hares usin an emulsification technique and heat stabilisation 100 ml Soya oil was mixed with 1 ml of a 10a albumin volution and homogenised ~t X000 rpm. The emulsion was ..
added to 200 ml soya o:~l at 50 °C and stirred at 1500 rpm.
.' The emulsion was heated to 120 °C and equilibrated for 20°C
at this temperature> The'micr~spheres were cooled to room temperature end washed with-pets~leum ~~her, fo~:lowed by 1.5 ethanol and acetone. They were then filtered and,driedo t~icrospheres of ~.-~:0 ,um were obtained.
Preparation of Albumin microspheres usincr a coacervata~ean technir~ue 10 ml 25o HSA solution (ph=5) was stirred (500rpm~
while a 30o solution of PEG was added (2.5 ml) until phase separation occurred. The system was stirred for l5 minutes before the albumin dr~plets was solidified by sl~wly heating the mixture to 90°C and keeping it at this temperature for 30 minutes. Instead of heat denaturati~r~, glutaraldehyde can be used to crosslink ache albumin but this latter method seems to make the particles aggregate to ~ greater extent khan that seen with the heat denaturation.
~WC~ 93/15737 ~ ~ ~ ~ ~ ,~ F(.'T/G~93/002Z~
~3 The m~icrospheres were then isolated by' filtration and breeze dried.
With a stirring speed of 500 rpm particles with a mean size of 43 um -!- 6 ~.m was produced.
Pre aration of soluble otato starch micros hers usin a coacervation technique ml 5% starch solution (pH=7) was kept at a constant 10 temperature of 70°C az~d stirred (500 rpm) while a 3O~S
..
solution of PEG was added (7 ml) unt~.l phase separation had ocGUrred, the system was st,~.~red for furt~a~r 1~ mihutes before it was cooled ~n ice during constant ~i~i.r~ing. The micros~heres were then isolated by filtr tion and freeze' z~ dried.
With a stixr~:ng sped of 500 rpm particles with a ~e~n s~.ze o~ 33 ~Cm ~ x0 dam was prcaduced, 2Q Pre station of elating micros heres usin a coae~r~r~ti.on techniaue 30 ml 1~~ bovin gelatine (pH=8<5) Was;'kept at a oonstant temperature of 50°C and stirred (500 rpanj while a 30o solution of PEA was added (20 ml) until the 2~ coacervation region was reached. To control this step-a nephelometer can be used. The mixture was cooled on ice during constant stirring. The microspheres were isolated by filtration and freeze dried.
w~ ~~~~s~~~ . ~ . pc°r~~~9~ioozzs :, :.
With a stirring speed of 500 rpm particles with a mean size of &0 ~cm 1- 10 ~cm was produced.
Pre aration of albumin micros heres usin an emulsion technicrue 100 ml olive oil was mixed with 0.S-2 ml 25o HSA
solution and the mixture was stirred for 15 minutes at 500-1000 rpm to form a w/o-emulsion. Solidification of the albumin~droplets can be done either by the add~aion of 0.1-0.4 ml 25% glutaraldehyde and letting this react with the albumin for 15 minutes, or by'heating the system to 90°C
fc~x 30 minutes. In either base the micrasphexes are isolated by filtration; washed and freeze elrie.d.
A stirring speed of 700 rpm gives a mean particle size of 53 ,gym ~ 11 ~crn.
Preparation of gelatine microspheres usinq_ an emulsi~~n technictue 100 ml olive oil (70°C) was mixed with l0 ml 5-10%
gelatine solution and the mixture was stirred at 500-1500 rpm keeping the temperature constant at 70°C, the emulsi~n is stirred f'or 15 minutes and was then cooled on ice during constant stixring. The microspheres were isolated by filtration; washed and freeze dried.
A concentration of 10% gelatine and a stirring speed of 1000 rpm gives a mean particle size of 70 ~,m ~ 8 Vim.
V6~~ 93/i5737 ~ ~ ~ P(.'T/~~93/00228 Preparation of Chitosan microspheres Chitosan microspheres were prepared by an emulsion technique as follows .
Chitosan, as for example a glutamate salt (70% degree of deacetylation), was dissolved in water to a concentration of 5% w/v. 100 ml soybean oil was mixed with 1o ml of the 5 % Chitosan solution to form a water in oil emulsion. The microspheres were stabilized by adding dropwise 0.1 ml of a ~5% w/v glutaraldehyde solution under ~ r. ., continual stirring foi I5 minutes. The microspheres were isolated by centrifugation, washed and freeze-dried. The size of the microspMeres wasp in the range of 10-90 Vim.
The microsphere~ obtained may be sieved if necessar~r in order to separa~ce out. microspheres in a desir~:d sire range. Other size separation techniques (air elutriation).
may also be employed. The final miGrospheres can be modified by chemical cross-linking or heat treatment.
Suitable cross-linking agents for use with starch microspheres include epichlorohydrin, terephthaloyl chloride and sodium trimetaphosphate.: Suitable agents for use with albumin microspheres include aldehydes such as formaldehyde and glutaraldehyde, ~xidised dextran ("dextranox") and 2,3-butanediose, the latter also being suitable for use with gelatin microspheres~. Agents such as N,N,Ni,N'-tetramethylethylenediamine can be used with dextran ~microspheres. The morphine metabolite can be iy~ 93,~5~f~ ~~ 14~~ ~ o ~; ~ ' F'C~'/G~9310~22~
~. 6 incorporated into the microspheres during their preparation or sorbed into/onto the system after preparation. The effectiveness of the system can be controlled by the physical nature of the microsphere matrix and, for example, the extent of cross linking.
As an added advantage the particles may have variable controlled release characteristics through modifications made to the micras~here system, for example by controlling the degree of ,cross-linking or by .the incorporation of ..
excipients that alter the diffusional propertiesv of the administered drug ar by using mechanisms based on ion--exchange for metabolites that ~~e ion~.z~lale in ague~us environments: F'or example D~AE-dext~can and chitosan are Positively charged and can .be used for art .z.~x~-excl~enge inte~actic~n with metabolites that are negatively cY~arged.
The amount bf drug that can be carried by the micros~heres is ter~n~d the loading capacity, w~~aich i~ deter~na:ned by the phy~i.c~~-c~emica~, properties of the drug molecule and in particular its size and affinity for the particle matrix.
Higher loading capacities are to be expected when the administered drug is incorporated into the microspheres during the actual process of microsphere manufacture.
Microcapsules of a similar sire, which are bioadhesive anc~
~aha,ch have controlled release p~a~pertaes y ox any microcapsule which provide similar absorption promoting effects may also provide similar benefit as an absorption W~193/ 15737 ~c-rm~93/oozz~
promoting agent. These microcapsules can be produced by a variety of methods. The surface of the capsule can be adhesive in its own right or can be modified by coating methods familiar to those skilled in the art. These coating materials are preferably bioadhesive polymers such as polycarbophil, carbopol, DEAF°dextran, alginates, or chitosan. Other bioadhesive powdery materials such as microcrystalline cellulose, dextrans and polycarbophils may also be used.
l0 s;,..
Surface active agents wh:~.ch are suitable include bile salts such as sodium deoxycholate and cholylsarcosine (a synthetic N-~acyl co~ajugate off: cholic acid with. sa~cosir~e 15: [N-methylg~lycine]), and derivatives such as sodium taur~
dihydrofusidate, non-ionic surfactants, such as laureth-9 (polyoxyethylene -9 lauryl ether), phospholipids and lysophosphatidyl compaunds such as lysol~cithin;
lysophosphatidyl-ethanolamine, lysophOSphatidylcholi.ne, 20 lysophosphatidyl~rlycerol, lysophospha~idy3.serine, lysophosphat~:dic acid etc. Other phospholipid compgunds soluble in water can be expected to demonstrate similar effects, for example short chain phosphatidylglycerol and phospfiratidylcholines. A suitable concentration is from ~25 0.02 to 109. Phospholipids and lysophosphatides are preferred absoprtion promoting materials. Lysophosphatides ale produced by the hydrolysis of phospholipids. Sudh materials are surface active and form micellar structures.
vvr~ ~3e~s73~ ~~e~~~3eoox2s 2~~°~g~~ is Lysophosphatidylcholine, which is produced from egg or soy lecithin, changes the permeability of membranes and allows the increased uptake of proteins and peptides including, for example, insulin, human growth hormone and ~5 other products of biotechnology and recombinant DNA
methodologies. After administration the lysophosphatides are converted by the cells of the endothelial lining of the mucosa to the intact phosphatides which are normal cell camponents. (Lysolecithin itself is alsr~ present in cell membranes in very small. quantities:) This rapid and ..
efficient conversion of lysophosphatides into the complete phosphatide structure leads to much reduced adverse reactions and site effects in terms of irritati~n and toxicity.
1~
9ther lysophosphatidylcholines that have different aryl groups as well as lyso compounds produced from phasph~atidylethan~lamines, phosphatidyl~lycerols aid phbsphatidic acid which have similar; mom~rran2 m~difying 2o properties may be used. Water soluble phospholipids with short acyl chains will also be appropriate since these are surface active. Acyl carnitines ~e.g. p~lmit~yl-~L
carnitine~chloride) are an alternatives Other materials include acyl-~carnitines, acyl glyco~°ols, non-conic 25 surfactants, fatty acids and salts (see for example list in Nearly, Crit.. Rev.,The. Drug Carrier Systems, 8:331-394 (1.9~1~, Table 2), glycyrrhetinates and, biological detergents listed in the SIGMA catalog, 188, page 316°-32~..
VV~CD 93/15737 P~'/G~93/0~228 ~ '~~
Also agents that modify the membrane fluidity and permeability would be appropriate such as enamines (e.g phenylalanine enamine of ethyl-lacetoacetate), malor~ates, (e. g. diethyl-eneoxymethylene malonate), salicylates, bile salts and analogues and fusidates. Suitable concentrations would be up to 100.
Examples of suitable chelating agents are EGTA, EDTA
and alginates. Suitable mucolytic agents include thiol-containing compounds such as .N-acetylcysteine and ,,: -~.
tyloxapol. Examples of suitable cyclodextrins are cc-cyclodextrin, dimethyl-/3-cyclodextrin; (3-cyclodextrin, hydroxypopy~:-~3~-cyclodextra.n; y-cyclodextrin; and hydroxypropyl-~3~-cyclodextrin. Suitable peptide inhikaitors ~5 include a~tinonin, amasta~in-, antipain, bestatin, chloroacetyl-HO-Leu-Ala-Glyn~-NH2, diprotinin A and ~, eb~lactone A and H, E-E,4, leupeptin; pepstatin A, p~osp~oramidon, H-~. _(tHu)-Pie-Pro-OH, aproti.nin, kal.likreira, chymostatin, ben~amidine, chymcitrypsin;
trypsih. Suitable concentxat~.ons would be from 0.01 to g~~
For morphine-~-sulphate, is is also possilale to use structures complementary in charge and size that will complex with the molecule and thereby facilitate uptake across the nasal mucosa. Examples of suitable agents are betaines, alkyl alpha picol,inium bromides, amino acids such . as arginine and homoarginine hydr~chlorides, labile quarternary ammonium salts, for example as described in US
CVO 93/1S737 PCT/~~93/0~22~
~1~~'~0~ ~ r 20 4,140;796, ion-pairing agents for anionic drugs for example those described by ,7onkman and Hunt, (1983) Pharm Weekblad.
Sci. Ed. 5 42 and N,N,dialkylpropionamides.
Preferred absorption promoting agents for use with both morphine-6-sulphate and morphine--6-glucuronide are bioadhesive miGrospheres, especially starch microspheres, or a lysophospholipid such as lysophosphatidylglycerol.
Further preferr~~l materials for use wath morphine-6-glucuronide are chitosan and chelating agents such as EDTA..
C~ampositions according to the invention can be administered by any appxopri:a a method acc~rding to their form. A comp~sition comprising microspheres or a powder 3.5 can be administered us~,ng a nasal insufflator device.
Example of these are already employed ,for commercial powder systems intended for nasal application (e.e~. Fisans Lomudal g~~tem).
The a.n~uf f lator produces a f finely divided cloud of the dry powder or microspheres. The insuff later i~ pref~rab~:y provided with means to ensure administration of a substantially ffixed amount of the composition. The powdex or microspheres may be used directly with an insuf f lator 25 which is provided with a bottle or container for the powder or micrpspheres. Alternatively the powder or microspheres may be filled into a capsule such as a gelatin capsule, or other single dose device adapted for nasal administration.
rV~ 93/5737 PC,°f/G~93J0022~
~~.~~0.~
The insufflator preferably has means to break open the capsule or other device. .
A composition comprising a solution or dispersion in an aqueous medium can be administered as a spray using an appropriate device such as a metered dose aerosol valve or a metered dose pump. A gas or liquid propellant can be used. Details of other devices can be found in the pharmaceutical literature (see for. example Bell, A.
Tntranasal Delivery Devices, in Drug Delivery Devices v, fundamentals and A lications T Ie P.
pp . y (ed), Dekker, New York, 198), Remington's Pharmaceutical Sciences, Mack Publishing Co., 1975.
The invention will now be further demonstrated with reference to the following example.
Exatno 1 a 1 ~x~eramental details Morphine 6°-glucuronide purchased from Ultrafine chemicals, Salfard, UK, was mixed in solution with the polycationic material chitosan, obtained from Frotan Ltd df medium viscosity grade. The dose of morphine-6-glu~uronide was 0.1~ mg/kg, The chitosan concentration was 0.X4. The solution was administered into the sheep nostril using a simple spay pump device followed by serial blood sampl~.ng.
The appearance of the morphine-6-glucuronide in the plasma was followed by taking serial blood samples, removing the WO 93/15737 ~~_ PC°f/G~93>00228 red cells then assaying plasma samples for morphine s-glucuronide. Control experiments were conducted using i.v.
dosage of the glucuronide.
Dosinca Three anima3.s (labelled NF, CAF, PF} were given morphine--6-glucuronide intravenously as a bolus of 0.015 mg/kg and a further three animals (labelled IF, JF, KF) received nasally administered morphine-6~-glucuronide at a 10, dose of 0.15 mg/kg. Blood samples (10 ml) were taken at the following times.
PredoSe,-2, 5, 10, 15, 20, 30r 45, ~Or 90, 1:20, x.50, 180; 240, 3t?0, 360 minutes.
P~.asma was separated by centrifugation soon after sampling and the plasma samples (approximately 5 ml) wexe stored at ~-80°C prior to analysis:
2a Assay fc~r a~or~hine-6-~uronide in gl~sma Plasma concentrations of morphine--6-glucuronide were determined by an improved method based an the published procedure of Svennson et a1 (1982) J. Chromatog. Biomed.
25 Appl. 230, 427. The method involves solid phase extraction of morphine-6-glucuronide from the plasma sample followed by high-performance liquid chromatography analysis using electrochemical detection. The limit of quantification of 'hU~CD 93/i5737 ~I ~ PCCf/C~~393/00228 the method is 1 ng/ml far a 0.5 m1 plasma sample and the assay is linear over. the range of 1 to 1200 ng/ml drug concentration.
During the period of analysis a seven point plasma standard calibration line (1. to 240 ng/ml) was routinely run on each day, Quality control samples consist~.ng of sheep blank plasma spiked with known amounts of morph~.ne-6-glucuronide were prepared in advance and stored at -20°C.
1.0 These wire analysed with the 'study samples ora each day:
C~~.aulatioa~ ~f ~a3asma ~~ncen~tration Plasma m~xphir~e~6~glucur~nide concentrations wage calculated by interpolation from a calibration fine ~~uata~n fitted by linear regression analysis: Morphine-C
glucuronide plasma concentrations of less than ~. ng/m~, were regarded as not quantifiable within the limit of preci~ioz~
and accuracy 'of the assay:
2p pharm~co~e~r~etic calculations The plasma concentration of morphine-6-g~aacuroa~ide vez°~u~ time after admina.stration of 'the four formulations was characterised in terms of the maximum observed concentra~.i.~n (Cmax), the time at which Cmax occurred (Tan~x) . The area under the curve (AUC) was calculated over 0-300 minutes using the linear trapezoidal methoei'. The AUC
values for the intravenous administration were normalised to the 0.15 mg/kg nasal dose for the calculation of W~ 93/i5737 ~ ~ ~ ~ ~ P(.'T/G~93/0~228 bioavailability. The validity of this normalisation assumes linear kinetics for morphine-6-glucuronide up to a 0.15 mg/kg intravenous dose. Clearance was calculated by dividing the dose by the AUC, and the volume of -5 distribution was calculated by dividing the clearance by the elimination rate constant. The bioavailability was calculated by dividing the mean AUC for nasal administration by the normalised mean AUC after intravenous administration.
z~
a ~..
ReSbilt~
Plasma-concentration, tame ~da~t~
The plasma concentrations of morphine-6-glucuronide in the plasma samples resulting from the intravenous and nasal 15 doses are~reported in Tebles l and 2 respectively.
No morphine Haas detected in any. of the plasma samples (limit of detection 1 ~nglmlj~
20 pharaaaoolcix~et~.c analysis The pharmacokinetic~ parameters calculated from the plasma concentration data after intravenous a~ad nasal doses are shown in Tables 3 and 4 respectively.
25 Bioawailability The mean nasal bioavailability was calculated to be 32.3% (n=3j.
i~~ 93115737 ~ ~ PsCl'/~~93f0~228 2 5 ., PLAS~LA
CONCENTRATIONS
AFTER
INTRA'~7ENOUS
AI~I~iINISTRATTON
morphine-6-glucuronide concentration (ng~ml) SHEEP NF S~I~~P OF SHEEP PF
Time (min) Predose na nd nd 2 43.8 ~ 3?.9 4~.5 5 40>3 54.? 34e6 ZO 1.0 36.1 4?:0 31>8 ~5 z8.6 3?.3 28.5 23.z 41:7 29.8 zz.5. 3z.Z 24.3 ~5 13.4 30.3 z0:0 ~:5 6 0 12 : 0 z 5 . 0 14 . ?
90 9:4 1?.7 11.6 1.20 5.6 i2.6 8.6 150 3.5 7.3 3,5 180 2,~ 3.8 3.,9 , ~~ z4~ n~ i. s x..~ .
3 0 n d nd ~~~
3 6 , n~ n~ ~a WO 93/15737 PC°Jf'/G~93/00228 ~~.I~Q'' PLASMA CONCEI~1TRATI02~TS AFTER NASAL .AbI~IINISTRATION
morphine-6--g~.ucuranide concentration (ng/ml) Time (min) Predoss nd nd nd ~d 13.3 17.1 5 21.8 50.5 65.3 10 89.1 165.3 1~9.3 ~ ,..
121.4 154.8 110.3 .
1~~..9 1.22.5 94:9 3O 107.2 x.05.5 ~ 8~.9 45 18.5 83.6 735 5.5 6~ ' 66.7 64.9 x.5.7 90 41.1 ' 41.3 29.3 120 2L.9 29.2 19.1 .
15O 16.0 25.9 12:7 180 10.2 10.0 6.3 ~~ 24~ 2.7 6.9 3;0 300 nd 2~~ nd 3 6 (7 nd nd na nd = not delectable (less than 1.O ng/ml) W~ 9311737 ~
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Example 2 A bioadhesive powder formulation of morphine-6-glucuronids was prepared using microspheres of cross-linked starch. The microspheres were prepared by the method described in GB 1.518121. or EP 223302 described above. A
preferred size of microspheres is 1-100 Vim.
75 mg of morphine-6-glucuronide was d~.ssolved in 30 ml water and mixed with 1 g of starch rnicrospherds. ~'he product was freeze-dried to produce ,a free f lowing powdery The final concentration of morphine anetabolite in the product was 0.075 mg/mg of search microspheres.
The powder was administered to the nasal cavity using .15 an insufflator device. The quantity administered was 2.0 mg microsp.heres per kg body weight c~ntaining 0.15 mg morphine-6~g~ucuronide.
Ex~an 2~ A bioadhesive powder formulation of morphine-6-sulphate was prepared using microspheres of cross-l~.nked starch. The microspheres were prepared by the meth~d described in G~ 155.8121 or EF~ 223302 descra.bed above. A
preferred size of microspheres is 1-100 ~,m.
75 mg of morphine-6-sulphate was dissolved in 30 ml water and minced with 1 g of starch microspheres. The product was freeze--dried to prodmce a free f lowing powder.
wo ~3r~s~~~ ;,~- ~c.°rr~~~~ro~228 The final concentration of morphine metabolite in the product was 0.075 mg/mg of starch microspheres.
The powder was administered to the nasal cavity using 5 an insufflator device. The quantity administered way 2. C1 mg microspheres per kg body weight containing 0.15 mg morphine~5-sulphate.
Exam~~le ~
.0 The bioadhesi.ve ~icrosphere system described in Examples 2 and 3 were palpated but in addition an . ~ absorption enhancing agent was employed A preferred material is lys~phosphatidyl glycerol (LPG). 30Q m,g hpG
was added to the su~pensior~ cof the morphine znetabol~ae and la . macrosphe~es. the fxee~e dried prcadu~~ was administered mss' a powder as in Example 1 end 2. The ffinal quanta.ti~s of morphine-6-gl~curonide or morphine-6-sulphate and enhanca.r~g agent were 7.5 mg and 10 ~ng; respe~ti.vely in a 1.00 zng dose of microsphere~:
Exams ~. a 5 p~ liqua.d fo~nulation vsimilar to that described ~n Ea~amp3.e 1 eras prepared with added absorptit~n 'enhancing agent as f~llows.
3~O mg o~ morphine-6-glucuronide was~dissolved in 30 ml of a ~.5% solution of medium viscosity grade of Chitos~n degree of deacetylation, Protan Limited). The ewo ~3ms~a~7 ~~s~~~~iv~zx~
substituted cyclodextrin material dimethyl-~3-cyclodextrin (Sigma Chemical Comp) was added to provide a concentration of 5%. 'The liquid formulation was administered using a conventional pump spray device.
Exaznp 1 a 6 The formulation described in Example 5 was prepared but in the place of the dimethyl-a--cyclodextrin, ~~-cyclodextrin (Sigma Chemical Co.) at the same concentration of 50 mg/ml was added.
l .. .
EI~ZI~lC1 Z ~ 7 The mierosphere formulation described in Eac~mple ~ eras.
prepared but instead of the enhancing agent a chelat~~g 1~ ~g~n~ in the f~rm of ED~'R wa s ~mplo~red > 50 mg of ED~'A' ~~s added to the su~pei~sion of morphine metabo~.ite anew macrospheres, The product was freeze dried as before in Example 2. The fina3, quantities of morpha.ne-6-~luc~xroriide and claei~tinc~ agent ire 7:5 mg and 5 mg, 'respecti.vely in a ZQ 1~0 mg dose of ma.crospheres administered to sheep.
The partition coefficient of morphine, expressed as a logarithm (loge) partitioned between an aqueous buffer and octanol ranges from 0.70 to 1.03 (Hansch C. and Leo A.
°'Substituent constants for Correlation Analysis in Chemistry and Biology" Wiley, New York, 1979). The polar metabolites of morphine will~therefore have a lower loge value than that of morphine. The major metabolites of morphine are morphine-3-glucuronide,(M3G) and morphine-6 ~~ glucuronide (M-6G). Formation of the ethereal sulphates at positions 3 and 6 in the molecule may also occur.
Morphine-6-sulphate which d~.ffers from morphine itself by having an ionizable group off: Carbon-6 at physioa.ogical pH
has been shown to be a more potent analgesic than morphine following intracerebroventricular administration in mice (Brown e~ a1 (1985) J. Pharm. Sci: 74, 821). Morphine-6-sulphate and a number of its 3-O-acetyl derivatives exhibit potent antinociceptive activity in the rat when given by subcutaneous injection (Houdi, et al (1992) Pharm. Res. 9 s-z~3).
The structures of morphine-6-glucuronide and morphine-6-sulphate are shown below .
W~ 93/ ~ 5737 PdC1'/~1393/0022~
M
r G~3 0 '~-~3 C coo t-( I t C,~ J-t p ~- S ~.- ~
t~ J I
~H H O
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morphine-6~glucuronide morpha.n~-~-sulphate The ab~orpti.~n pr~motinc~ agent should be such that it pr~vid~s therapeutic hovels of m~taboli.te in the plasma ~~th an absorption efficiency of greater than 10°~ acrd p~'eferably gx°~ater than 30%. '~h~ absox~ptian is measured in .
germs of the bioavail.ab~lity, wh5.eh ~.s defined as the ratio of the quaratit~ of metabolite appearing a:n the blood after intranasal a~i~aa.ni~tration compared try that found after intravenous ad~ai.nistration, expressed as a percertta~e.
The therapeutic level of the metabolite acha.eved should be a plasma concentration that is at leash a~
eguipotent as the level ree~ui,red for the opi~id anal~esi.c for anal.geaic effect. For morphine, the usual therapeutic levels in plasma are from 1-500 ng/ml, and more typically 20-100 ng/ml. Data have indicated that, for example, W4 93/15737 ~'C.'T1G~9310022~
morphine--6-glucuronide and morphine-6-sulphate could be many times more active than morphine. Thus the required therapeutic levels of morphine-6-glucuronide and morphine-6-sulphate may be in the same range as those ~or morphine or they may be much lower and it is the potency that will decade the required concentration. Although more work is required in this area, morphine-6-glucuronide and morphine-6-sulphate levels may be expected to be in the region of two times less vthan those of morphine to give the same pain relief effect.
y ,..
The composition of the ~inventi.on may be used for pain relief in a variety of situations but especially to relieve chronic pa~.h in terminal cancer patients, f~r acute pain, for example after dental surgery and for other gost-~
operative pain.
The absorption promoting agent is desirably a cationic polymer, a bioadhesive agent, a surface active agent, a 2~ fatty acid, a chelating agent, a mucolytic agent, a cyolodextrin or combinations thereof or a microsbhere preparation, and may be present in the composition as a solution in an aqueous medium, a dispersion in an aqueous medium, as a powder or as microspheres. The terms used here are not intended to be mutually exclusive.
Chitosan, a cationic polymer, i.s a preferred absorption enhancex. Chitosan is deacetylated chitin, or i~V~ 931573'7 ~ ~ ~'"~ .~ ~ ~ . Pt:.T/G~93/8~z28 poly-N-acetyl-D-glucosamine. It is available from Protan Laboratories Inc, Redmond, iJashington 98052, USA and, depending on the grade selected, can be soluble in water up to pig 6Ø A 1% solution of non-water soluble chitosan (sea Cure) may be made by making a slurry (eg 2g/100 m1) in water and adding an equal volume of organic acid (eg 100 ml of 2% acetic acid) and stirring vigorously for one hour.
Water-soluble chitosan (Sea Cured) may dissolve without organic or inorganic acids being present. The chitosan tray also be used as chitosan microspheres.
.,..
ehitosan has previoushy been used to precipitate proteinaceous material, to make surgical sutures and as an ixxnmmunostimu~.ant. It has also been employed previously in 15. oral drug formulations in order to improve the dissolution of poorly soluble drugs (Sawayanagi e~ a1, (1983) Chem.
Pharm. dull., 31, 2062-268) or for the 'sustained release of drugs (I~agai ef al, Proc. Jt. LJS- Jpn. Semin. Adv.
Chitin, Chitosan, Relat. Enzymes, 21-39. Zikakis J.P.
2~ (ed), Academic Press. Orlando (1984)) by a process of slow erosion from a hydrated compressed matrix.
I7iethylaminoethyl-dextran (DEAE-dextran) is also suitable and is a polycationic derivative of dextran 25 containing diethylaminoethyl groups coupled to the glucose residues by ether linkages. The parent dextran can have an average molecular weight of about 5,000 to ~0 x 106, but is typically about 500,000.
W~ 93/15737 PCf/G$9310022~
a Further cationic polymers which may be used in the compositions of the invention include other polycationic carbohydrates such as but not limited to inorganic or organic salts of chitosan and modified forrns of chitosan (especially more positively charged ones), polyaminoacids such as polylysine, polyquaternary compounds, protamine, polyamine, DFAE-imine, polyvinylpyridine, polythiodiethyl-aminomethylethylene (P(TDAE)), polyhistidine, DFAE-methacrylate, DF:AE-acrylamide, poly-p-aminostyrene, l0 polyoxethane, co-polymethacrylates. (e:g. copol,ymers of ~_~ ..
HPMA, N-(2-hydroxypropyl)-methacrylamide, GAFQUAT (US Pat i~o 3,910,62) and polyamidoamines. The polycatioraic substances used in the invention. typically hive a mol.ec~alar 'weight" of 1~J OOO or more. 7Che chitosan (or salt thereof) 15. preferably has.an intrinsic viscs~sity of at lest ~~0 ml~g. .
more pr~efer~bly at lest 50~, 750 or 1000 ml/g.
The co~ncentl: anon of the Galri~nic p~lymer ira a solution is preferably 0.01 to 50% w/v, more preferably O.I.
20 to Sop and more preferably 0.2 to 30~>
Amongst 'the bioadhesive agents suitable for use are included bioadhesive microspheres. ~ Preferably the microspheres are prepared from a bio-compahible material 25 that will gel in co~atact with the mucosal surface:
Substantial~.y uniform .sol~.d microspheres are preferred.
Starch microspheres (drosslinked if necessary) are a preferred material. Other materials that can be used to W~ 93/15737 ....~ ~~. :~ ~CH'/~~~3/00228 form ~microspheres include starch derivatives, modified starches such as amylod~:~arin, gelatin, albumin, collagen, dextran and dextran :ae:-ivatives, polyvinyl alcohol, polylactide-co-glycolide, hyaluronic acid and derivatives thereof such as benzyl and ethyl esters, gellan gum and derivatives thereof such as benzyl and ethyl esters and pectin and derivatives thereof such as benzyl and ethyl esters. By the term °°de~ivatives°° We particularly mean esters and ethers of the parent compound that can be 1c9 unfunctionalised or functionalised to contain, ~or example, ..
l.onlc gr~UplnCJa .
Suitable starch derivatives include hydroxyethyl starch, hydroxypropyl starch, carb~xymethyl starch, ~:5 cationic starch, ~cetylated starch, phasphorylateci starch, succzraate derivata.ves of starch and grafted starches : Such starch derivatav~s are well known and described in the art (for example Modified Starches: Properties and Uses, O.E.
Wurzburg, CRC PreSS BOGa Raton (1986)).
Suitable dextran derivatives include, diethylaxninoethyl-dex~rara (D~AE-dextran) , dextrara sulphate, dextran methyl-benzylamide sulphonates, dextran methyl-benzylamide carboxylates, carbo~ymethyl d~xtran, diphosphonate deactran, dextran hydrazide, palmitoyldextran and dextran phosphate.
Preparation of these microspheres is well described in ~V~ 9~/~5'737 '~ P'C.'flC~9~/00228 2~.~~~U~ 10 the pharmaceutical literature (see for example ~avis et a.i . , ( Eds ) , °°Microspheres anc~ Drag Therapy°° , Elsevier Biomedical Press, 1984, which is incorporated herein by reference). Emulsion and phase separation methods are both .5 suitable. For example, albumin microspheres may be made using the water-in-oil emulsification method where a dispersion of albumin is produced in a suitable oil by homogenization techniques or stirring techniques, with the addition if necessary of small amounts ~f an appropriate surface active agent. The size of the microspheres is .., .
largely di.ctated.by the speed of stirring or homogenization conditions. The agitation can be provided by a sample laboratory st~:rrer or by more sophisticated devices such as a microfluidizer or homogenizer. Emulsification techniques are also used to produce starch microspheres as described in ~B 1 518 121 and EP 223 30~ as well as for the preparation of microspheres of gelatin. Proteinaceous microspheres may also be prepared by coacervation methods such as simple or complex coacerva~ion or by phase separation techniques using an appropriate solvent or electrolyte solution. Full details of the methods of preparing these systems can be obta~.ned from standard text books (see for example Florence and Attwood, Physicochemical Principles og Pharmacy 2nd Ed., MacMillan Press, 1988, Chapter 8).
For example, microspheres were prepared as follows:
W~ 93/15737 ~ P~'1G~93/0022~
The pret~aration of starch micros hares usin emulsification A loo starch gel was prepared by heating (70°c) 5 g of starch with 40 ml of water until a clear gel was formed.
After cooling water was added to a volume of 50 ml. 20 ml of the starch gel was added to 100 ml of Soya oil containing antioxidant and lm v/v Span 80 and homogenised at 7000 rpm for 3 minutes» This emulsion was added to 100 ml hot (80°C) Soya oil BP (cantaining antioxidant) and stirred at 1500 rpm while heated to 115°C over 15 minutes.
The emulsion was left stirring at 115°C for 15 minutes and y , ..
then rapidly cooled. 100 ml of acetone was added and the microspheres were centrifuged at 4500 rpm for l5 minutes.
They were then washed with acetone and air dried. The microspheres can be separated into the desired size 25 fraction (for example 1~-10 ~,m) using appropriate sieves.
Pre aration of h aluronic acid ester micros hares b solvent extraction An emulsion was formed by mixing a 6%~w/v solutipn of 2o the polymer eg benzyl hyaluronic acid ester fHyaff - 11) in dimethylsulphoxide with white mineral oil containing 0.5%
Arlacel A. The inner phase was added to the outer oil phase (their respective ratio ~aeing 1 . 16 v/v) with continuous stirring for 10 minutes. (1000 rpm). Ethyl 25 acetate, the extraction solvent, was then 'added to the emulsion at a retie of 2.: 1 v/v. The extraction proceeded for 15 minutes at a stirring rata of 700 rpm until the microparticles were formed. The microsphere suspension was 'W~ 93/15737 , . PC'T/~B9310022~
filtered and extensively washed with n-hexane and dried.
Drug can be incorporated into the microspheres by addition to the initial polymer solution.
The obtained microsphere size was 2-l0~axn.
The re aration of alb~.xmin micros hares usin an emulsification technique and heat stabilisation 100 ml Soya oil was mixed with 1 ml of a 10a albumin volution and homogenised ~t X000 rpm. The emulsion was ..
added to 200 ml soya o:~l at 50 °C and stirred at 1500 rpm.
.' The emulsion was heated to 120 °C and equilibrated for 20°C
at this temperature> The'micr~spheres were cooled to room temperature end washed with-pets~leum ~~her, fo~:lowed by 1.5 ethanol and acetone. They were then filtered and,driedo t~icrospheres of ~.-~:0 ,um were obtained.
Preparation of Albumin microspheres usincr a coacervata~ean technir~ue 10 ml 25o HSA solution (ph=5) was stirred (500rpm~
while a 30o solution of PEG was added (2.5 ml) until phase separation occurred. The system was stirred for l5 minutes before the albumin dr~plets was solidified by sl~wly heating the mixture to 90°C and keeping it at this temperature for 30 minutes. Instead of heat denaturati~r~, glutaraldehyde can be used to crosslink ache albumin but this latter method seems to make the particles aggregate to ~ greater extent khan that seen with the heat denaturation.
~WC~ 93/15737 ~ ~ ~ ~ ~ ,~ F(.'T/G~93/002Z~
~3 The m~icrospheres were then isolated by' filtration and breeze dried.
With a stirring speed of 500 rpm particles with a mean size of 43 um -!- 6 ~.m was produced.
Pre aration of soluble otato starch micros hers usin a coacervation technique ml 5% starch solution (pH=7) was kept at a constant 10 temperature of 70°C az~d stirred (500 rpm) while a 3O~S
..
solution of PEG was added (7 ml) unt~.l phase separation had ocGUrred, the system was st,~.~red for furt~a~r 1~ mihutes before it was cooled ~n ice during constant ~i~i.r~ing. The micros~heres were then isolated by filtr tion and freeze' z~ dried.
With a stixr~:ng sped of 500 rpm particles with a ~e~n s~.ze o~ 33 ~Cm ~ x0 dam was prcaduced, 2Q Pre station of elating micros heres usin a coae~r~r~ti.on techniaue 30 ml 1~~ bovin gelatine (pH=8<5) Was;'kept at a oonstant temperature of 50°C and stirred (500 rpanj while a 30o solution of PEA was added (20 ml) until the 2~ coacervation region was reached. To control this step-a nephelometer can be used. The mixture was cooled on ice during constant stirring. The microspheres were isolated by filtration and freeze dried.
w~ ~~~~s~~~ . ~ . pc°r~~~9~ioozzs :, :.
With a stirring speed of 500 rpm particles with a mean size of &0 ~cm 1- 10 ~cm was produced.
Pre aration of albumin micros heres usin an emulsion technicrue 100 ml olive oil was mixed with 0.S-2 ml 25o HSA
solution and the mixture was stirred for 15 minutes at 500-1000 rpm to form a w/o-emulsion. Solidification of the albumin~droplets can be done either by the add~aion of 0.1-0.4 ml 25% glutaraldehyde and letting this react with the albumin for 15 minutes, or by'heating the system to 90°C
fc~x 30 minutes. In either base the micrasphexes are isolated by filtration; washed and freeze elrie.d.
A stirring speed of 700 rpm gives a mean particle size of 53 ,gym ~ 11 ~crn.
Preparation of gelatine microspheres usinq_ an emulsi~~n technictue 100 ml olive oil (70°C) was mixed with l0 ml 5-10%
gelatine solution and the mixture was stirred at 500-1500 rpm keeping the temperature constant at 70°C, the emulsi~n is stirred f'or 15 minutes and was then cooled on ice during constant stixring. The microspheres were isolated by filtration; washed and freeze dried.
A concentration of 10% gelatine and a stirring speed of 1000 rpm gives a mean particle size of 70 ~,m ~ 8 Vim.
V6~~ 93/i5737 ~ ~ ~ P(.'T/~~93/00228 Preparation of Chitosan microspheres Chitosan microspheres were prepared by an emulsion technique as follows .
Chitosan, as for example a glutamate salt (70% degree of deacetylation), was dissolved in water to a concentration of 5% w/v. 100 ml soybean oil was mixed with 1o ml of the 5 % Chitosan solution to form a water in oil emulsion. The microspheres were stabilized by adding dropwise 0.1 ml of a ~5% w/v glutaraldehyde solution under ~ r. ., continual stirring foi I5 minutes. The microspheres were isolated by centrifugation, washed and freeze-dried. The size of the microspMeres wasp in the range of 10-90 Vim.
The microsphere~ obtained may be sieved if necessar~r in order to separa~ce out. microspheres in a desir~:d sire range. Other size separation techniques (air elutriation).
may also be employed. The final miGrospheres can be modified by chemical cross-linking or heat treatment.
Suitable cross-linking agents for use with starch microspheres include epichlorohydrin, terephthaloyl chloride and sodium trimetaphosphate.: Suitable agents for use with albumin microspheres include aldehydes such as formaldehyde and glutaraldehyde, ~xidised dextran ("dextranox") and 2,3-butanediose, the latter also being suitable for use with gelatin microspheres~. Agents such as N,N,Ni,N'-tetramethylethylenediamine can be used with dextran ~microspheres. The morphine metabolite can be iy~ 93,~5~f~ ~~ 14~~ ~ o ~; ~ ' F'C~'/G~9310~22~
~. 6 incorporated into the microspheres during their preparation or sorbed into/onto the system after preparation. The effectiveness of the system can be controlled by the physical nature of the microsphere matrix and, for example, the extent of cross linking.
As an added advantage the particles may have variable controlled release characteristics through modifications made to the micras~here system, for example by controlling the degree of ,cross-linking or by .the incorporation of ..
excipients that alter the diffusional propertiesv of the administered drug ar by using mechanisms based on ion--exchange for metabolites that ~~e ion~.z~lale in ague~us environments: F'or example D~AE-dext~can and chitosan are Positively charged and can .be used for art .z.~x~-excl~enge inte~actic~n with metabolites that are negatively cY~arged.
The amount bf drug that can be carried by the micros~heres is ter~n~d the loading capacity, w~~aich i~ deter~na:ned by the phy~i.c~~-c~emica~, properties of the drug molecule and in particular its size and affinity for the particle matrix.
Higher loading capacities are to be expected when the administered drug is incorporated into the microspheres during the actual process of microsphere manufacture.
Microcapsules of a similar sire, which are bioadhesive anc~
~aha,ch have controlled release p~a~pertaes y ox any microcapsule which provide similar absorption promoting effects may also provide similar benefit as an absorption W~193/ 15737 ~c-rm~93/oozz~
promoting agent. These microcapsules can be produced by a variety of methods. The surface of the capsule can be adhesive in its own right or can be modified by coating methods familiar to those skilled in the art. These coating materials are preferably bioadhesive polymers such as polycarbophil, carbopol, DEAF°dextran, alginates, or chitosan. Other bioadhesive powdery materials such as microcrystalline cellulose, dextrans and polycarbophils may also be used.
l0 s;,..
Surface active agents wh:~.ch are suitable include bile salts such as sodium deoxycholate and cholylsarcosine (a synthetic N-~acyl co~ajugate off: cholic acid with. sa~cosir~e 15: [N-methylg~lycine]), and derivatives such as sodium taur~
dihydrofusidate, non-ionic surfactants, such as laureth-9 (polyoxyethylene -9 lauryl ether), phospholipids and lysophosphatidyl compaunds such as lysol~cithin;
lysophosphatidyl-ethanolamine, lysophOSphatidylcholi.ne, 20 lysophosphatidyl~rlycerol, lysophospha~idy3.serine, lysophosphat~:dic acid etc. Other phospholipid compgunds soluble in water can be expected to demonstrate similar effects, for example short chain phosphatidylglycerol and phospfiratidylcholines. A suitable concentration is from ~25 0.02 to 109. Phospholipids and lysophosphatides are preferred absoprtion promoting materials. Lysophosphatides ale produced by the hydrolysis of phospholipids. Sudh materials are surface active and form micellar structures.
vvr~ ~3e~s73~ ~~e~~~3eoox2s 2~~°~g~~ is Lysophosphatidylcholine, which is produced from egg or soy lecithin, changes the permeability of membranes and allows the increased uptake of proteins and peptides including, for example, insulin, human growth hormone and ~5 other products of biotechnology and recombinant DNA
methodologies. After administration the lysophosphatides are converted by the cells of the endothelial lining of the mucosa to the intact phosphatides which are normal cell camponents. (Lysolecithin itself is alsr~ present in cell membranes in very small. quantities:) This rapid and ..
efficient conversion of lysophosphatides into the complete phosphatide structure leads to much reduced adverse reactions and site effects in terms of irritati~n and toxicity.
1~
9ther lysophosphatidylcholines that have different aryl groups as well as lyso compounds produced from phasph~atidylethan~lamines, phosphatidyl~lycerols aid phbsphatidic acid which have similar; mom~rran2 m~difying 2o properties may be used. Water soluble phospholipids with short acyl chains will also be appropriate since these are surface active. Acyl carnitines ~e.g. p~lmit~yl-~L
carnitine~chloride) are an alternatives Other materials include acyl-~carnitines, acyl glyco~°ols, non-conic 25 surfactants, fatty acids and salts (see for example list in Nearly, Crit.. Rev.,The. Drug Carrier Systems, 8:331-394 (1.9~1~, Table 2), glycyrrhetinates and, biological detergents listed in the SIGMA catalog, 188, page 316°-32~..
VV~CD 93/15737 P~'/G~93/0~228 ~ '~~
Also agents that modify the membrane fluidity and permeability would be appropriate such as enamines (e.g phenylalanine enamine of ethyl-lacetoacetate), malor~ates, (e. g. diethyl-eneoxymethylene malonate), salicylates, bile salts and analogues and fusidates. Suitable concentrations would be up to 100.
Examples of suitable chelating agents are EGTA, EDTA
and alginates. Suitable mucolytic agents include thiol-containing compounds such as .N-acetylcysteine and ,,: -~.
tyloxapol. Examples of suitable cyclodextrins are cc-cyclodextrin, dimethyl-/3-cyclodextrin; (3-cyclodextrin, hydroxypopy~:-~3~-cyclodextra.n; y-cyclodextrin; and hydroxypropyl-~3~-cyclodextrin. Suitable peptide inhikaitors ~5 include a~tinonin, amasta~in-, antipain, bestatin, chloroacetyl-HO-Leu-Ala-Glyn~-NH2, diprotinin A and ~, eb~lactone A and H, E-E,4, leupeptin; pepstatin A, p~osp~oramidon, H-~. _(tHu)-Pie-Pro-OH, aproti.nin, kal.likreira, chymostatin, ben~amidine, chymcitrypsin;
trypsih. Suitable concentxat~.ons would be from 0.01 to g~~
For morphine-~-sulphate, is is also possilale to use structures complementary in charge and size that will complex with the molecule and thereby facilitate uptake across the nasal mucosa. Examples of suitable agents are betaines, alkyl alpha picol,inium bromides, amino acids such . as arginine and homoarginine hydr~chlorides, labile quarternary ammonium salts, for example as described in US
CVO 93/1S737 PCT/~~93/0~22~
~1~~'~0~ ~ r 20 4,140;796, ion-pairing agents for anionic drugs for example those described by ,7onkman and Hunt, (1983) Pharm Weekblad.
Sci. Ed. 5 42 and N,N,dialkylpropionamides.
Preferred absorption promoting agents for use with both morphine-6-sulphate and morphine--6-glucuronide are bioadhesive miGrospheres, especially starch microspheres, or a lysophospholipid such as lysophosphatidylglycerol.
Further preferr~~l materials for use wath morphine-6-glucuronide are chitosan and chelating agents such as EDTA..
C~ampositions according to the invention can be administered by any appxopri:a a method acc~rding to their form. A comp~sition comprising microspheres or a powder 3.5 can be administered us~,ng a nasal insufflator device.
Example of these are already employed ,for commercial powder systems intended for nasal application (e.e~. Fisans Lomudal g~~tem).
The a.n~uf f lator produces a f finely divided cloud of the dry powder or microspheres. The insuff later i~ pref~rab~:y provided with means to ensure administration of a substantially ffixed amount of the composition. The powdex or microspheres may be used directly with an insuf f lator 25 which is provided with a bottle or container for the powder or micrpspheres. Alternatively the powder or microspheres may be filled into a capsule such as a gelatin capsule, or other single dose device adapted for nasal administration.
rV~ 93/5737 PC,°f/G~93J0022~
~~.~~0.~
The insufflator preferably has means to break open the capsule or other device. .
A composition comprising a solution or dispersion in an aqueous medium can be administered as a spray using an appropriate device such as a metered dose aerosol valve or a metered dose pump. A gas or liquid propellant can be used. Details of other devices can be found in the pharmaceutical literature (see for. example Bell, A.
Tntranasal Delivery Devices, in Drug Delivery Devices v, fundamentals and A lications T Ie P.
pp . y (ed), Dekker, New York, 198), Remington's Pharmaceutical Sciences, Mack Publishing Co., 1975.
The invention will now be further demonstrated with reference to the following example.
Exatno 1 a 1 ~x~eramental details Morphine 6°-glucuronide purchased from Ultrafine chemicals, Salfard, UK, was mixed in solution with the polycationic material chitosan, obtained from Frotan Ltd df medium viscosity grade. The dose of morphine-6-glu~uronide was 0.1~ mg/kg, The chitosan concentration was 0.X4. The solution was administered into the sheep nostril using a simple spay pump device followed by serial blood sampl~.ng.
The appearance of the morphine-6-glucuronide in the plasma was followed by taking serial blood samples, removing the WO 93/15737 ~~_ PC°f/G~93>00228 red cells then assaying plasma samples for morphine s-glucuronide. Control experiments were conducted using i.v.
dosage of the glucuronide.
Dosinca Three anima3.s (labelled NF, CAF, PF} were given morphine--6-glucuronide intravenously as a bolus of 0.015 mg/kg and a further three animals (labelled IF, JF, KF) received nasally administered morphine-6~-glucuronide at a 10, dose of 0.15 mg/kg. Blood samples (10 ml) were taken at the following times.
PredoSe,-2, 5, 10, 15, 20, 30r 45, ~Or 90, 1:20, x.50, 180; 240, 3t?0, 360 minutes.
P~.asma was separated by centrifugation soon after sampling and the plasma samples (approximately 5 ml) wexe stored at ~-80°C prior to analysis:
2a Assay fc~r a~or~hine-6-~uronide in gl~sma Plasma concentrations of morphine--6-glucuronide were determined by an improved method based an the published procedure of Svennson et a1 (1982) J. Chromatog. Biomed.
25 Appl. 230, 427. The method involves solid phase extraction of morphine-6-glucuronide from the plasma sample followed by high-performance liquid chromatography analysis using electrochemical detection. The limit of quantification of 'hU~CD 93/i5737 ~I ~ PCCf/C~~393/00228 the method is 1 ng/ml far a 0.5 m1 plasma sample and the assay is linear over. the range of 1 to 1200 ng/ml drug concentration.
During the period of analysis a seven point plasma standard calibration line (1. to 240 ng/ml) was routinely run on each day, Quality control samples consist~.ng of sheep blank plasma spiked with known amounts of morph~.ne-6-glucuronide were prepared in advance and stored at -20°C.
1.0 These wire analysed with the 'study samples ora each day:
C~~.aulatioa~ ~f ~a3asma ~~ncen~tration Plasma m~xphir~e~6~glucur~nide concentrations wage calculated by interpolation from a calibration fine ~~uata~n fitted by linear regression analysis: Morphine-C
glucuronide plasma concentrations of less than ~. ng/m~, were regarded as not quantifiable within the limit of preci~ioz~
and accuracy 'of the assay:
2p pharm~co~e~r~etic calculations The plasma concentration of morphine-6-g~aacuroa~ide vez°~u~ time after admina.stration of 'the four formulations was characterised in terms of the maximum observed concentra~.i.~n (Cmax), the time at which Cmax occurred (Tan~x) . The area under the curve (AUC) was calculated over 0-300 minutes using the linear trapezoidal methoei'. The AUC
values for the intravenous administration were normalised to the 0.15 mg/kg nasal dose for the calculation of W~ 93/i5737 ~ ~ ~ ~ ~ P(.'T/G~93/0~228 bioavailability. The validity of this normalisation assumes linear kinetics for morphine-6-glucuronide up to a 0.15 mg/kg intravenous dose. Clearance was calculated by dividing the dose by the AUC, and the volume of -5 distribution was calculated by dividing the clearance by the elimination rate constant. The bioavailability was calculated by dividing the mean AUC for nasal administration by the normalised mean AUC after intravenous administration.
z~
a ~..
ReSbilt~
Plasma-concentration, tame ~da~t~
The plasma concentrations of morphine-6-glucuronide in the plasma samples resulting from the intravenous and nasal 15 doses are~reported in Tebles l and 2 respectively.
No morphine Haas detected in any. of the plasma samples (limit of detection 1 ~nglmlj~
20 pharaaaoolcix~et~.c analysis The pharmacokinetic~ parameters calculated from the plasma concentration data after intravenous a~ad nasal doses are shown in Tables 3 and 4 respectively.
25 Bioawailability The mean nasal bioavailability was calculated to be 32.3% (n=3j.
i~~ 93115737 ~ ~ PsCl'/~~93f0~228 2 5 ., PLAS~LA
CONCENTRATIONS
AFTER
INTRA'~7ENOUS
AI~I~iINISTRATTON
morphine-6-glucuronide concentration (ng~ml) SHEEP NF S~I~~P OF SHEEP PF
Time (min) Predose na nd nd 2 43.8 ~ 3?.9 4~.5 5 40>3 54.? 34e6 ZO 1.0 36.1 4?:0 31>8 ~5 z8.6 3?.3 28.5 23.z 41:7 29.8 zz.5. 3z.Z 24.3 ~5 13.4 30.3 z0:0 ~:5 6 0 12 : 0 z 5 . 0 14 . ?
90 9:4 1?.7 11.6 1.20 5.6 i2.6 8.6 150 3.5 7.3 3,5 180 2,~ 3.8 3.,9 , ~~ z4~ n~ i. s x..~ .
3 0 n d nd ~~~
3 6 , n~ n~ ~a WO 93/15737 PC°Jf'/G~93/00228 ~~.I~Q'' PLASMA CONCEI~1TRATI02~TS AFTER NASAL .AbI~IINISTRATION
morphine-6--g~.ucuranide concentration (ng/ml) Time (min) Predoss nd nd nd ~d 13.3 17.1 5 21.8 50.5 65.3 10 89.1 165.3 1~9.3 ~ ,..
121.4 154.8 110.3 .
1~~..9 1.22.5 94:9 3O 107.2 x.05.5 ~ 8~.9 45 18.5 83.6 735 5.5 6~ ' 66.7 64.9 x.5.7 90 41.1 ' 41.3 29.3 120 2L.9 29.2 19.1 .
15O 16.0 25.9 12:7 180 10.2 10.0 6.3 ~~ 24~ 2.7 6.9 3;0 300 nd 2~~ nd 3 6 (7 nd nd na nd = not delectable (less than 1.O ng/ml) W~ 9311737 ~
P(.TfG~93100228 o o ~
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1~'~ 93115737 PCT/GBg3/0022~
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w~ ~~ns7~7 ~ ~ ~.~ g ~ ~ ~crrc~9~rooxx~
Example 2 A bioadhesive powder formulation of morphine-6-glucuronids was prepared using microspheres of cross-linked starch. The microspheres were prepared by the method described in GB 1.518121. or EP 223302 described above. A
preferred size of microspheres is 1-100 Vim.
75 mg of morphine-6-glucuronide was d~.ssolved in 30 ml water and mixed with 1 g of starch rnicrospherds. ~'he product was freeze-dried to produce ,a free f lowing powdery The final concentration of morphine anetabolite in the product was 0.075 mg/mg of search microspheres.
The powder was administered to the nasal cavity using .15 an insufflator device. The quantity administered was 2.0 mg microsp.heres per kg body weight c~ntaining 0.15 mg morphine-6~g~ucuronide.
Ex~an 2~ A bioadhesive powder formulation of morphine-6-sulphate was prepared using microspheres of cross-l~.nked starch. The microspheres were prepared by the meth~d described in G~ 155.8121 or EF~ 223302 descra.bed above. A
preferred size of microspheres is 1-100 ~,m.
75 mg of morphine-6-sulphate was dissolved in 30 ml water and minced with 1 g of starch microspheres. The product was freeze--dried to prodmce a free f lowing powder.
wo ~3r~s~~~ ;,~- ~c.°rr~~~~ro~228 The final concentration of morphine metabolite in the product was 0.075 mg/mg of starch microspheres.
The powder was administered to the nasal cavity using 5 an insufflator device. The quantity administered way 2. C1 mg microspheres per kg body weight containing 0.15 mg morphine~5-sulphate.
Exam~~le ~
.0 The bioadhesi.ve ~icrosphere system described in Examples 2 and 3 were palpated but in addition an . ~ absorption enhancing agent was employed A preferred material is lys~phosphatidyl glycerol (LPG). 30Q m,g hpG
was added to the su~pensior~ cof the morphine znetabol~ae and la . macrosphe~es. the fxee~e dried prcadu~~ was administered mss' a powder as in Example 1 end 2. The ffinal quanta.ti~s of morphine-6-gl~curonide or morphine-6-sulphate and enhanca.r~g agent were 7.5 mg and 10 ~ng; respe~ti.vely in a 1.00 zng dose of microsphere~:
Exams ~. a 5 p~ liqua.d fo~nulation vsimilar to that described ~n Ea~amp3.e 1 eras prepared with added absorptit~n 'enhancing agent as f~llows.
3~O mg o~ morphine-6-glucuronide was~dissolved in 30 ml of a ~.5% solution of medium viscosity grade of Chitos~n degree of deacetylation, Protan Limited). The ewo ~3ms~a~7 ~~s~~~~iv~zx~
substituted cyclodextrin material dimethyl-~3-cyclodextrin (Sigma Chemical Comp) was added to provide a concentration of 5%. 'The liquid formulation was administered using a conventional pump spray device.
Exaznp 1 a 6 The formulation described in Example 5 was prepared but in the place of the dimethyl-a--cyclodextrin, ~~-cyclodextrin (Sigma Chemical Co.) at the same concentration of 50 mg/ml was added.
l .. .
EI~ZI~lC1 Z ~ 7 The mierosphere formulation described in Eac~mple ~ eras.
prepared but instead of the enhancing agent a chelat~~g 1~ ~g~n~ in the f~rm of ED~'R wa s ~mplo~red > 50 mg of ED~'A' ~~s added to the su~pei~sion of morphine metabo~.ite anew macrospheres, The product was freeze dried as before in Example 2. The fina3, quantities of morpha.ne-6-~luc~xroriide and claei~tinc~ agent ire 7:5 mg and 5 mg, 'respecti.vely in a ZQ 1~0 mg dose of ma.crospheres administered to sheep.
Claims (10)
PROPERTY OR PRIVILEGE IS CLAIMED ARE DEFINED AS FOLLOWS:
1. A composition for nasal administration comprising a polar metabolite of an opioid analgesic and an absorption promoting agent.
2. A composition according to claim 1 wherein the metabolite is a glucuronide.
3. A composition according to claim 1 wherein the metabolite is a sulphate.
4. A composition according to claim 2 wherein the glucuronide is morphine-6-glucuronide.
5. A compostion according to claim 3 wherein the sulphate is morphine-6-sulphate.
6. A composition according to any one of claims 1 to 5 wherein the absorption promoting agent is a cationic polymer, a bioadhesive agent, a surface active agent, a fatty acid, a chelating agent, a mucolytic agent, a cyclodextrin, or a microsphere preparation, or combinations thereof.
7. A composition according to claim 6 wherein the absorption promoting agent is chitosan.
8. A composition according to any one of the preceding claims wherein the composition comprises a solution or dispersion of the absorption promoting agent.
9. A composition according to any one of claims 1 to 7 wherein the composition comprises microspheres as the absorption promoting agent.
10. The use of a composition according to any one of claims 1 to 9 for the nasal administration of a polar metabolite of an opioid analgesic.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
GB929202464A GB9202464D0 (en) | 1992-02-05 | 1992-02-05 | Composition for nasal administration |
GB9202464.5 | 1992-02-05 | ||
PCT/GB1993/000228 WO1993015737A1 (en) | 1992-02-05 | 1993-02-04 | Compositions for nasal administration containing polar metabolites of opioid analgesics |
Publications (2)
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CA2127805A1 CA2127805A1 (en) | 1993-08-19 |
CA2127805C true CA2127805C (en) | 2004-03-30 |
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ID=10709891
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
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CA002127805A Expired - Lifetime CA2127805C (en) | 1992-02-05 | 1993-02-04 | Composition for nasal administration |
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US (1) | US5629011A (en) |
EP (1) | EP0625044B1 (en) |
JP (1) | JP3958352B2 (en) |
AT (1) | ATE171872T1 (en) |
AU (1) | AU665806B2 (en) |
CA (1) | CA2127805C (en) |
DE (1) | DE69321458T2 (en) |
DK (1) | DK0625044T3 (en) |
ES (1) | ES2123660T3 (en) |
GB (2) | GB9202464D0 (en) |
NO (1) | NO306283B1 (en) |
WO (1) | WO1993015737A1 (en) |
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IT1247472B (en) * | 1991-05-31 | 1994-12-17 | Fidia Spa | PROCESS FOR THE PREPARATION OF MICROSPHERES CONTAINING BIOLOGICALLY ACTIVE COMPONENTS. |
US5266331A (en) * | 1991-11-27 | 1993-11-30 | Euroceltique, S.A. | Controlled release oxycodone compositions |
US5478577A (en) * | 1993-11-23 | 1995-12-26 | Euroceltique, S.A. | Method of treating pain by administering 24 hour oral opioid formulations exhibiting rapid rate of initial rise of plasma drug level |
US20080075781A1 (en) * | 1992-11-25 | 2008-03-27 | Purdue Pharma Lp | Controlled release oxycodone compositions |
EP0865789B1 (en) * | 1993-03-26 | 2005-03-16 | Franciscus Wilhelmus Henricus Maria Merkus | Pharmaceutical compositions for intranasal administration of dihydroergotamine |
US20070275062A1 (en) * | 1993-06-18 | 2007-11-29 | Benjamin Oshlack | Controlled release oxycodone compositions |
US7740881B1 (en) | 1993-07-01 | 2010-06-22 | Purdue Pharma Lp | Method of treating humans with opioid formulations having extended controlled release |
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1993
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- 1993-02-04 JP JP51386993A patent/JP3958352B2/en not_active Expired - Lifetime
- 1993-02-04 AT AT93917408T patent/ATE171872T1/en active
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1994
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NO942787D0 (en) | 1994-07-27 |
GB2277682B (en) | 1995-12-20 |
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GB9413102D0 (en) | 1994-08-31 |
GB2277682A (en) | 1994-11-09 |
ATE171872T1 (en) | 1998-10-15 |
DE69321458T2 (en) | 1999-03-18 |
NO306283B1 (en) | 1999-10-18 |
EP0625044A1 (en) | 1994-11-23 |
US5629011A (en) | 1997-05-13 |
JPH07503481A (en) | 1995-04-13 |
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