NZ709502B2 - New abuse-resistant pharmaceutical composition for the treatment of opioid dependence - Google Patents
New abuse-resistant pharmaceutical composition for the treatment of opioid dependence Download PDFInfo
- Publication number
- NZ709502B2 NZ709502B2 NZ709502A NZ70950212A NZ709502B2 NZ 709502 B2 NZ709502 B2 NZ 709502B2 NZ 709502 A NZ709502 A NZ 709502A NZ 70950212 A NZ70950212 A NZ 70950212A NZ 709502 B2 NZ709502 B2 NZ 709502B2
- Authority
- NZ
- New Zealand
- Prior art keywords
- buprenorphine
- tablet
- acid
- naloxone
- particles
- Prior art date
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- A61P25/04—Centrally acting analgesics, e.g. opioids
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61P—SPECIFIC THERAPEUTIC ACTIVITY OF CHEMICAL COMPOUNDS OR MEDICINAL PREPARATIONS
- A61P25/00—Drugs for disorders of the nervous system
- A61P25/30—Drugs for disorders of the nervous system for treating abuse or dependence
-
- A—HUMAN NECESSITIES
- A61—MEDICAL OR VETERINARY SCIENCE; HYGIENE
- A61P—SPECIFIC THERAPEUTIC ACTIVITY OF CHEMICAL COMPOUNDS OR MEDICINAL PREPARATIONS
- A61P25/00—Drugs for disorders of the nervous system
- A61P25/30—Drugs for disorders of the nervous system for treating abuse or dependence
- A61P25/36—Opioid-abuse
Abstract
Disclosed herein are tablets for sublingual administration comprising microparticles of buprenorphine or a pharmaceutically-acceptable salt thereof, particles of a weak acid, naloxone or a pharmaceutically-acceptable salt thereof and a disintegrant. The tablets are intended to provide a mode of abuse-resistant treatment for opioid dependence. e-resistant treatment for opioid dependence.
Description
NEW ABUSE-RESISTANT PHARMACEUTICAL COMPOSITION FOR THE
TREATMENT OF OPIOID DEPENDENCE
The present application is a divisional application out of NZ 618120.
This invention relates to new pharmaceutical compositions comprising opioids
that are useful in the treatment of opioid/opiate dependency and/or pain, which
compositions may be abuse-resistant, and may be administered transmucosally
and, in particular, sublingually.
Opioids are widely used in medicine as analgesics.
Indeed, it is presently
accepted that, in the palliation of more severe pain, no more effective therapeutic
agents exist.
Opioid agonist analgesics are used to treat moderate to severe, chronic cancer
pain, often in combination with non-steroidal anti-inflammatory drugs (NSAIDs),
as well as acute pain (e.g. during recovery from surgery and breakthrough pain).
Further, their use is increasing in the management of chronic, non-malignant
pain.
A perennial problem with potent opioid agonists however is one of abuse by drug
addicts. Drug addiction is a worldwide problem of which opioid dependence,
notably of heroin, is a major component. The World Health Organisation (WHO)
eslimates
that there are approximately 4.3 million opioid addicts globally, with
2:5 approximately 07 million in Europe and 0.3 million in the US and Canada.
Opioid dependence is a major health problem and long-term heroin use is
connected to a substantially increased risk of premature death from drug
overdoses, violence and suicide. Furthermore, sharing of needles among addicts
contribute to the spreading of potentially fatal blood infections such as HIV, and
hepatitis C. In addition, opioid dependence often leads to difficulties with social
relations, inability to manage a normal job and increased criminality to finance
addiction, with severe implications for the opioid dependent person and his/her
family.
Opioid addicts not only feed their addition by direct purchase of opioids "on the
street", typically in the form of opioid-based powders (such as heroin), but may
also get hold of pharmaceutical formulations intended for the treatment of e.g.
pain. Such individuals then often apply innovative techniques in their abuse of
such formulations, for example by extracting a large quantity of active ingredient
from that formulation into solution, which is then injected intravenously. With
most commercially-available pharmaceutical formulations, this can be done
relatively easily, which renders them unsafe or ''abusable". Thus, there is a
general need for non-abusable pharmaceutical formulations comprising opioid
agonists.
Opioid addicts are often treated by way of "substitution" therapy, in which mainly
"street" opioids of unknown strength and purity are replaced by pharmaceutical-
grade opioids with a longer duration of action, such as buprenorphine.
Further, a new cohort of opioid-dependent individuals has begun to emerge in the
last decade, particularly in the US, namely so-called "white collar addicts, who
have become dependent upon prescription opioids, typically initiated for the
treatment of pain. Substitution therapy is also required for this growing group of
patients.
Opioid antagonists are used to reverse the pharmacological effects of opioids.
Selective opioid antagonists, such as naloxone, may therefore be used to treat
narcotic drug overdose or to diagnose suspected opioid addiction. Naloxone in
particular has a poor bioavailability when administered transmucosally but is
rendered fully bioavailable when administered by injection.
A simple mixture combination tablet comprising the opioid partial agonist
buprenorphine and naloxone in a 4:1 ratio for sublingual administration is
available under the trademark Suboxone0. (This and other abuse-resistant
opioid-containing formulations are reviewed by Fudula and Johnson in
Drug and
Alcohol Dependence, 83S, S40 (2006). See also US patent applications US
2003/0124061 and US 2003/0191147.)
Because of naloxone's poor transmucosal bioavailability, if Suboxone is taken
sublingually, as directed, the small amount of naloxone that is absorbed should
not interfere with the desired effects of buprenorphine.
On the other hand, if Suboxone is dissolved and injected by an addict with a view
to achieving a "high", the increased availability of naloxone via the parenteral
route should serve to antagonize the effects of buprenorphine, at the same time
as precipitating unpleasant opioid withdrawal symptoms in an individual
physically dependent on opioids.
Nonetheless, when administered parenterally, naloxone's functional blockade of
buprenorphine's action is also only partial and is short-lived in its nature. In view
of this, diversion and illicit use of Suboxone has frequently been reported,
especially in hidden populations such as incarcerated and active drug abusers
(see, for example, Alho
et al, Drug and Alcohol Dependence, 88, 75 (2007),
Monte
eta!, Journal of Addictive Diseases, 28, 226 (2009), Stimmel, ibid., 26, 1
(2007) and Smith
eta!, ibid., 26, 107, 2007). Indeed, a recent study of untreated
intravenous abusers in Finland revealed that 68% reported abuse of Suboxone.
Moreover, 66% of those that had abused the drug once admitted that they had
abused it at least once subsequently, or even regularly thereafter (see Ahlo et al,
supra).
Further, Suboxone has also been reported to have several other significant
limitations. For example, the tablets are large and disintegrate slowly. The
bioavailability of buprenorphine is also significantly lower than for a sublingual
solution (see Compton
et al, Drug and Alcohol Dependence, 82, 25 (2006)).
Moreover, the taste is not well tolerated by all patients and the tablet has an
unpleasant gritty mouthfeel. A film-based product has recently been developed
to counteract these problems, but the film formulation also does not dissolve
particularly quickly. Furthermore, a maximum of only two films (with doses of 2
mg and 8 mg of buprenorphine) may be administered simultaneously. Sequential
administration is thus required for (commonly administered) doses in excess of
mg or 16 mg of buprenorphine, respectively.
There is thus a presently unmet clinical need for an abuse-resistant product for
use in opioid addiction substitution therapy, but which does not possess the
afore-mentioned limitations. In particular, if it were possible to devise a
formulation that was capable of significantly increasing the bioavailability of
buprenorphine, it might be possible to reduce the amount of this active
pharmaceutical ingredient, giving rise to less opioid in the formulation and so
reducing the amount available for injection if diverted by way of intravenous
abuse.
International patent applications WO 00/16751, , WO
2006/103418 and all disclose drug delivery systems for the
treatment of e.g. acute pain by sublingual administration, applying an interactive
mixture principle, in which the active ingredient in microparticulate form is
adhered to the surfaces of larger carrier particles in the presence of a
bioadhesive and/or mucoadhesive promoting agent. in
particular discloses a formulation comprising particles of opioid agonist drug upon
the surfaces of carrier particles comprising an opioid antagonisi such as
naloxone,
Prior art documents, including international patent applications WO 03/005944,
VVO 02/067903, VVO 2007/141328, VVO 2010/132605, VVO 01/30288 and US
patent application US 2009/0263476 Al employ pH modifying agents to promote
dissolution and/or absorption of active ingredients.
We have now found that, by applying a specific formulation principle to a
combination of specific active ingredients, buprenorphine and naloxone, we have
provided a product with unexpected, significantly improved pharmaceutical and
clinical properties,
According to a first aspect of the invention there is provided a tablet suitable for
sublingual administration comprising:
microparticles of buprenorphine, or a pharmaceutically-acceptable salt
thereof;
particles comprising a weak acid;
(c) naloxone, or a pharmaceutically-acceptable salt thereof; and
(d) a disintegrant,
wherein, in an in vitro small-volume funnel dissolution test (as herein defined), the
tablet exhibits:
a maximum pH drop from 6.8 of between 0.5 and 5 pH units within
about 1 minute; followed by
a return to the initial pH (±0.5) within about 3 minutes,
with the pH drop and increase being measured from the start of dripping from the
outlet of the glass funnel.
According to a second aspect of the invention there is provided a use of a tablet
according to the invention for the manufacture of medicament for use in a
method of treatment of a patient, which method comprises administration of said
tablet to said patient.
Is According to a third aspect of the invention there is provided a use of a tablet
comprising:
(i) microparticles of a pharmacologically-effective amount of buprenorphine,
or a pharmaceutically-acceptable salt thereof;
(ii) particles comprising a weak acid;
(Hi) particles of a pharmacologically-effective amount of naloxone, or a
pharmaceutically-acceptable salt thereof; and
(iv) a disintegrant,
wherein the dose ratio of buprenorphineinaloxone is about 4:1 (calculated as free
bases), for the manufacture of a medicament for use in a method of treatment of
a patient, which method comprises sublingual administration of said tablet to said
patient.
Also described is a pharmaceutical composition comprising microparticles of a
pharmacologically-effective amount of buprenorphine, or a pharmaceutically-
acceptable salt thereof, in associative admixture with particles comprising a weak
acid, or particles comprising weakly-acidic buffer forming materials.
Such
compositions are referred to hereinafter as the compositions of the invention".
It is preferred that the pharmaceutical compositions comprising buprenorphine, or
a pharmaceutically-acceptable salt thereof, are presented in admixture (e.g. in
simple mixture) together with a disintegrant.
In this respect, there is further described a pharmaceutical composition
comprising:
a composition of the invention as hereinbefore defined ("Component
(i)"); and
(ii) a disintegrant (hereinafter "Component (ii)").
Compositions comprising Components (i) and (ii) are also referred to together
hereinafter as compositions of the invention.
It is further preferred that the pharmaceutical compositions comprising
buprenorphine, or a pharmaceutically-acceptable salt thereof, are presented in
admixture (e.g. in simple mixture) together with a disintegrant and naloxone.
In this respect, there is further described a pharmaceutical composition
comprising:
(a) a composition of the invention comprising Components (i) and/or (H)
as hereinbefore defined; and
(b) particles of a pharmacologically-effective amount of naloxone, or a
pharmaceutically-acceptable salt thereof (hereinafter "Component
(iii)").
Compositions comprising Component (Hi) formulated together with Components,
(i) and/or (H) are also referred to together hereinafter as compositions of the
invention.
Buprenorphine and pharmaceutically-acceptable salts thereof are presented in
the compositions described herein in the form of microparticles. Naloxone and
pharmaceutically-acceptable salts thereof may also (e.g. preferably) be presented
in compositions of the invention in the form of microparticles. Microparticles
preferably possess a weight based mean diameter, number based mean
diameter and/or a volume based mean diameter of between about 0.5 pm and
about 15 pm, such as about 1 pm and about 10 pm. As used herein, the term
"weight based mean diameter" will be understood by the skilled person to include
that the average particle size is characterised and defined from a particle size
distribution by weight, i.e. a distribution where the existing fraction (relative
amount) in each size class is defined as the weight fraction, as obtained by e.g.
sieving (e.g. wet sieving). As used herein, the term "number based mean
diameter" will be understood by the skilled person to include that the average
particle size is characterised and defined from a particle size distribution by
number, i.e. a distribution where the existing fraction (relative amount) in each
size class is defined as the number fraction, as measured by e.g. microscopy. As
used herein, the term "volume based mean diameter" will be understood by the
skilled person to include that the average particle size is characterised and
defined from a particle size distribution by volume, i.e. a distribution where the
existing fraction (relative amount) in each size class is defined as the volume
fraction, as measured by e.g. laser diffraction.
Microparticles of active ingredients may be prepared by standard micronisation
techniques, such as grinding, jet milling, dry milling, wet milling, precipitation, etc.
An air elutriation process may be utilised subsequently to prepare specific size
fractions, if required.
Preferred salts of buprenorphine and naloxone include hydrochloride salts.
Buprenorphine and pharmaceutically-acceptable salts thereof are formulated
together in associative admixture with particles of a weak acid, or with particles of
weakly-acidic buffer forming materials. to provide compositions of the invention
(or Component (i) of compositions of the invention).
Weakly acidic materials that may be mentioned include those that, when
provided in a composition described herein, enable the provision when the
composition is dissolved in water and/or saliva (e.g. at the site of administration
of compositions of the invention) of a pH of between about 4.0 and about 6.5
(e.g. about 6.25), and are present in a sufficient amount to enable the
maintenance of pH within this range for an appropriate length of time (e.g. about
seconds, such as about 1 minute) to about 3 minutes (e.g. about 2 minutes,
such as about 1.5 minutes) to facilitate dissolution of, particularly, the
buprenorphine microparticles, and/or absorption of buprenorphine across the
sublingual mucosa thereafter. For the purpose of this disclosure, the term
includes substances that are safe for use in mammals, and includes weak acids,
weak acid derivatives and other chemicals that convert to weak acids
in vivo
(e.g. precursors that convert to acids in vivo,
by for example being sequentially
activated in accordance with properties of the local environment). Typical pKas
of weak acids are in the range of between about -1.5 (e.g. about -1.74) and
about 16 (e.g. about 15.74) (e.g. see Vollhardt,
Organic Chemistry (1987). A
preferred range is between about 1 and about 10. More preferably, the weakly
acidic material comprises a weak acid that is safe for human consumption, for
example a food acid, such as malic acid, fumaric acid, adipic acid, succinic acid,
lactic acid, acetic acid, oxalic acid, maleic acid, ammonium chloride, preferably
tartaric acid, and more preferably citric acid, or a combination of such acids. The
skilled person will appreciate that, when weak acids are employed which are not
solids (and therefore not particulate) at or around room temperature and
atmospheric pressure, they may be adsorbed into a particulate carrier material
(such as colloidal silica) in order to provide particles comprising the weakly acidic
material.
Weakly-acidic buffer forming materials include materials [hat, when provided in a
composition described herein, provide a weakly acidic buffer system when the
composition is dissolved in water and/or saliva (e.g, at the site of administration
of compositions of the invention), enabling the provision of a pH of between
about 4.0 and about 6.5 (e.g. about 6.25), and are present in a sufficient amount
to enable the maintenance of pH within this range for an appropriate length of
time (e.g. about 30 seconds, such as about 1 minute) to about 3 minutes (e.g.
about 2 minutes, such as about 1,5 minutes) to facilitate dissolution of,
particularly, the buprenorphine microparticles, and/or absorption of
buprenorphine across the sublingual mucosa thereafter. Buffer forming materials
thus include combinations of weak acid and salt of weak acid, such as
combinations of the aforementioned acids with alkaline salts of those acids,
including sodium citrate, potassium citrate, sodium tartrate, potassium tartrate
and the like. Preferred buffer forming materials are citric acid and sodium citrate.
The skilled person will appreciate that, when materials are employed which are
not solids (and therefore not particulate) at or around room temperature and
atmospheric pressure, they may be adsorbed into a particulate carrier material
(such as colloidal silica) in order to provide particles comprising the weakly-acidic
buffer forming materials.
Suitable particles sizes of weakly acidic, or weakly-acidic buffer forming, materials
are in the range about 1 pm and about 1000 pm (e.g. about 800 pm, such as
about 750 pm), and preferably between about 40 (such as about 50 pm) and
about 600 pm. Suitable amounts of weakly acidic materials that enable the
maintenance of pH within the aforementioned ranges after oral administration as
hereinbefore described are in the range of at least about 1% to about 10% by
weight of the total formulation. Suitable total amounts of weakly-acidic buffer
forming materials that enable the maintenance of pH within the aforementioned
ranges after oral administration as hereinbefore described are in the range of at
least about 1% to about 15% by weight of the total formulation.
The disintegrant or "disintegrating agent" that may be employed as, or as part of,
Component (ii) in compositions of the invention may be defined as any material
that is capable of accelerating to a measurable degree the
disintegration/dispersion of a composition of the invention. The disintegrant may
thus provide for an in vitro
disintegration time of about 30 seconds or less, as
measured according to e.g. the standard United States Pharmacopeia (USP)
disintegration test method (see
FDA Guidance for Industry: Orally Disintegrating
Tablets;
December 2008). This may be achieved, for example, by the material
being capable of swelling, wicking and/or deformation when placed in contact
with water and/or mucous (e.g. saliva), thus causing tablet formulations to
disintegrate when so wetted.
Suitable disintegrants (as defined in, for example, Rowe et al, Handbook of
Pharmaceutical Excipients, 6 th
ed. (2009)) include cellulose derivatives such as
hydroxypropyl cellulose (HPC), low substituted HPC, methyl cellulose, ethyl
hydroxyethyl cellulose, carboxymethyl cellulose calcium, carboxymethyl cellulose
sodium, microcrystalline cellulose, modified cellulose gum; starch derivatives
such as moderately cross-linked starch, modified starch, hydroxylpropyl starch
and pregelatinized starch; and other disintegrants such as calcium alginate,
sodium alginate, alginic acid, chitosan, colloidal silicon dioxide, docusate sodium,
guar gum, magnesium aluminium silicate, polacrilin potassium and
polyvinylpyrrolidone. Combinations of two or more disintegrants may be used.
Preferred disintegrants include so-called "superdisintergrants" (as defined in, for
example, Mohanachandran et al, International Journal of Pharmaceutical
Sciences Review and Research, 6, 105 (2011)), such as cross-linked
polyvinylpyrrolidone, sodium starch glycolate and croscarmellose sodium.
Combinations of two or more superdisintegrants may be used.
Disintegrants may also be combined with superdisintegrants in compositions of
the invention.
Disintegrants and/or superdisintegrants are preferably employed in an (e.g. total)
amount of between 0.5 and 15% by weight based upon the total weight of a
composition. A preferred range is from 1 to 8%, such as from about 2 to about
7% (e.g. about 5%, such as about 4%) by weight.
Compositions described herein may be formulated together (along with any other
materials that may be present) by standard simple mixing techniques or by way of
2.0 granulation.
Granules may be prepared by a process of dry granulation, wet granulation, melt
granulation, thermoplastic pelletising, spray granulation or
extrusion/spheronisation.
Wet granulation techniques are well known to those skilled in the art and include
any technique involving the massing of a mix of dry primary powder particles
using a granulating fluid, which fluid comprises a vclaile, inert solvent, such as
water, ethanol or isopropanol, either alone or in combination, and optionally in the
presence of a binder or binding agent. The technique may involve forcing a wet
mass through a sieve to produce wet granules which are then dried, preferably to
a loss on drying of less than about 3% by weight.
Dry granulation techniques are also well known to those skilled in the art and
include any technique in which primary powder particles are aggregated under
high pressure, including slugging and roller compaction, for example as described
hereinafter.
Melt granulation will be known by those skilled in the art to include any technique
in which granules are obtained through the addition of a molten binder, or a solid
binder which melts during the process. After granulation, the binder solidifies at
room temperature. Thermoplastic pelletising will be known to be similar to melt
granulation, but in which plastic properties of the binder are employed. In both
processes, the agglomerates (granules) obtained comprise a matrix structure.
Spray granulation will be known by those skilled in the art to include any
technique involving the drying of liquids (solutions, suspensions, melts) while
simultaneously building up granulates in a fluid bed. The term thus includes
processes in which foreign seeds (germs) are provided upon which granules are
built up, as well as those in which inherent seeds (germs) form in the fluid bed
due to abrasion and/or fracture, in addition to any spray coating granulation
technique generally. The sprayed liquid coats the germs and assists further
agglomeration of particles. It is then dried to form granules in the form of a
matrix.
Extrusion/spheronisation will be well known to those skilled in the art to include
any process involving the dry mixing of ingredients, wet massing along with a
binder, extruding, spheronising the extrudate into spheroids of uniform size, and
drying.
In particular, microparticles of buprenorphine or salt thereof and particles of
weakly acidic, weakly-acidic buffer forming, materials are presented in
associative admixture with each other in compositions described herein. By
"associative admixture" we mean that whether or not Component (i) is
subsequently formulated along with Components (ii) and (iii) as hereinbefore
defined, some form of mixing step (simple mixing, granulation as described
hereinbefore, or otherwise) takes place as between the buprenorphine/salt
microparticles and particles of weakly acidic, weakly-acidic buffer forming,
materials, rendering them in intimate contact with each other.
For the avoidance of doubt, by "intimate contact", we include that microparticles
of buprenorphine or salt thereof, and particles of weakly acidic, weakly-acidic
buffer forming, materials, are presented in compositions described herein in any
form in which they are, at least in part, in intimate contact with each other. This
includes the possibility of the inclusion of quickly dissolving coatings on one or
other, or both, sets of particles.
In this respect, Component (i) is preferably presented as, or as part of, a
composition described herein in the form of a interactive mixture comprising at
least one population of carrier particles upon the surfaces of which are presented
(e.g. adhered) microparticles of buprenorphine or a pharmaceutically acceptable
salt thereof.
The term "Interactive" mixture will be understood by those skilled in the art to
include the term "ordered" mixture, and to denote a mixture in which particles do
not appear as single units, as in random mixtures, but rather where smaller
particles (e.g. microparticles of, for example, buprenorphine) are attached to (i.e.
adhered to or associated with) the surfaces of larger carrier particles. Such
mixtures are characterised by interactive forces (for example van der VVaals
forces, electrostatic or Coulomb forces, and/or hydrogen bonding) between
carrier and surface-associated particles (see, for example, Staniforth,
Powder
Technol., 45, 75 (1985)). In final mixtures, and compositions comprising such
mixtures, the interactive forces need to be strong enough to keep the adherent
particles at the carrier surface.
When interactive mixtures are employed as the formulation principle by which the
particulate Component (i) is presented in a composition described herein, these
are made, preferably, with carrier particles that are of a size (weight and/or
volume based average or mean diameter, vide supra) that is between about 30
pm and about 1000 pm (e.g. about 800 pM, such as about 750 pm), and
preferably between about 40 (such as about 50 pm) and about 600 pm.
Carrier particles may comprise pharmaceutically-acceptable substances that are
soluble in water, such as carbohydrates, e.g. sugars, such as lactose, and sugar
alcohols, such as mannitol, sorbitol and xylitol; pharmaceutically-acceptable
inorganic salts, such as sodium chloride. Water soluble carrier particles may also
comprise the weakly acidic, and/or weakly acidic buffer forming materials,
mentioned hereinbefore (such as citric acid and/or sodium citrate). Alternatively,
carrier particles may comprise pharmaceutically-acceptable substances that are
insoluble or sparingly soluble in water, such as dicalcium phosphate anhydrate,
dicalcium phosphate dihydrate, tricalcium phosphate, calcium carbonate, and
barium sulphate; starch and pre-gelatinised starch; bioadhesive and
mucoadhesive materials, such as crosslinked polyvinylpyrrolidone and
croscarmellose sodium; and other polymers, such as microcrystalline cellulose,
cellulose and; or mixtures thereof.
By "soluble in water" we include that the material has a solubility in water that is
greater than 33.3 mg/mL at atmospheric pressure (e.g. 1 bar) and room
temperature (e.g. 21°C). On the other hand, the term "sparingly soluble or
insoluble in water - includes materials that have a solubility in water that is less
than 33.3 mg/mL under the same conditions. Preferred soluble carrier particle
materials include sugar alcohols, such as sorbitol, xylitol and particularly
mannitol. Preferred sparingly water-soluble or water-insoluble carrier particle
materials include cellulose and starches, such as microcrystalline cellulose.
It is preferred that buprenorphine or pharmaceutically acceptable salt thereof is
presented on the surfaces of water-soluble carrier particles.
In this respect, as stated above, weakly acidic materials, and/or weakly-acidic
buffer forming materials, may also function as water-soluble carrier particle
materials. Therefore, the associated admixture of such materials with
buprenorphine/salt thereof may mean the former comprise carrier particles upon
which microparticles of the latter are presented. In such cases, such materials
may be presented at least as further water-soluble carrier particles, in addition to
the presence of other water-soluble carrier particles, upon the surfaces of both of
which are presented burprenorphine microparticles.
When carrier particles comprise such weakly acidic/buffer forming materials,
composites of such materials with other water-soluble carrier particle materials
(such as those described hereinbefore) may be provided. Such materials may be
prepared by direct compression or granulation, for example. Alternatively, carrier
particles may consist essentially of a weakly acidic material and/or one or more
materials that, when dissolved in saliva, give rise to a weakly acidic buffer
system. By "consisting essentially" of such materials, we mean that, excluding
the possible presence of water (vide infra), the carrier particles comprise at least
about 95%, such as at least about 98%, more preferably greater than about 99%,
and particularly at least about 99.5% by weight (based on the total weight of the
carrier particle) of such materials. These percentages exclude the presence of
trace amounts of water (e.g. crystal water or water bound to external surfaces of
materials), and/or any impurities that may be present in such materials, which
impurities may arise following the production of such materials, either by a
commercial or non-commercial third party supplier, or by a skilled person making
a composition described herein.
Alternatively (and/or in addition), in Component (i), particles of weakly acidic
material, and/or of weakly-acidic buffer forming materials, may be presented, at
least in part, upon the surfaces of, and/or between, carrier particles. In such
cases, suitable particle sizes of such materials are as presented herein for active
ingredients and/or disintegrants.
When employed in compositions described herein, Components (ii) and (iii) are
preferably formulated together, for example to form particles comprising naloxone
or salt thereof and the disintegrant, prior to mixing with Component (i),
Alternatively, particles of weakly acidic material, and/or of weakly-acidic buffer
forming materials, may be formulated along with Components (ii) and/or (iii) prior
to mixing with buprenorphine microparticles, which latter microparticles may be
presented in the form of interactive mixtures with carrier particles as hereinbefore
described. Weakly acidic, and/or weakly-acidic buffer forming, materials may
thus be formulated in associative admixture with buprenorphine microparticles (as
hereinbefore defined) in this way.
Furthermore, in Component (iii), particles of naloxone, or pharmaceutically-
acceptable salts thereof, may also be presented upon the surfaces of, and/or
between, carrier particles in compositions described herein, but this is not
essential. Such carrier particles may be water-soluble (as hereinbefore defined),
or may (preferably) be water-insoluble/sparingly soluble carrier particles*
Disintegrant and/or superdisintegrant materials, may also be presented, at least
in part, as particles upon the surfaces of, and/or between, carrier particles, which
may or may not also carry naloxone or salt thereof.
If employed in particulate
form, particles of disintegrants and/or superdisintegrants may be presented with a
particle size (weight and/or volume based average or mean diameter, vide supra)
of between about 0.1 and about 100 ,um (e.g. about 1 and about 50 pm).
Alternatively, disintegrants and/or superdisintegrants may also be present as a
constituent in composite excipients. Composite excipients may be defined as co-
processed excipient mixtures. Examples of composite excipients comprising
superdisintegrants are Parteck0 ODT, Ludipress® and Prosolv0 EASYtab.
Bio/mucoadhesive materials may also be presented in compositions described
70 herein. Such materials may be presented upon (e.g. adhered to) the surfaces of
carrier particles when components of compositions described herein are
presented in the form of interactive mixtures.
Compositions described herein may be employed in the treatment of opioid
dependency and/or addiction as described hereinbefore, for example in
substitution therapy programs. Opioid dependency and/or addiction may be
defined in numerous ways (see, for example,
www.who.int/substance abuse/terminolo :definition1), but may be characterized
for example by physiological, behavioural, and cognitive phenomena wherein the
use of a substance or a class of substances takes on a much higher priority for a
given individual than other behaviours that once had greater value, and/or
characterised by a desire (often strong, and sometimes overpowering) to take
opioids and/or opiates (which may or may not have been medically prescribed).
It is particularly preferred that compositions described herein comprising
naloxone are used in the treatment of opioid dependency and/or addiction.
Buprenorphine is a partial agonist at the p-opioid receptor and an antagonist at
the k-opioid receptor. It has high binding affinity at both receptors and competes
with other agonists, such as methadone, heroin (diamorphine) and morphine, at
the p-opioid receptor. Opioid agonist effects of buprenorphine are less than the
maximal effects of other, "full" opioid agonists, such as morphine, and are limited
by a "ceiling" effect. The drug thus produces a lower degree of physical
dependence than other opioid agonists, such as heroin, morphine or methadone
and is therefore particularly useful in substitution therapy.
The term "pharmacologically effective amount" refers to an amount of an active
ingredient, which is capable of conferring a desired therapeutic effect on a treated
patient, whether administered alone or in combination with another active
ingredient. Such an effect may be objective (i.e. measurable by some test or
marker) or subjective (i.e. the subject gives an indication of, or feels, en effect).
Thus, appropriate pharmacologically effective amounts of buprenorphine (or salt
thereof) include those that are capable of producing, and/or contributing to the
production of, the desired therapeutic effect, namely decreased opioid and/or
opiate craving and/or decreased illicit drug use, when administered
transmucosally, whereas appropriate pharmacologically effective amounts of
naloxone (or salt thereof) when employed must be sufficient so as not to compete
with the above-mentioned pharmacological effect of the buprenorphine present in
the composition described herein upon transmucosal administration, but to
antagonize the effect of the buprenorphine and precipitate withdrawal symptoms
if an attempt is made by an opioid-addicted individual to inject a composition
described herein.
The amounts of active ingredients that may be employed in compositions
described herein may thus be determined by the skilled person, in relation to
what will be most suitable for an individual patient. This is likely to vary with the
route of administration, the type and severity of the condition that is to be treated,
as well as the age, weight, sex, renal function, hepatic function and response of
the particular patient to be treated.
The total amount of buprenorphine/salt thereof that may be employed in a
composition described herein may be in the range of about 0.1%, such as about
1%, to about 20%, such as about 10%, by weight based upon the total weight of
the composition. The amount of this active ingredient may also be expressed as
the amount in a unit dosage form (e.g. a tablet). In such a case, the amount of
buprenorphine/salt that may be present may be sufficient to provide a dose of
buprenorphine (calculated as the free base) per unit dosage form that is in the
range of between about 0.1 mg, such as about 1 mg and about 50, for example
about 30, such as about 20 mg (e.g. about 15 mg, e.g. about 12 mg, such as
about 10 mg). Preferred ranges for the treatment of pain are about 0.1 mg to
about 4 mg. Preferred ranges for substitution therapy are about 0.5 mg to about
50 mg, such as about 0.75 mg, (e.g. about 1 mg) to about 12 mg, such as about
mg (e.g. about 7 mg). Individual buprenorphine doses per tablet that may be
mentioned include about 11.4 mg, about 8.6 mg, about 5.7 mg, about 2.9 mg and
about 1.4 mg.
When employed, the total amount of naloxone/salt thereof that may be employed
in a composition described herein may be in the range about 0.125%, such as
about 0.25% to about 5%, such as about 2.5%, by weight based upon the total
weight of the composition. The amount of this active ingredient may also be
expressed as the amount in a unit dosage form (e.g. a tablet). In such a case,
the amount of naloxone/salt that may be present may be sufficient to provide a
dose of naloxone (calculated as the free base) per unit dosage form that is in the
range of between about 0.125 mg and about 12.5 mg, such as about 0.19 mg
(e.g. about 0.25 mg) to about 3 mg, such as about 2.5 mg (e.g. about 1.75 mg).
Individual naloxone doses per tablet that may be mentioned include about 2.9
mg, about 2.2 mg, about 1.4 mg, about 0.7 mg and about 0.4 mg.
Although, for compositions described herein containing naloxone, it is preferred
that the dose ratio of buprenorphine:naloxone is maintained at about 4:1, the
above-mentioned dosages are exemplary of the average case; there can, of
course, be individual instances where higher or lower dosage ranges are merited,
and such are within the scope of this disclosure.
Compositions described herein, once prepared, are preferably directly
compressed/compacted into unit dosage forms (e.g. tablets) for administration to
mammalian (e.g. human) patients, for example as described hereinafter.
Compositions described herein may be in the form of powders or, more
preferably, tablets for e.g. sublingual administration. Tablets may also comprise
a binder. A binder may be defined as a material that is capable of acting as a
bond formation enhancer, facilitating the compression of the powder mass into
coherent compacts. Suitable binders include cellulose gum and microcrystalline
cellulose. If present, binder is preferably employed in an amount of between 0.5
and 20% by weight based upon the total weight of the tablet formulation. A
preferred range is from 1 to 15%, such as from about 2.0 to about 12% (e.g.
about 10%) by weight.
Suitable further additives and/or excipients that may be employed in compositions
described herein, in particular those in the form of tablets for e.g. sublingual
administration may comprise:
(a) lubricants (such as magnesium stearate or, preferably, sodium st- aryl
fumarate);
(D) flavourings (e.g. lemon, peppermint powder or, preferably, menthol),
sweeteners (e.g. neohesperidin, acesulfame K or, preferably, sucralose)
and dyestuffs;
(c) antioxidants, which may be naturally occurring or otherwise (e.g. butylated
hydroxytoluene (BHT), vitamin C, vitamin E, a-carotene, uric acid,
uniquion, superoxide dismutase (SOD), glutathione peroxidase or
peroxidase catalase); and/or
(d) other ingredients, such as carrier agents, preservatives and gliding agents
(e.g. colloidal silica).
Compositions described herein may be prepared by standard techniques, and
using standard equipment, known to the skilled person.
When presented in the form of interactive mixtures, particles of e.g,
buprenorphine/salt may be dry mixed with relevant carrier particles over a period
of time that is sufficiently long to enable appropriate amounts of respective active
ingredients to adhere to the surface of the carrier particles. This may also apply
to other active ingredients and/or excipients defined hereinbefore.
The skilled person will appreciate that, in order to obtain a dry powder formulation
in the form of an interactive mixture, larger carrier particles must be able to exert
enough force to break up agglomerates of smaller particles. This ability will
Jo primarily be determined by particle density, surface roughness, shape, flowability
and, particularly, relative particle sizes.
Standard mixing equipment may be used in this regard. The mixing time period
is likely to vary according to the equipment used, and the skilled person will have
no difficulty in determining by routine experimentation a suitable mixing time for a
given combination of active ingredient and carrier particle material(s).
Interactive mixtures may also be provided using techniques other than dry mixing,
which techniques will be well known to those skilled in the art.
Other ingredients may alternatively be incorporated by standard mixing or other
formulation principles.
The compositions described herejn may be administered transmucosally, such as
buccally, rectally, nasally or pr ,._:rornbly sublingually by way of appropriate dosing
means known to the skilled person. A sublingual tablet may be placed under the
tongue, and the active ingredients absorbed through the surrounding mucous
membranes.
In this respect, the compositions described herein may be incorporated into
various kinds of pharmaceutical preparations intended for transmucosal (e.g.
sublingual) administration using standard techniques (see, for example, Lachman
et al, "The Theory and Practice of Industrial Pharmacy',
Lea & Febiger, 3 edition
(1986) and "Remington: The Science and Practice of Pharmacy",
Gennaro (ed.),
Philadelphia College of Pharmacy & Sciences, 19th edition (1995)).
Pharmaceutical preparations for sublingual administration may be obtained by
combining compositions described herein with conventional pharmaceutical
additives and/or excipients used in the art for such preparations, and thereafter
preferably directly compressed/compacted into unit dosage forms (e.g. tablets).
(See, for example, Pharmaceutical Dosage Forms: Tablets. Volume 1, 2nd
Edition, Lieberman et at (eds.), Marcel Dekker, New York and Basel (1989) p.
354-356 and the documents cited therein.) Suitable compacting equipment
includes standard tabletting machines, such as the Kilian SP300, the Korsch
EKO, the Korsch XP1, the Korsch XL100 or the Korsch PharmaPress 800.
Suitable final sublingual tablet weights are in the range of about 30 to about 400
mg, such as about 40 (e.g. about 50) to about 300 mg (e.g. about 250 mg, such
as about 200 mg), for example about 50 (e.g. about 60) to 180 mg, more
preferably between about 60 (e.g. about 70) and about 160 mg. Suitable final
tablet diameters are in the range of about 3 to about 12 mm, for example about 4
to about 10 min, and more preferably about 5 to about 9 mm. Suitable final tablet
thicknesses are in the range of about 0.5 mm to about 4 mm, such as about 1.5
mm to about 3 mm. Various tablet shapes are possible (e.g. circular, triangular,
square, diamond, polygon or oval). Suitable tablet hardnesses include crushing
strengths in the range of about 10N to about 100N, for example about 15N to
about 50N (depending on the size and/or weight of the tablet), according to US
Pharmacopoeia method <1217>.
Irrespective of the foregoing, compositions described herein comprising
disintegrants (or other excipients that function by swelling) should be essentially
free (e.g. less than about 20% by weight based
on the total weight of the
formulation) of water. It will be evident to the skilled person that "premature"
hydration will dramatically decrease the performance of a tablet formulation in
use and may result in premature dissolution of active ingredients.
Wherever the word "about" is employed herein in the context of dimensions (e.g.
tablet sizes and weights, particle sizes etc.), surface coverage (e.g. of carrier
particles by particles of active ingredients), amounts (e.g. relative amounts of
individual constituents in a composition or a component of a composition and
absolute doses (including ratios) of active ingredients), temperatures, pressures,
times, pH values, concentrations, it will be appreciated that such variables are
approximate and as such may vary by ± 10%, for example ± 5% and preferably ±
2% (e.g. ± 1`)/0) from the numbers specified herein. Wherever the word "about" is
employed herein in the context of pharmacokinetic properties (Cmax,
tmax,
AUCs),etc., it will be appreciated that such variables are approximate and as
such may vary by ± 15%, such as ± 10%.
Compositions described herein may be administered by way of appropriate
o dosing means known to the skilled person. For example, a sublingual tablet may
be placed under the tongue, and the active ingredients absorbed through the
surrounding mucous membrane.
We have found that compositions described herein surprisingly give rise to
significantly improved bioavailability for buprenorphine when compared to prior
art, commercially-available formulations. This means that formulations with lower
single doses of buprenorphine may be administered by way of compositions
described herein, so reducing the "street value" of a single tablet when it
comprises a composition described herein, with more than one such tablet being
required to give the same effect when illicitly administered parenterally (i.e. in
"street" terms, the same -
fix"). This means that compositions described herein
arc less likely to be abused than prior art, commercially-available formulations
(see Corner eta!, Addiction, 105, 709-718 (2010)).
Additionally, we have found that compositions described herein comprising
naloxone also surprisingly give rise to significantly (and simultaneously with
buprenorphone) improved bioavailability for naloxone when compared to prior art,
commercially-available formulations.
Compositions described herein comprising naloxone thus surprisingly give rise to
similar, almost parallel, degrees of improved bioavailability for both
buprenorphine and naloxone, which means that the "optimal" ratio of
buprenorphine to naloxone, which has been arrived at to reduce abuse potential
(see, for example, Mendelson and Jones, Drug and Alcohol Dependence,
70, 829
(2003)), may be maintained, and doses of both active ingredients therefore
lowered by an equivalent degree to preserve the same ratio.
Also described herein is a method of treating opioid dependency and/or addiction
in a human,
which method comprises sublingual administration to a human patient
suffering from opioid dependency and/or addiction of
at least one unit dose of a pharmaceutical composition (e.g. a tablet)
comprising buprenorphine or a pharmaceutically acceptable salt thereof,
in combination with naloxone or a pharmaceutically acceptable salt
thereof, in about a 4:1 buprenorphine:naloxone dose ratio (calculated as
free bases),
wherein said unit dose composition comprises a dose of buprenorphine,
which is about 75% of that of a random mixture compressed (RMC) tablet
comprising buprenorphine, and
which method achieves, after an initial dose in any given treatment
program, a plasma-concentration time profile for buprenorphine (and/or
naloxone) that is essentially equivalent to that/those exhibited by such
RMC tablets.
"RMC tablets" include, but are not limited to, the commercially-available tablet
product Suboxone® (NDA No. 20-733, approval date October 8, 2002;
buprenorphine strength 2 mg (Product No. 001; actual weight about 100 mg) and
8 mg (Product No. 002; actual weight about 400 mg)). The 8 mg tablets (at least)
have a mean crushing strength (US Pharmacopeia method <1217>) of about 127
N. RMC tablet strengths are thus in the range of about 80 to about 180 N. RMC
tablets are formed by compression of a random mixture, prepared by wet
granulation of a standard mixture comprising buprenorphine hydrochloride,
naloxone hydrochloride dihydrate, lactose monohydrate, mannitol, maize starch,
povidone K30, citric acid (anhydrous granular), sodium citrate, natural lemon and
lime flavour, acesulfame potassium and magnesium stearate.
By "a plasma-concentration time profile for buprenorphine and/or naloxone that is
essentially equivalent to that/those exhibited by such RMC tablets", we include
that, after an initial dose in any given treatment program, one or more of:
the maximum plasma concentration (Cmax); and/or
(ii)
the time to maximum plasma concentration (t m, x); and/or
(iii) the total area under the plasma concentration-time curve from time zero to
the time of the last measured plasma concentration (AUCt); and/or
(iv) the area under the plasma concentration-time curve from time zero to the
last concentration extrapolated to infinity based on the elimination rate constant
(AUCInf),
as measured by standard pharmacokinetic monitoring means, e.g. as described
in Example 2 hereinafter, for naloxone and/or, more preferably, for
buprenorphine, is between about 80% and about 125% of the corresponding
values obtained for the aforementioned RMC tablets.
Thus, after an initial dose in any given treatment program, for tablets comprising
a dose of buprenorphine that is about 75% of a RMC tablet comprising 8 mg of
buprenorphine may present:
(i) a Cr„, of between about 3,0 ng/mL and about 5.6 (such as about 4.5) ng/mL;
and/or
(ii) a t ma
, that is less than about 3 hours, preferably less than about 2 hours;
and/or
(iii) an AUCinf that is about 25 ng.h/mL to about 40 ng.h/mL, such as about 28
ng.h/mL to about 36 ng,h/mL,
for buprenorphine; and/or
(a) a Cmax of between about 150 pg/mL and about 300 (such as about 250)
pg/mL; and/or
(b) a tr,,, that is less than about 1 hour,
for naloxone.
Also described is a method of treating opioid dependency and/or addiction in a
human,
which method comprises sublingual administration to a human patient
suffering from opioid dependency and/or addiction of
at least one unit dose of a pharmaceutical composition (e.g. a tablet)
comprising buprenorphine or a pharmaceutically acceptable salt thereof,
in combination with naloxone or a pharmaceutically acceptable salt
thereof, in about a 4:1 buprenorphine:naloxone dose ratio calculated as
free bases),
wherein said unit dose composition comprises a dose of buprenorphine,
which is about 75% of that of a RMC tablet as hereinbefore defined, and
which method achieves after an initial dose in any given treatment
program a mean relative bioavailability compared to such RMC tablets
that is:
(A) about 1.2 to about 1,6 for buprenorphine; and/or
(B) about 1.2 to about 2.0 for naloxone.
Also described is a method of treating opioid dependency and/or addiction in a
human, which method comprises sublingual administration to a human patient
suffering from opioid dependency and/or addiction of at least one unit dose of a
pharmaceutical composition (e.g. a tablet) comprising buprenorphine or a
pharmaceutically acceptable salt thereof, in combination with naloxone or a
pharmaceutically acceptable salt thereof, wherein said tablet comprises a dose of
buprenorphine or salt thereof, which is about 6 mg or about 1.5 mg, and the
buprenorphine:naloxone dose ratio is about 4:1 (calculated as the free base).
Compositions described herein
may also give rise to a lower
norbuprenorphine:buprenorphine ratio in plasma when compared to prior art,
commercially-available formulations. A lower norbuprenorphine to buprenorphine
ratio is also seen after sublingual administration of an ethanol solution compared
to a tablet formuUion (see Harris
et al, Clin. Pharmacokinet,, 43, 329 (2004)) as
dose is increased, suggesting that less buprenorphine is being swallowed. In
addition, less norbuprenorphine is found in the plasma after parenteral
administration compared to sublingual administration (Sigmon et al, Addiction,
101, 420 (2005)), further supporting the notion that norbuprenorphine is formed
from swallowed buprenorphine by first pass metabolism through the liver. Thus,
the lower norbuprenorphine:buprenorphine ratio reported herein may be reflective
of the fact that more buprenorphine is absorbed over the sublingual mucosa (and
so less is swallowed) than with prior art, commercially available (e.g. RMC tablet)
formulations. There may also be benefits from the reduction of the
norbuprenorphine:buprenorphine ratio per se, such as reduced respiratory
depression (see Megarbane
et al, Toxicology and Applied Phamacology, 212,
256 (2006)).
Also described herein is a method of treating opioid dependency and/or addiction
in a human, which method comprises sublingual administration of a
pharmaceutical composition comprising buprenorphine or a pharmaceutically
acceptable salt thereof, in combination with naloxone or a pharmaceutically
acceptable salt thereof, in about a 4:1 buprenorphine:naloxone dose ratio
(calculated as the free base), wherein said composition comprises a dose of
buprenorphine which is about 75% of that of a RMC tablet as hereinbefore
defined, to a human patient suffering from opioid dependency and/or addiction,
wherein said formulation achieves after an initial dose in any given treatment
program a ratio of norbuprenorphine/buprenorphine concentrations in plasma of
less than about 0.8 based upon AUC24.
Such methods may comprise administration of a composition as defined herein.
By any given treatment program", we mean any course of treatment of a patient
with a composition described herein.
Without being limited by theory, it is understood that the compositions described
herein give rise to such surprisingly increased bioavailability when compared to
prior art, commercially-available formulations, e.g. RMC tablets, such as
Suboxone, because of a pH-timing effect, in which pH is lowered as hereinbefore
described for a short period of time (e.g. between about 1 and about 3 minutes)
after sublingual administration, resulting in improved and/or more rapid
dissolution of microparticles of burprenorphine. Although such dissolution might
be expected to be improved by decreasing pH, what is completely unexpected is
that the degree of absorption across the sublingual mucosa does not appear to
decrease. One would expect that lowering local pH would give rise to the
presence of more burprenorphine in the ionized state at the site of absorption,
which would in turn be expected to decrease the degree of absorption across the
sublingual mucosa. The fact that the bioavailability is better per unit dose of
buprenorphine for compositions described herein than it is for prior art
compositions is indeed remarkable.
Also described is a pharmaceutical composition comprising microparticles of
buprenorphine or a pharmaceutically acceptable salt thereof, and particles of a
weak acid or particles of weakly acidic buffer forming materials, characterized in
that the composition exhibits, in an
in vitro small-volume funnel dissolution
method, for example as described in Example 5 hereinafter:
a) a pH drop of about 0.5 to about 5 pH units;
a maximum pH drop within about 1 minute of the start of the method; and
a return to the initial pH (±0.5) within about 3 minutes.
Also described is a pharmaceutical composition comprising microparticles of
buprenorphine or a pharmaceutically acceptable salt thereof, and particles of a
weak acid or particles of weakly acidic buffer forming materials, characterized in
that the composition enables the provision (at the site of administration) of a pH
of between about 4.0 and about 6.5 (e.g. less than about 6.25), and the
maintenance of pH within this range for an appropriate length of time (e.g. about
seconds, such as about 1 minute) to about 3 minutes (e.g. about 2 minutes,
such as about 1.5 minutes) to facilitate dissolution of, particularly, the
buprenorphine microparticles, and/or absorption of buprenorphine across the
sublingual mucosa thereafter.
Compositions described herein comprising naloxone surprisingly give rise to
similar, almost parallel, degrees of improved bioavailability for both
buprenorphine and naloxone, which means that the "optimal" ratio of
buprenorphine to naloxono, which has been arrived at to reduce abuse potential
(see, for example, Mendelson and Jones,
Drug and Alcohol Dependence, 70, 829
(2003)), may be maintained, and doses of both active ingredients therefore
lowered by an equivalent degree to preserve the same ratio.
The compositions described herein are useful in the treatment of opioid
dependency and/or addiction. Compositions described herein may also be useful
in the treatment of pain (including mild, moderate and severe pain).
According to three further aspects of the disclosure there are described:
a method of treatment of opioid dependency and/or addiction;
a method of treatment of pain; and
(iii) a method of treatment of both pain and opioid dependency and/or
addiction,
which methods comprise administration of a composition described herein to a
person suffering from, or susceptible to, the relevant conditions.
Compositions described herein may also be administered in the induction phase
(Le. the start-up) of buprenorphine therapy, wherein buprenorphine is
administered once an opioid-addicted individual has abstained from using opioids
for about 12-24 hours and is in the early stages of opioid withdrawal.
Also described is a method of treatment of opioid dependency and/or addiction,
which method comprises administration of a composition described herein to an
individual that has abstained from using opioids for at least about 12 hours and/or
is in the early stages of opioid withdrawal.
By "treatment" of pain we include the therapeutic treatment, as well as the
symptomatic and palliative treatment of the condition. However, by "treatment" of
opioid dependency and/or addiction, we further include the prophylaxis, or the
diagnosis of the relevant condition in addition to therapeutic, symptomatic and
palliative treatment. This is because, by employing buprenorphine in the
treatment of pain, compositions described herein may prevent the development of
opioid dependency and/or addiction.
The compositions described herein enable the production of unit dosage forms
that are easy and inexpensive to manufacture, and which enable the rapid
release and/or a rapid uptake of the active ingredients employed through the
mucosa, such as the oral mucosa, thus enabling rapid relief of symptoms, such
as those described hereinbefore.
The compositions described herein also have the advantage that, if injected by an
opioid addict, they do not produce the euphoric effects that such an addict seeks
and indeed induce opioid withdrawal symptoms.
Compositions described herein may also have the advantage that they may be
prepared using established pharmaceutical processing methods and employ
materials that are approved for use in foods or pharmaceuticals or of like
regulatory status.
Compositions described herein may also have the advantage that they may be
more efficacious than, be less toxic than, be longer acting than, be more potent
than, produce fewer side effects than, be more easily absorbed than, possess a
better patient acceptability than, have a better pharmacokinetic profile than,
and/or have other useful pharmacological, physical, or chemical properties over,
pharmaceutical compositions known in the prior art, whether for use in the
treatment of opioid addiction or pain or otherwise.
The term "comprising" as used in this specification and claims means "consisting
at least in part of". When interpreting statements in this specification, and claims
which include the term "comprising", it is to be understood that other features that
are additional to the features prefaced by this term in each statement or claim
may also be present. Related terms such as "comprise" and "comprised" are to
be interpreted in similar manner.
The invention is illustrated by way of the following examples, with reference to the
attached figures in which analyte concentration-time plasma profiles are
presented in linear scale plots for buprenorphine (Figure 1), norbuprenorphine
(Figure 2) and naloxone (Figure 3) following sublingual administration of tablets
comprising a composition of the invention (diamonds) and the commercially-
available comparator, Suboxone (squares); Figure 4 shows an in vivo
sublingual
pH profile obtained for a placebo composition (analogous to one prepared in
accordance with the invention); Figure 5 shows comparative in vitro
pH profiles
for composition of the invention versus Suboxone and other comparators in a
small-volume funnel dissolution test; Figures 6 and 7 show release of
buprenorphine and naloxone, respectively, from the compositions referred to in
Figure 5; Figure 8 shows comparative in vitro pH profiles for compositions of the
invention versus Suboxone and other comparators in a small-volume funnel
dissolution test; and Figure 9 show release of buprenorphine from compositions
referred to in Figure 8.
Example 1
Buprenorphine/Naloxone Sublingual Tablets I
Naloxone hydrochloride dihydrate (Macfarlan Smith, Edinburgh, UK) and
buprenorphine hydrochloride (Macfarlan Smith, Edinburgh, UK) were micronised
using an air jet mill (Pilotmill-1/Food and Pharma Systems, Italy). The volume
based mean particle size (diameter) of the buprenorphine was 3.4 pm and of the
naloxone was 4.6 pm.
9,15 g of the micronised naloxone hydrochloride dihydrate was mixed together
AvicelTM
with microcrystalline cellulose (47.50 g;
PH102 (mean particle size 100
pm), FMC Biopolymer, Cork, Ireland) and croscarmellose sodium (18.00 g;
A c DiS 0
ITM, FMC Biopolymer) in a tumble blender (Turbula, WAG, Switzerland) for
40 hours.
32.40 g of the micronised buprenorphine hydrochloride was mixed together with
mannitol (314.20 g; Pearlitol" 200SD, Roquette, Lestrem, France), sieved citric
acid (15.00 g; fine granular 16/40 grade, DSM, Switzerland, Basel) and sieved (to
avoid agglomeration) sodium citrate (48.75 g) Emprove' cryst., Merck,
Darmstadt, Germany) in a tumble blender for 40 hours,
Menthol (5.00 g; EmproveTM cryst., Merck) was mortared until a fine powder was
formed. This and also acesulfame potassium (5.00 g; Sunett Pharma D,
Nutrinova, Kelsterbach, Germany) and anhydrous colloidal silica (5.00 g;
Aeros
ilTM 200 Pharma, Evonik Degussa, Hanau-Wolfgang, Germany) were added
by sieving into the buprenorphine premix, together with the naloxone premix, and
the whole mixed together in a tumble blender for 1 hour.
PruvTM,
Sodium stearyl fumarate (10.00 g;
JRS Pharma, Poland°, Spain) was
then added by sieving into this mixture and mixing continued in the tumble
blender for 5 minutes.
The final powder mixture was then compressed into tablets in a tablet machine
(Korsch XP1) equipped with 7 mm round, flat faced, radius-edged punches, to a
tablet weight of 102 mg and a tablet crushing strength of 35 N.
Example 2
Clinical Trial
The tablets of Example 1 were sublingually administered in an open-label, 2-
period crossover study with randomised treatment sequence.
The study comprised a screening visit conducted within 28 days prior to first
treatment, two treatment periods each of 4 days length (Day -1 to Day 3) and a
washout period of at least 10 days between treatment periods. During the
treatment periods, subjects were admitted to the clinical unit on the morning prior
to first dosing (Day -1) and remained in the unit until the completion of Day 3
procedures. A follow-up visit was carried out 5 to 10 days after completion of the
second Investigational Medicinal Product (IMP) administration.
The IMPs were sublingual tablet prepared in accordance with Example 1 (6 mg
buprenorphine/1,5 mg naloxone; hereafter "formulation of the invention") and, as
the reference product, Suboxone sublingual tablet (8 mg buprenorphine/2 mg
naloxone; Reckitt Benckiser Healthcare Ltd, Hull, UK). Treatment with
formulation of the invention, or Suboxone (1 tablet) in alternate periods was open-
label and was administered on Day 1 in each treatment period.
Naltrexone tablets (Naiorex ®, 50 mg, Bristol-Myers Squibb Pharmaceuticals Ltd;
Uxbridge, UK) were administered orally (one 50 mg tablet), at -24 to -16 hours, -1
hour (±5 minutes) and +24 hours (±1 hour) in relation to administration of IMP, as
a naltrexone block in the study (in order to alleviate opioid side effects during the
study).
Eighteen healthy male volunteers aged between 18 and 50 years were enrolled.
These received both treatments and were evaluated. The mean age was 29,8
years and ages ranged from 19 to 49 years. All subjects were male Caucasians,
The mean weight was 78.16 kg and ranged from 63.0 to 93.5 kg. The mean body
mass index of the subjects was 25.05 kg/m 2 and ranged from 20.7 to 28.9 kg/m
All subjects (except one) reported current alcohol use ranging from 1 to 20 units
per week. No subject was a current smoker. All subjects reported current
caffeine use of 1 to 5 cups or cans per day. No subject had been treated with
opioids within 1 year prior to screening.
No subject reported any pre-study medication (taken within 2 weeks prior to
screening). One subject reported ongoing use of antihistamines for systemic use
by oral tablet or capsule to treat seasonal allergic rhinitis.
Trial medication was administered in the clinic under the supervision of clinic
personnel.
All subjects who were enrolled in the study and who received at least one dose of
trial medication. All randomised subjects who received at least one treatment,
had at least one evaluable plasma profile and had no major protocol deviations
that could have a substantial effect on the buprenorphine, norbuprenorphine or
naloxone plasma concentration profile, such as:
swallowing of study medication (applies to both formulation of the
invention and Suboxone)
• vomiting within 4 hours after administration of either type of tablet
• having a pre-dose quantifiable concentration that is > 5% of a subject's
Cmax
All randomised subjects who received at least one treatment and had
disintegration or acceptability data present for at least one treatment.
Pharmacokinetic (PK) variables were based on plasma concentrations of
buprenorphine, norbuprenorphine (a metabolite of buprenorphine) and naloxone
and were calculated using standard, non-compartmental methods. The PK
WinNonlinTM
non-compartmental analysis was performed using Professional
version 5.2. Data permitting, the following parameters were determined:
lag time before the start of absorption
maximum plasma concentration
time to reach maximum plasma concentration
area under the plasma concentration-time curve from time zero to
the time of the last quantifiable plasma concentration
AUC0-48 area under the plasma concentration-time curve from time zero to
48 hours post-dose
MR metabolic ratio
In addition, the relative bioavailability (F
rei) of formulation of the invention to
Suboxone was derived based on dose-adjusted PK data,
Subjects were classified as evaluable or non-evaluable with respect to the PK
evaluation by the pharmacokineticist after examining the subjects PK profiles and
taking into account any deviations with respect to those listed above. The PK
analyses based on the PK population included only those subjects with evaluable
PK data.
Actual blood sampling times for buprenorphine, norbuprenorphine and naloxone
were converted to a time from dosing (elapsed time), Elapsed times were listed
by subject for each treatment, together with the individual buprenorphine,
norbuprenorphine and naloxone concentrations. Elapsed times were used in the
PK analysis.
The buprenorphine, norbuprenorphine and naloxone concentrations were
summarised by descriptive statistics of number of missing samples, number of
samples less than the lower limit of quantification (<L00), n, arithmetic mean,
SD, CV(%), geometric mean, 95% confidence intervals (Cl) for the arithmetic
mean, median, minimum and maximum. All buprenorphine, norbuprenorphine
and naloxone concentrations <LOQ were set to zero for the purpose of
calculating descriptive statistics. If at any time-point 1/3 or more of subjects had
values <LOQ, descriptive statistics were not calculated.
The PK parameters Cmax, AUCo_t and AUC0_48 of buprenorphine, norbuprenorphine
and naloxone were compared between treatments using a mixed effects Analysis
of Variance (ANOVA) procedure.
Arithmetic mean (+SEM) analyte concentration-time plasma profiles are
presented in linear scale plots for each analyte in Figures 1 (buprenorphine), 2
(norbuprenorphine) and 3 (naloxone) with both treatments included on each plot.
It can be seen from these figures that, for both buprenorphine and
norbuprenorphine after administration of formulation of the invention (diamonds),
and Suboxone (squares), plasma concentrations of all three analytes increased
to a maximum then declined in a biphasic manner.
In relation to other PK parameters:
on average, the lag time was slightly shorter after treatment with
formulation of the invention compared to Suboxone by 15% for
buprenorphine, 29% for norbuprenorphine and 34% for naloxone;
the range of times at which maximal concentrations were attained
(1,,
() was similar between treatments for all analytes. Median t,„,
values were less than or equal to 1 h for buprenorphine and naloxone
indicating rapid sublingual absorption following administration of both
formulation of the invention and Suboxone. For norbuprenorphine,
t,„ was generally similar to buprenorphine after both treatments
indicating metabolism of buprenorphine to norbuprenorphine was
rapid;
the mean metabolite ratios exceeded 0.5 indicating extensive
metabolic conversion of buprenorphine to norbuprenorphine, with
conversion being 31% lower following administration of formulation of
the invention compared to Suboxone. This result is significant as it
means that more buprenorphine is absorbed sublingually in the case
of formulation of the invention;
(iv)
the doses of both buprenorphine and naloxone were lower in the
formulation of the invention, but mean systemic exposure, in terms of
C max
and AUC, of buprenorphine and naloxone were higher when
compared to Suboxone, and, as stated above, the values were lower
for norbuprenorphine; and
(v) the mean relative bioavailabilities of formulation of the invention to
Suboxone were 1.659 and 2.056 for buprenorphine and naloxone
respectively, indicating higher dose-normalised systemic exposure
following administration of formulation of the invention. For
norbuprenorphine the dose-normalised systemic exposure appeared
to be similar between treatments with a mean relative bioavailability of
1.084. The buprenorphine result is surprising. The reported relative
bioavailability of a sublingually-administered ethanol solution
comprising buprenorphine (where conditions are theoretically
optimised for rapid absorption over the sublingual mucosa) compared
to Suboxone was reported to be 1.5 (see Compton et al, Drug and
Alcohol Dependence,
82, 25 (2006)). The fact that the relative
number reported in this study for a solid sublingual tablet was even
higher than that reported for a solution is remarkable.
Disintegration time of the tablets was assessed by either a nurse or a physician
by mouth inspections, and was also reported by the subjects, who were given
thorough instructions of the dosing procedures prior to dosing on Day 1 in both
treatment periods, including the procedures for observer and subject
assessments of disintegration.
Subjects were to report any premature
swallowing.
The sublingual space and the tablet were examined to determine the time to
disintegration. The tablet residues were characterised as 'intact', fragments',
'paste like residue' or 'dissolved'. Inspections were carried out every 2 minutes
and the findings recorded until the tablet was completely disintegrated. In
addition, the subject was instructed to indicate when they thought the IMP was
dissolved by raising their hand or to indicate whether they had swallowed the
tablet before it was dissolved.
The time of dissolution or swallowing was
recorded.
Median time to non-intact tablets was 2 minutes for the formulation of the
invention and was 8 minutes for Suboxone.
Summary and Conclusions
The above-reported parameter ratios suggest that the formulation of the invention
resulted in slightly higher plasma buprenorphine and naloxone concentrations
and slightly lower plasma norbuprenorphine concentrations than the comparator.
The former result is despite the initial dose being lower which indicates that it may
be possible to reduce dose still further. Tablets comprising formulations of the
invention also disintegrated faster than the comparator.
Example 3
Buprenorphine/Naloxone Sublingual Tablets II
3.97 g of micronized naloxone hydrochloride dihydrate was mixed together with
microcrystalline cellulose (20.00 g; Avicel" PH102 (mean particle size 100 pm),
AcDiS0ITM,
FMC Biopolymer) and croscarmellose sodium (7.20 g; FMC
Biopolymer) in a tumble blender (Turbula, WAG, Switzerland) for 40 hours.
14.04 g of micronised buprenorphine hydrochloride was mixed together with
mannitol (130.30 g; Pearlitol T" 200SD, Roquette, Lestrem, France), sieved citric
acid (6,00 g; fine granular 16/40 grade, DSM, Switzerland, Basel) and sieved (to
avoid agglomeration), sodium citrate (1950 . g) EmproveTM cryst., Merck,
Darmstadt, Germany) and blended in a tumble blender for 42 hours.
Menthol (2.00 g; EmproveTM cryst,, Merck KGaA, Darmstadt, Germany) was
mortared until a fine powder was formed and was blended with silicon dioxide,
AerosilTM
colloidal (0.20 g;
200 Pharma), (1:1 volume ratio),
Sucralose (6.00 g, Merck KGaA, Darmstadt, Germany) was added to the
buprenorphine premix. The naloxone premix and the rest of the silicon dioxide
colloidal (2.80 g) were added by co-sieving into the buprenorphine premix. The
menthol-silicon dioxide blend was added by sieving to the buprenorphine premix
and all ingredients were mixed for 1 hour.
PruvTM,
Sodium stearyl fumarate (8.00 g; JRS Pharma, Polane°, Spain) was then
added by sieving into this mixture and mixing continued in the tumble blender for
minutes.
The final powder mixture was then compressed into tablets in a tablet machine
(Korsch EKO) equipped with 7 mm round, flat faced, radius-edged punches, to a
tablet weight of 110 mg and a tablet crushing strength of 30-35 N.
Example 4
In Viva Experiment
Placebo tablets prepared according to the procedure described in Example 1
above (excluding buprenorpine, but including naloxone) were first administered
sublingually.
Sublingual saliva pH was measured in vivo
using a Schott CG 842P pH Meter
attached to a Schott Flatrode nn-electrode (pH 0-14, 0-60°C). The Flatrode
TM has
a super-flat membrane for surface measurements and a robust plastic shaft with
a ring diaphragm, which guarantees a quick response
via enhanced contact
between the sample and reference. The diameter of the flat surface of the
electrode is 6.0 mm giving a measuring surface of 0.28 cm'.
The Flatrode was positioned (at an open mouth angle of 45°) gently behind the
lower teeth, just beside the tablet in the mouth. A very gentle pressure was
applied in order to measure pH in saliva rather than venous blood pH (typically
pH 7.4).
pH was measured at time intervals of 0, 30, 60 and 90 seconds (over 5 seconds
until a stable value was observed).
Care was taken to avoid accidental
withdrawal of dissolved powder by the electrode. The mouth was shut between
measurements with no active swallowing.
Triplicate runs were carried out to ensure a reliable pH-profile. Between runs, the
mouth was washed thoroughly with water and pH measured prior to
administration to obtain a new zero-value.
The results indicated that the pH decrease peaked at around 35-40 seconds. It
can be seen from Figure 4 that the body rapidly compensates for the modified pH
and also slightly overcompensates, and that the window of opportunity (i.e. the
time range with a 0.5 pH unit decrease (at least) compared to resting pH) for
increased solubility of buprenorphine is only about 80 seconds, starting after 10
seconds (n=4).
Example 5
Comparative In Vitro Small-Volume Funnel Dissolution Experiment I
In addition to the sublingual tablets described in Example 3 above, two other
otherwise identical batches of sublingual tablets were prepared using the same
methodology, except that, in one case, the buprenorphine hydrochloride was not
micronized, and in the other, no citric acid and sodium citrate were included
(instead a further 12.75 mg per tablet of mannitol was included.
Tablets form the three above-mentioned tablet batches, as well as Suboxone
tablets (buprenorphine 8 mg/naloxone 2 mg; Reckitt Benckiser Healthcare Ltd,
Hull, UK) were placed on top of a Porosity 1 20 mm diameter silica filter in a 55
mm (upper inner diameter) glass funnel.
Potassium phosphate buffer with a pH of 6.8 (USP/NF), which mimics saliva, was
allowed to drip through a soft PVC plastic tube with an inner diameter of 3 mm
onto the tablets at a rate, set by a peristaltic pump (Flocon 1003), of 2 mL per
minute. The ciislance between the end of the plastic tube and the silica filter in
the funnel was set at approximately 7.5 cm, in order, along with the dripping rate,
to correspond to a force similar to the pressure of the underside of the tongue.
The small amounts of water involved endeavour to mimic the low amounts of
water available in vivo
under the human tongue.
pH was measured over time using a Mettler Toledo InLab Expert Pro electrode
(pH 0-14; 0-100°C) attached to standard Mettler Toledo 340 pH meter positioned
at the outlet of the glass funnel.
To measure the release of active pharmaceutical ingredients over time from the
tablets, a glass beaker equipped with a magnetic stirrer containing 490 mL of
potassium phosphate buffer pH 6.8 (USP/NF) collected the drops from the funnel.
800 pL samples were withdrawn from the beaker using a calibrated micropipette
at intervals of 0,5, 1.0, 1.5, 2.0, 2.5, 3.0, 3.5, 4.0, 4.5, 5.0, 10.0, 15.0 and 20.0
minutes. These samples were emptied into 1 mL vials already containing 200 pL
of diluted phosphoric acid. No additional buffer was added to the collection
beaker to compensate. It started with a volume of 490 mL and ended with a
volume of 520 mL (the difference between 40 mL added to the beaker over 20
minutes, and 10.4 mL removed in total (13 x 0.8 mL) is 29.6 mL (i.e. about 30
mL)). It was decided to start at 490 mL instead of 485 mL to be as close to 500
mL for as long a period as possible. The exact individual volumes were of course
calculated for each sample.
Three tablets from each of the four tablet table batches in the trial were analysed
as release test samples. Amounts of buprenorphine and naloxone were
measured using HPLC (Agilent 1000; Diode array-detector, gradient pump,
autosampler, column oven), with a gradient method with UV detection at 210 nm,
pH was plotted over time for the following four tablet batches and the results are
shown in Figure 5 (tablets prepared according to Example 3 (squares); non-
micronised buprenorphine equivalents (crosses); equivalents without citric
acid/sodium citrate (diamonds); and Suboxone (triangles)). The dashed line in
Figure 5 is the superimposed in vivo profile from Figure 4.
The drug release profiles over the first 5 minutes for buprenorphine and naloxone
are presented in Figures 6, and 7, respectively. Although Suboxone has a 23%
higher drug loading than all of the other tablets, it produces a buprenorphine
release after 20 minutes through the funnel of only 75% of that of the tablets
according to the invention. The difference is most noticeable over the first 5
minutes.
Example 6
Buprenorphine/Naloxone Sublingual Tablets ill
336.0 g of micronized naloxone hydrochloride dihydrate was mixed together with
AvicelTM
microcrystalline cellulose (2000.0 g;
PH102 (mean particle size 100 pm),
FMC Biopolymer, Wallington, Little Island, Co. Cork, Ireland) and croscarmellose
AcDiS0ITM,
sodium (720.0 g; FMC Biopolymer, Wallington, Little Island, Co. Cork,
Ireland) in a 12 L double cone blender (Sewin, Zickert systems, Kungsbacka,
Sweden) for 3 hours.
Citric acid (600.0 g; fine granular 16/40 grade, DSM, Switzerland, Basel), sodium
citrate (1950.0 g Emprove T
m cryst., Merck, Darmstadt, Germany) and silicon
AerosilTM
dioxide, colloidal (480.0 g
200 Pharma, Evonik Degussa GmbH,
Rheinfelden, Germany) were deagglomerated together with Quadro comil
apparatus (Quadro Engineering, Ontario, Canada) and premixed with two thirds
PearlitolTM
of a pre-measured amount of mannitol (8737.3 g;
200SD, Roquette,
Lestrem, France) in a 60 L double cone blender (Sewin, Zickert systems,
Kungsbacka, Sweden) for 5 minutes.
1188.0 g of the micronised buprenorphine hydrochloride was added to the premix
and the other third of the mannitol (4368.7 g) was added on top of the
buprenorphine hydrochloride and all ingredients were mixed for 3 hours.
Menthol (200.0 g; EmproveTM cryst., Merck KGaA, Darmstadt, Germany) was
milled with Quadro comill. Silicon dioxide, colloidal (20.0 g) and milled menthol
(1:1 volume ratio) was processed with Quadro comill in order to deagglomerate
the silicon dioxide (colloidal).
Sucralose (600.0 g, Merck KGaA, Darmstadt, Germany), the naloxone premix
and the menthol-silicon dioxide blend were added to the buprenorphine premix
and all ingredients were mixed for 1 hour.
Sodium stearyl fumarate (800.0 g; Pruy Tm
, JRS Pharma, Polanco, Spain) was
deagglomerated with Quadro comil and added to double cone blender and mixed
for 10 minutes.
The final powder mixture was then compressed into tablets in a tablet machine
(Korsch XL100, Korsch AG, Berlin, Germany) equipped with 7 mm round, flat
faced, radius-edged punches, to a tablet weight of 110 mg and a tablet crushing
strength of 30-35 N.
Example 7
Buprenorphine/Naloxone Sublingual Tablets IV
200,000 100 mg buprenorphine/naloxone (4:1 dose ratio) tablets comprising a 1.4
mg dose of buprenorphine (calculated as the free base) were prepared using
essentially the same procedure as described in Example 6.
Example 8
Buprenorphine/i\!aloxone Sublingual Tablets V
200,000 110 mg buprenorphine/naloxone (4:1 dose ratio) tablets comprising a 5.7
mg dose of buprenorphine (calculated as the free base) were prepared using
essentially the same procedure as described in Example 6.
Example 9
Comparative In Vitro Small-Volume Funnel
Dissolution Experiment II
Using the in vitro
small-volume funnel dissolution procedure described in
Example 5, pH profiles (measurement of pH over time) were obtained for:
buprenorphine/naloxone sublingual tablets prepared as described in
Example 8;
buprenorphine/naloxone sublingual tablets prepared essentially as
described in Example 8, except that the citric acid and sodium citrate were
included during the mixing step in which the two APIs are mixed together;
buprenorphine/naloxone sublingual tablets prepared essentially as
described in Example 8, but without citric acid (i.e. sodium citrate only);
(d) buprenorphine/naloxone sublingual tablets prepared essentially as
described in Example 8, but without sodium citrate (i.e. citric acid only);
(e) buprenorphine/naloxone sublingual tablets prepared essentially as
described in Example 8, except that tartaric acid (Sigma-Aldrich) was
used instead of citric acid and sodium citrate; and
Suboxone0 film (8 mg buprenorphine/2 mg naloxone; Reckitt Benckiser
Healthcare Ltd, Hull, UK).
In the case of tablets (c), and (d), an equivalent amount of mannitol was
employed instead of the citric acid, and the sodium citrate, respectively, that was
excluded. In the case of tablets (e), 2 mg (per tablet) of tartaric acid and an extra
.75 mg (per tablet) of mannitol were employed.
The results are shown in Figure 8 (tablets (a) — diamonds; tablets (b) — light grey
squares; tablets (c) - triangles; tablets (d) — black squares; tablets (e) — mid-grey
squares; and Suboxone films (f) - circles). Also superimposed on Figure 8 are:
the
in vivo profile from Figure 4 (dashed line); and
the in vitro pH profile previously obtained for Suboxone® tablets (solid
line; originally presented in Figure 5).
The drug release/dissolution profiles over the first 5 minutes for buprenorphine
are presented in Figure 9. It can be clearly seen from Figures 8 and 9 taken
together that drug dissolution correlates strongly with how much the pH is
lowered during first 1 minute to 2 minutes after the start of the experiment
(corresponding to sublingual administration in vivo). It can also be seen that the
largest pH drop, and the highest dissolution rate, were obtained when citric acid
alone was used.
The following numbered paragraphs define particular aspects of the present
invention:
1. A pharmaceutical
composition comprising microparticles of a
pharmacologically-effective amount of buprenorphine, or a pharmaceutically-
acceptable salt thereof, in associative admixture with particles comprising a weak
acid, or particles comprising weakly-acidic buffer forming materials.
A composition according to paragraph 1, wherein the microparticles of
buprenorphine have a weight based mean diameter of less than about 15 i.trn.
3. A composition according to paragraph 1 or paragraph 2, wherein the weakly
acidic material comprises citric acid, tartaric acid, malic acid, fumaric acid, adipic
acid, succinic acid, lactic acid, acetic acid, oxalic acid, maleic acid, ammonium
chloride or a combination thereof.
4. A composition according to paragraph 1 or paragraph 2, wherein the buffer
forming materials comprise a combination of a weakly acidic material and a salt
of a weakly acidic material.
. A composition according to paragraph 4, wherein the weakly acidic
material is as defined in paragraph 3.
A composition according to paragraph 4 or paragraph 5, wherein the salt is
sodium citrate, potassium citrate, sodium tartrate or potassium tartrate.
A composition according to any one of the preceding paragraphs wherein
the buffer system is citric acid/sodium citrate.
A composition according to any one of the preceding paragraphs which is
presented as an interactive mixture comprising microparticles of buprenorphine or
a pharmaceutically acceptable salt thereof presented upon the surfaces of carrier
particles.
A composition according to paragraph 8, wherein the carrier particles are of
a size that is between about 100 and about 800 pm,
10. A composition according to paragraph 8 or paragraph 9, wherein the carrier
particles are water-soluble.
11. A composition according to any one of paragraphs 8 to 10, wherein the
carrier particles comprise mannitol.
12. A composition according to any one of paragraphs 8 to 11, wherein the
particles of weak acid, or of weakly-acidic buffer forming materials, are presented
and act as carrier particles.
13. A pharmaceutical composition according to any one of the preceding
paragraphs, which further comprises a disintegrant.
14. A composition according to paragraph 13, wherein the disintegrant is a
superdisintegrant selected from croscarmellose sodium, sodium starch glycolate,
crosslinked polyvinylpyrrolidone or a mixture thereof.
. A pharmaceutical composition according to any one of the preceding
claims, which further comprises a pharmacologically-effective amount of
naloxone, or a pharmaceutically-acceptable salt thereof.
16. A pharmaceutical composition according to paragraph 15, wherein the
composition comprises particles comprising naloxone or salt thereof and
disintegrant.
17. A composition according to any one of the preceding paragraphs which is in
the form of a tablet suitable for sublingual administration.
A process for the preparation of a composition as defined in any one of
paragraphs 8 to 17, which comprises dry mixing carrier particles with
buprenorphine or salt thereof.
A process for the preparation of a composition as defined in any one of
paragraphs 15 to 17, which comprises a process according to paragraph 18,
followed by admixing with particles comprising naloxone or salt thereof and
disintegrant.
A process for the preparation of a sublingual tablet as defined in paragraph
17, which comprises directly compressing or compacting a composition as
defined in any one of paragraphs 1 to 16.
A method of treatment of opioid dependency and/or addiction, and/or pain,
which method comprises administration of a composition as defined in any one of
paragraphs 1 to 17 to a person suffering from, or susceptible to, the relevant
condition(s).
A composition as defined in any one of paragraphs 1 to 17 for use in a
method of treatment of opioid dependency and/or addiction, and/or pain.
The use of a composition as defined in any one of paragraphs 1 to 17 for the
manufacture of a medicament for a method of treatment of opioid dependency
and/or addiction, and/or pain.
In this specification where reference has been made to patent specifications,
other external documents, or other sources of information, this is generally for the
purpose of providing a context for discussing the features of the invention.
Unless specifically stated otherwise, reference to such external documents is not
to be construed as an admission that such documents, or such sources of
information, in any jurisdiction, are prior art, or form part of the common general
knowledge in the art.
In the description in this specification reference may be made to subject matter
that is not within the scope of the claims of the current application. That subject
matter should be readily identifiable by a person skilled in the art and may assist
in putting into practice the invention as defined in the claims of this application.
Claims (19)
1. A tablet suitable for sublingual administration comprising; microparticles of buprenorphine, or a pharmaceutically-acceptable salt thereof; 5 (b) particles comprising a weak acid; naloxone, or a pharmaceutically-acceptable salt thereof; and (d) a disintegrant, wherein, in an in vitro small-volume funnel dissolution test (as herein defined), the tablet exhibits: (1) a maximum pH drop from 6.8 of between 0.5 and 5 pH units within about 1 minute; followed by (2) a return to the initial pH (±0.5) within about 3 minutes, with the pH drop and increase being measured from the start of dripping from the outlet of the glass funnel. 15 2.
A tablet as claimed in Claim 1, wherein the dose ratio of buprenorphine:naloxone is about 4:1 (calculated as free bases).
A tablet as claimed in Claim 2 wherein the dose of buprenorphine is 11.4 mg, 8.6 mg, 5.7 mg, 2.9 mg or 1.4 mg.
4. A tablet as claimed in any one of the preceding claims, wherein the microparticles of buprenorphine or salt thereof are associatively admixed together with the particles comprising weak acid.
A tablet as claimed in Claim 4, wherein the admixture comprises dry mixing the microparticles of buprenorphine, or salt thereof, together with the particles comprising weak acid.
6. A tablet as claimed in any one of the preceding claims, wherein the weakly 30 acidic material comprises citric acid, tartaric acid, malic acid, fumaric acid, adipic acid, succinic acid, lactic acid, acetic acid, oxalic acid, maleic acid, ammonium chloride or a combination thereof.
7. A tablet as claimed in any one of the preceding claims, in which microparticles of buprenorphine or pharmaceutically acceptable salt thereof are attached to, adhered to, or associated with, the surfaces of larger carrier particles.
8. A tablet as claimed in Claim 7 in which said particles comprising weak acid are presented, at least in part, upon the surfaces of, and/or between, said carrier particles. 10
9. A tablet as claimed in any one of the preceding claims, wherein the disintegrant is selected from the group croscarmellose sodium, sodium starch glycolate, crosslinked polyvinylpyrrolidone and mixtures thereof.
10. A tablet as claimed in any one of the preceding claims, wherein the 15 naloxone or pharmaceutically-acceptable salt thereof is provided in the form of particles.
11. A use of a tablet according to any one of the preceding claims for the manufacture of medicament for use in a method of treatment of a patient, which method comprises administration of said tablet to said patient.
12. A use of a tablet comprising: (i) microparticles of a pharmacologically-effective amount of buprenorphine, or a pharmaceutically-acceptable salt thereof; 25 particles comprising a weak acid; particles of a pharmacologically-effective amount of naloxone, or a pharmaceutically-acceptable salt thereof; and (iv) a disintegrant, wherein the dose ratio of buprenorphine:naloxone is about 4:1 (calculated as free 30 bases), for the manufacture of a medicament for use in a method of treatment of a patient, which method comprises sublingual administration of said tablet to said patient.
13. A use as claimed in Claim 11 or Claim 12, wherein said administering is for treatment of opioid dependency and/or addiction.
14. A use as claimed in Claim 13, wherein the dose of buprenorphine in the tablet is 11.4 mg, 8.6 mg, 5.7 mg, 2.9 mg, or 1.4 mg; and wherein the use achieves, after an initial dose, a plasma-concentration time profile as 5 characterized by: (a) the maximum plasma concentration (C,); and/or (b) the total area under the plasma concentration-time curve from time zero to the time of the last measured plasma concentration (AUC t ); and/or the area under the plasma concentration-time curve from time zero to 10 the last concentration extrapolated to infinity based on the elimination rate constant (AUCinf), for buprenorphine and naloxone that is between about 80% and about 125% of the corresponding values obtained for a random mixture compressed tablet comprising doses of buprenorphine:naloxone that are 16:4 mg, 12:3 mg, 8:2 mg, 15 4:1 mg or 2:0.5 mg, respectively.
15. A use as claimed in Claim 14, wherein the random mixture compressed tablets are formed by compression of a random mixture, prepared by wet granulation of a standard mixture comprising buprenorphine hydrochloride, 20 naloxone hydrochloride dihydrate, lactose monohydrate, mannitol, maize starch, povidone K30, citric acid (anhydrous granular), sodium citrate, natural lemon and lime flavour, acesulfame potassium and magnesium stearate, and have a tablet strength in the range of about 80 to about 180 N (US Pharmacopeia method <1217>).
16. A use as claimed in any one of Claims 12 to 15, wherein the weakly acidic material comprises citric acid, tartaric acid, malic acid, fumaric acid, adipic acid, succinic acid, lactic acid, acetic acid, oxalic acid, maleic acid, ammonium chloride or a combination thereof.
17. A use as claimed in any one of Claims 12 to 16, wherein the disintegrant is selected from the group croscarmellose sodium, sodium starch glycolate, crosslinked polyvinylpyrrolidone and mixtures thereof.
A tablet as claimed in Claim 1, substantially as herein described with reference to any example thereof.
19. A use as claimed in Claim 11 or 12, substantially as herein described with 5 reference to any example thereof.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US201161536180P | 2011-09-19 | 2011-09-19 | |
US61/536,180 | 2011-09-19 | ||
NZ618120A NZ618120B2 (en) | 2011-09-19 | 2012-09-18 | New abuse-resistant pharmaceutical composition for the treatment of opioid dependence |
Publications (2)
Publication Number | Publication Date |
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NZ709502A NZ709502A (en) | 2017-01-27 |
NZ709502B2 true NZ709502B2 (en) | 2017-04-28 |
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