Title of Invention

AEROGEL POWDER AND A PROCESS FOR MANUFACTURING IT

Abstract A dispersible dry powder for pulmonary delivery comprising a therapeutically effective amount of a therapeutic agent in combination with an aerogel particle such as herein described which can react the alveoli of subject's lung and is soluble in human pulmonary surfactant.
Full Text Background of the Invention
The present invention is directed to an improved method of delivering
pharmaco-therapeutic agents in which the time required for drug delivery into a
patient's blood stream is substantially reduced. The delivery is direct to the blood
stream, but non-invasive, non-disruptive, and pain-free. Examples of the classes
of pharmaco-therapeutic agents which may be delivered in accordance with the
present invention include such as: opioid-receptor agonists/antagonists, dopamine-
receptor agonists/antagonists, serotonin-receptor agonists/antagonists, monoamine
transporter agonists, antimanic agents, anti-smoking agents and immunogenic ther-
apies (antibody products to reduce peripheral levels of drug substances), vaccines,
antibiotics, high blood pressure drugs, heart medications, asthma medications,
sexual dysfunction medications, analgesics, anesthesia drugs, insulin, and the like.
There are four general types of drug delivery currently available: oral,
injection either intravenous, subcutaneous or transdermal, implants, and inhalation.
Each of the methods has advantages and disadvantages.
1. Oral administration is acceptable in most cases except that the drug
delivery rate is often too slow and it can cause digestive tract upset.
2. Intravenous injection is effective, but is intrusive, painful, has a danger
of caus-ing adverse reactions from the body due to a high concentration drug
flowing through one small pathway, and presents a danger of infection both for the
patient and the health-giver alike. Also if the injections have to occur frequently,
such as once or twice a day for insulin as an example, there is a problem of running
out of injectable locations let alone pain, bruises and danger of infections.
Transdermal injection can be an answer to a lot of problems but has not been
widely used. The technology is still in early stages of development.
3. Implants are used to avoid multiple shots and to maintain constant dosage
over a long period of time, but requires invasive surgery.
. 4. Inhalation is an ideal drug delivery method. It can be done widely and
conveniently because it is very fast and non-intrusive. Inhalants such as for asthma
have shown a lot of promise but they are still not completely satisfactory. They
take effect very rapidly, sometimes even faster than intravenous injection, but the
inhalant method is currently limited to a few medications due to the difficulties of
forming suitable dispersions for delivery into the lungs. Also most inhalants today
use a chloro-fluoro compound (CFC) as a dispersant and there is a movement to
move away from CFC's for environmental reasons as well as suspected harmful
effects that CFC's might have inside the body.
The development of the first pressurized metered dose inhaler (MDI) in the
mid-1950s was a major advance in the administration of drugs locally to the lung,
especially for the treatment of asthmatics. More recently, research has focused on
using the lung as a conduit to deliver biomolecules such as peptides and proteins
to the systemic circulation. Sophisticated dry powder inhaler (DPI) and metered
solution devices have also been designed, both to improve deep-lung delivery and
to address the MDI actuation/breath coordination issue that is problematic for
certain patients. Relatively little development effort has been applied to improve
pulmonary drug delivery by means of new formulation strategies.
One attempt to produce an improved inhalant drug delivery system is that of
Alliance Pharmaceutical which is based upon "PulmoSpheres" which are prepared
by mixing a drug and a surfactant to form an emulsion and then spray-drying the
emulsion to cause the drug to be encased in the shells of hollow, porous, micro-
scopic surfactant spheres. The resultant powder is then suspended in a fluorochem-
ical or other propellant or carrier for delivery of the drug medications into the
lungs or nasal passages of a patient. The hollow/porous morphology of the micro-
spheres allows non-aqueous liquid propellants such as fluorochemicals to permeate
within the particles, improving suspension stability and flow aerodynamics while
impeding particle aggregation. U.S. Patent No. 6,123,936 utilizes this technology
to produce a dry powder formulation for interferons. Use of the spray-drying pro-
cess precludes the preparation of products from any heat-sensitive pharmaceuticals
since the drying must be conducted at elevated temperature, i.e. about 50 to 200°C.
Moreover, the densities of porous particles that can be produced by a spray-
drying process, although much lower than many currently available solid or liquid
inhalant particles, are still too high for many uses resulting in too much of the drug
which is being delivered not reaching the lung surfaces.
The porosity and surface area of the aerogel products of this invention are
much higher than those of spray-dried particles. The density of the aerogel pro-
ducts, which can be as low as about 0.003 g/cc, is much lower than both the Pulmo-
Spheres (about 0.1 g/cc) and that of crystalline powders (about 1 g/cc). As a result,
the aerogel inhalants of this invention float much longer resulting in more
pharmaceutical material reaching the inner part of lungs. Thus the delivery
efficiency is improved.
Although the primary intended use of aerogels heretofore has been in the
field of insulation, some inorganic oxide aerogels have been used as carriers for the
delivery of agricultural, veterinary medicines, and pharmaceuticals. For example.
Australian Patent 711,078 discloses the use of aerogels prepared from inorganic
oxides like silica by surface modifying them for hydrophobicity and then use as
carriers in agricultural and veterinary medicine, i.e. to carry an active material such
as insecticides, nematicides, etc. as well as viruses, bacteria, and other micro-
organisms. Australian Patent 9965549 discloses the use of inorganic aerogels as
carriers for pharmaceutically active compounds and preparations as solid, semi-
solid and/or liquid oral preparations.
, None of the prior aerogels and uses thereof are related to aerogel particles
which are soluble in pulmonary surfactant or the use of such particles as a dosage
form for delivery of a pharmaceutical by inhalation as in the present invention.
It is an object of this invention to substantially increase the applicability of
inhalation drug delivery to wider class of drugs by producing them in the form of
aerogel powders.
It is a further object of this invention to formulate an aerogel powder form
of a drug so that it is capable of reaching much of the available mucous area inside
the lungs.
It is a further object of this invention to formulate an aerogel powder form
of a drug for quick dissolution and introduction into the blood stream of mammals
and quick release of the drug.
It is a further object of this invention to formulate an aerogel powder form
of a drug for quick introduction into the blood stream of mammals and controlled
release of the drug thereafter.
It is a further object of this invention to formulate an aerogel powder form
of a drug for a long shelf life by making it physico-chemically stable in its
composition and packaging.
It is a further object of this invention to produce devices and equipment
suitable for delivery of an aerogel powder form a drug.
It is a further object of this invention to produce a controlled drug
administration environment, e.g. room, in which drug delivery may be done
passively, without coercion, man-handling, or intrusive measures.
SUMMARY OF THE INVENTION
This invention is directed to an aerogel powder form of a pharmaco-
therapeutic agent for use as an inhalant for mammals including humans.
More specifically, in one embodiment the invention involves preparing
highly porous, low density, submicron to micron size aerogel particles directly
from a therapeutic substance of interest as an inhalant. In a second embodiment,
wet - ultra-fine porous gels are prepared from a material which is soluble in
pulmonary surfactant, if necessary the solvent used to prepare the wet gels is
exchanged for a solvent in which the therapeutic agent is dissolved, then a solution
of the therapeutic agent in a solvent is penetrated into the pores of the wet gel by
soaking until the desired deposition occurs, and the aerogels formed by super-
critical drying. In both embodiments the resulting aerogels are then milled to the
desired final particle size.
The aerogel particles of the present invention exhibit a low density (down
to about 0.003 g/cc), an extremely high porosity (up to about 95%), a high surface
area (up to about 1000 m2/g) and a small particle size (micron and below). As a
result of these properties, a pharmaceutical in the form of an aerogel powder results
in a non-invasive high rate drug delivery system. The aerogel powders are in the
form of extremely light, ultra-fine particles which will be easily airborne for an
extended time during inhalation before settling down by gravity. This enables them
to reach the innermost alveoli of the lungs and deliver the drug into the blood
stream very rapidly.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
The inhalable aerogel particle drug delivery method of the present invention
is applicable to the preparation and use of inhalable forms of common therapeutic
drugs such as insulin, aspirin, Viagra®, asthma medication, cold medication,
antibiotics, etc. The drugs are delivered into the blood stream of a patient at a
delivery rate well exceeding the drug delivery rate of intravenous injection and
without the sting of a needle. The aerogel particle method bypasses potential
problems with the digestive system and enables the medication to take effect at a
much faster rate than is possible today.
Examples of substances that can be produced in the aerogel form of the
present invention include but is not limited to: methadone, Orlaam®, Buprenor-
phine®, nicotine, other opioid-receptor agonists/antagonists, dopamine-receptor
agonists/antagonists, serotonin-receptor agonists/antagonists, monoamine trans-
porter agonists, anti-manic agents, anti-smoking agents and immunogenic therapies
(antibody products to reduce peripheral levels of drug substances), vaccines,
antibiotics, high blood pressure drugs, heart medications, asthma medications,
sexual dysfunction medications, analgesics, anesthesia drugs, diabetic medications,
and the like.
Particularly suitable substances are those useful in drug treatment programs.
Methadone, a synthetic narcotic, which has been used for more than 30 years to
treat heroin addiction by suppressing withdrawal symptoms and curbing the craving
for heroin is particularly suitable. It is moderately soluble (12g/100 mL) in water,
the preferred dosage vehicle since the mucous membrane transfers water to the
particle on contact. Orlaam, another synthetic narcotic known generically as levo-
methadyl acetate, was approved in 1993, but has not been widely used. Buprenor-
phine, also a synthetic narcotic, is awaiting approval from the U.S. Food and Drug
Administration for use as an anti-addiction drug. It causes weaker narcotic effects.
No serious side effects are reported for any of the above three synthetic narcotics
except for occasional constipation, nausea and dry mouth for some patients. Also,
high dosages for all three were found to be much more effective in controlling the
heroin addiction than low dosages.
Naltrexone is used to reduce alcohol cravings and to cause drinking to be
less pleasurable (by inducing an unpleasant side-effect such as nausea when etha-
nol consumption occurs). Naltrexone is a narcotic antagonist, which was originally
used for narcotic dependency. Ethanol supposedly stimulates the body's natural
opiates, and naltrexone (or Revia) blocks this stimulation reducing cravings and
pleasure. Naltrexone is only effective for 24 hours, thus a once daily dose is
required. The pharmaco-kinetic efficacy of the drug is limited due to relatively
slow absorption, thus making an alternative dosage to the solid pill form to deliver
the drug rapidly to the bloodstream would have advantages.
Methadone and naltrexone will be used as examples in the following descrip-
tion of how to prepare aerogel products of this invention. The aerogel forms of
both drugs are sufficiently physicochemically stable to ensure adequate shelf life.
In general, the production of aerogels involves a sol-gel process during
which a wet gel containing the substance of interest is formed with a proper solvent
and catalyst. After the wet gel with nano-size pores and a lattice structure has been
formed, a supercritical extraction process is used to supercritically dry the gel
while avoiding potential collapse of the delicate pore and lattice structures due to
the lack of surface tension of the supercritical fluid. Most commonly the
supercritical fluid will be carbon dioxide (CO2). The resulting dried gel exhibits
nano-size pores (generally about 1 to 100 nm, preferably about 5 to 50 nm, more
preferably about 10 nm), a high surface area (generally about 100 to 1,500 m2 /g,
preferably about 100 to 1,200 m2 /g, more preferably about 500 to 1,000 m2 /g), a
low density (generally about 0.1 to 0.0001 g/cc, preferably about 0.01 to 0.001,
more preferably about 0.003 g/cc), and a small particle size (generally in the range
from submicron up to about 2 microns).
Methadone hydrochloride is a synthetic narcotic analgesic commonly used
to treat heroin addicts who would otherwise suffer narcotic withdrawal symptoms.
Treatment consists of oral dosages of the soluble hydrochloride salt, which can be
safely autoclaved for sterilization. The "free base" methadone has the chemical
structure shown below on the right. It is likely to be the therapeutic agent, but is
not water soluble. However, it is very soluble in non-polar organic solvents and
fats, and should have appreciable solubility in liquid or supercritical carbon

dioxide. The basicity of the molecule allows it to be readily protonatcd by strong
acids to form an ammonium salt. The preferred form for handling is in the form of
the ammonium salt, typically either as the hydrochloride shown on the left or as the
sulfate (not drawn).
The salts do not have appreciable solubility in non-polar organic solvents,
but rather have excellent solubility in water and alcohols (one gram of the
hydrochloride salt dissolves in 0.4 ml of water, 3.2 ml of cold water, 2 ml of hot
ethanol, or 12 ml of chloroform).
The methadone aerogel powder may be formed by co-gelling the free base
with glucose (which is preferably formed in situ from diisopropylidene glucose
precursor and sacrificial 1,2-diols via a trans-acetalization reaction) in a solvent
by the addition of a stoichiometric amount of anhydrous hydrogen chloride or
hydrochloric acid. Varying the ratio of methadone to glucose in the solvent will
allow control of the gelling behavior of the hydrochloride salts to produce desired
physical characteristics while avoiding the formation of a dense methadone hydro-
chloride crystallization. If desired, the anion can be changed and/or other acids
may be used to modify wet gel formation when reacted with the methadone/glu-
cose precursor/solvent combination. Examples of suitable acids include mineral
acids (hydrochloric, sulfuric, nitric) and organic acids (gluconic, malic, fumaric,
citric). The variables that can be used to control the gelling reaction are solvent
identity, 1,2-diol identity (e.g. 1.,2-phenylethanediol, 1,2-propanediol, glycerol),
methadone concentration, acid identity, temperature, percent water present, etc.
Supercritical drying of the gels with carbon dioxide gives aerogel powders
with the highest possible surface area. The supercritical drying process may be
performed in any Well known conventional manner. Thus further details of the
supercritical drying process are not provided herein. The supercritical drying is
performed at a temperature below about 40°C.
Naltrexone aerogel powder in accordance with the present invention may be
produced in the following manner. Generally, naltrexone is provided in the form
of ar hydrochloride salt to improve solubility in water and hence bioavailability.
The formation of a high surface area naltrexone containing aerogel powder will be
accomplished by co-gelling the hydrochloride or other suitable salt of the free base
naltrexone with glucose in a similar manner to that described above for methadone.
The glucose gel will preferably be formed in situ from a solution of 1,2:5,6 di-O-
isopropylidene a-gluco-furanose and an excess of sacrificial 1,2-diols via acid-
- catalyzed trans-acetalization in an appropriate solvent. The resulting product will
have naltrexone suspended in a glucose/solvent gel matrix. Subsequent drying with
supercritical carbon dioxide will provide the high surface area aerogel powders.
Varying the ratio of naltrexone to glucose in a particular solvent enables control
of the gelling behavior of the hydrochloride salts to avoid dense naltrexone hydro-
chloride crystallization. The anion can be changed as well, and a variety of acids
can be investigated which may enhance wet gel formation when reacted with the
naltrexone/glucose precursor/solvent combination. Mineral acids (hydrochloric,
sulfuric, nitric) and a modest sampling of organic acids (gluconic, malic, fumaric,
citric) may be used. System variables that can be used to control gelling behavior
include solvent identity, 1,2-diol identity (e.g. 1,2-phenylethanediol, 1,2-propane-
diol, glycerol), naltrexone concentration, acid identity, temperature, percentage of
water present and rheological control additives. Supercritical drying of the gels
with carbon dioxide will give aerogel powders with the desirable properties
specified above.
The free base is highly soluble in supercritical carbon dioxide but not that
soluble in water. In case, a slower and longer duration release of the drug is de-
sired, then the aerogels can be prepared using free base naltrexone. In such a case,
aerogelized free base naltrexone can be prepared by adsorbing it onto a preformed
appropriate aerogel, e.g. glucose, while in the supercritical CO2 or other drying
gas. This will be followed by depressurizing the system strategically to reduce the
solute solubility and deposit the solute naltrexone on the pores of the gels. Upon
contact with pulmonary surfactant present on a patient's lung tissue, the glucose
aerogel powder doped with the naltrexone free base will dissolve rapidly, leaving
behind tiny packets of free base naltrexone directly on the lungs. The packets of
these insoluble agents are so small that they simply diffuse across the membrane
into the blood stream at a desired slow speed. Moreover, even after getting into the
blood stream, the naltrexone should metabolize much more slowly than convention-
al naltrexone hydrochloride. This produces a dosage vehicle having a long dura-
tion bioavailability inside the human body after just a brief inhaling.
Alternatively, in a second embodiment shown in more detail in the Examples
below, a therapeutic aerogel powder may be prepared by-first forming porous gels
from a carrier material which is soluble in pulmonary surfactant, e.g. a sugar or a
carbohydrate. The reaction is usually carried out in a solvent. If the solvent will
also dissolve the therapeutic agent, then a solution of the therapeutic agent is
allowed to penetrate into the pores of the wet gel by soaking until the desired depo-
sition has occurred. If the reaction solvent will not dissolve the therapeutic agent,
then the solvent in the resulting gels is first removed by repeatedly exchanging the
wet gels with the therapeutic agent solvent (or a close homologue thereof),
generally at a temperature between about ambient and 50°C for a period of about
3-10 hours, and then the therapeutic agent solution is allowed to penetrate the
pores. Then the aerogels are formed by supercritical drying at low temperature.
Further alternatively, in a third embodiment when the therapeutic agent is
soluble in the reaction solvent, a solution thereof may be added prior to the initial
gel formation to avoid the solvent exchange step. Such a process will likely pro-
vide less control of uniformity of therapeutic agent deposition and is less preferred.
Since the small particle size and high open porosity are critical for fast and
even solubility in pulmonary surfactant and absorption at the mucous membrane,
the initial aerogel bodies produced by any of the embodiments are comminuted in
any suitable manner. Small particle diameters can be obtained while maintaining
the porous structure by utilizing conventional methods such as impact milling, ball
milling, and jet milling. Jet milling in a spiral jet mill has been found capable of
producing particles as small as 0.5 micron without lattice destruction, or a substan-
tial decrease in open porosity or increase in density. Below a certain size, further
reduction may not be warranted since the suspension and dissolving properties of
the aerogel particles arc so excellent.
The air suspension characteristics of the micron and submicron size aerogel
particles are determined using a small chamber with a paddle fan based upon the
principle of the lower the minimum air speed necessary to keep the particles afloat
substantially indefinitely, the greater the loft and travel of the particles within the
air passages of a patient to the lungs. The mechanism of particles floating in the
air can be explained as follows: the lift provided by the fluid drag force, that is
proportional to the velocity squared, is balancing and overcoming the gravitational
pull downward due to density difference between the fluid and the floating parti-
cles. The lower the density difference between the floating particle and the fluid,
the higher the chances the particle will stay afloat at a given level of fluid motion
and the particle dimension. Since the aerogel particles are so porous, up to 95%
filled with the same fluid and therefore much lighter than a solid particle, they have
much better chances of remaining afloat reaching the innermost part of the lungs
and settling on the pulmonary surfactant rather than on the mucous mem-branes
along the way. Since human lungs have an equivalent surface area of a tennis
court, it is advisable to take advantage of as much of the surface of the lungs as
possible for efficient drug delivery. In actual animal tests, as an animal breathes
in air and the air reaches the alveolar, the air velocity begins to slow down and
eventually goes to near zero. Therefore, minimum air speed necessary to keep the
particles aloft in the particle test chamber is a good measure of how long and how
far the particles would stay entrained in the air flow as the air goes through the air
pipes and reaches alveoli of the lungs.
Additives to reduce static electric charge on the aerogel particles may be
used.
The aerogel powders dissolve very fast once exposed to pulmonary surfac-
tant and the water on the mucous membranes. This is due to the aerogel powders
having pores that are only a few nanometers in diameter. The capillary pressure is
proportional to the surface tension of the fluid and inversely proportional to the
characteristic dimension of the pores. The surface tension of water is very high and
the same for both a sold particle and aerogel particle. However, the characteristic
dimension for a solid particle is the diameter of the particle (e.g., 2.5 micrometer)
whereas the characteristic dimension for an aerogel particle is the pore diameter
(e.g., 2.5 nanometer). This means the capillary pressure to get the inside pores of
an aerogel particle wet can be 1000 times higher than the surface tension force that
tends to wet the surface of the solid particles. Combine this with the fact that once
the pores of the aerogel particle are filled with the surfactant/water li-quid, the
dimensions or thickness of the solid material which must be dissolved in-to the
liquid is only 1-2 nanometers thick, i.e. the aerogel lattice structure forming the
pores, as opposed to the one or two micrometer radius of the particle. Thus the
speed of dissolution could be 1,000 times faster for aerogel vs. solid particles.
Another way of looking at the fast dissolution of aerogel particles is based
upon the surface area the particle which is exposed to solubilizing liquid. The
surface area of a solid ball of 2.5 micrometer is 20 x 10-12 m . For aerogel particle
of the same diameter with a specific pore surface area of 1000 m2 /g and a density
of 0.1 g/cc, the interior pore surface area is 8.2 x 10-10 m2. In other words, the
surface area of an aerogel particle is approximately 42 times that of a similarly
sized regular solid particles. Since all the pores of the aerogel particle will fill
with surfactant/water, the dissolution occurs more rapidly. Therefore, the speed
of dissolution of aerogel particles is at least two or three orders of magnitude faster
than regular solid particles which means that there is a much faster absorption of
the aerogel drug into the blood stream.
Inhalation of certain substances are known to reach the blood stream in 8
seconds, far faster than delivery by an intravenous injection. Inhalation delivery
by aerogel powder with its inherently effective reach deep into alveoli and ex-
tremely quick dissolution and absorption, is an effective, non-invasive and rapid
way of administering drugs.
A lot of materials can be produced in aerogel form: including most of the in-
organic and organic substances including alkaloids, organic salts, monomers,
polymers, proteins and carbohydrates. This covers a vast variety of medications,
both man-made and extracted from natural products. Thus, the method of aerogel
powder inhalation can be utilized as a more effective and non-invasive alternative
drug delivery method for treatment of wide variety of diseases and symptoms.
Further examples of aerogel inhalable particles include an inhalable form of
insulin and other daily medications that are generally injected with hypodermic
needles, such as various vaccines now given by hypodermic or transdermal
injections, high blood pressure medications and other pills now taken orally, such
as Viagra that may cause undesirable stomach reactions or are slow to take effect,
asthma treating inhalant and cold medicine that would penetrate deeper into the
innermost alveoli of the lungs, and other cases where medication is desired to be
introduced into the blood stream fast and without invasive or pain-ful measures.
In general, the aerogel powder inhalation will be a viable alternative to needle
injection, transdermal injections using high speed particle impingement, electric
potential, etc., and implantations of slow release capsules.
This drug delivery method produces inhalable forms of common therapeutic
drugs such as insulin, aspirin, Viagra®, asthma medications, cold medications,
antibiotics, and the like, as long as an aerogelized form of the drug can be produc-
ed. Bypassing digestive systems, the medication will take effect much faster and
more effectively than is possible today either taken orally, by inhalation or intra-
venous injection with less trauma and side effects.
A convenient way of using the aerogel powder as inhalants is by means of
a portable inhalation device similar to conventional asthma medication devices into
which the proper amount of an aerogel powder form of a pharmaceutical will be
placed and then shaken or electrostatically dispersed evenly before inhalation.
Another convenient way of using the proposed drug delivery method for
treatment of addicts will be placing the subject in a room into which the right
concentration of aerogel dust of the selected substance is injected for a required
period to reach the target dosage. The size, porosity, and surface area of the
particles determine the rate of dissolution of the particles on the surface of the
lungs and the rate of diffusion into the blood stream. Once the particle properties
are fixed, the rate of the drug delivery can be determined by the concentration of
particles in the inhaled air. Other things being equal, the rate of drug delivery will
depend on the particulate concentration in the air. The total dosage will depend on
the concentration and the exposure duration. The dosage chamber can be designed
in such a way that once the desired dosage is reached, before opening the chamber,
the particles in the air may be removed by filtering through an aerogel blanket
filter. The substances collected by the filter can be recycled.
In those cases where the pharmaceutical aerogel product has to be diluted by
means other than airborne dust concentration and/or exposure duration for medical
reasons such as toxicity of highly pure substances, a carrier aerogel matrix can be
doped with an appropriate level of the pharmaceutical aerogel product. Any such
carrier material will have to be completely innocuous and harmless to humans and
dissolvable in water also.
Further details and explanation of the present invention may be found in the
following specific examples, which describe the manufacture of aerogel products
in accordance with the present invention and test results generated therefrom. All
parts and percents are by weight unless otherwise specified.
Example 1
An insulin containing low density aerogel is prepared by first forming an
aerogel carrier powder by the transacetalation of a soluble derivatized mannitol
compound in a solvent that does not dissolve deprotected mannitol. Deprotection
initiates the forma-tion of the gel. These reactions are carried out by combining
a diisopropylidene (1,2,5,6-diisopropylidenemannitol) or dibenzylidene (1,3,4,6-
dibenzylidenemannitol) derivative of mannitol with an excess amount of a soluble
1,2-diol compound (i.e. (±)-1 phenyl-7,2-ethanediol (PED)), p-toluenesulfonic acid
catalyst (0.5-2%), and a non-polar aprotic solvent (toluene or dichloromethane).
The solvent in the resulting gels is re-moved by repeatedly exchanging the wet gels
with ethanol at a temperature between ambient and 50°C for a period of 4-6 hours.
Insulin is penetrated into the pores of the wet gel by soaking the gel with an
alcoholic solution of insulin at 37°C until the desired deposition of insulin is
reached.
The alcohol exchanged wet gels are then dried by CO2 extraction at a
pressure and temperature above the critical point (about 35°C and 1250 psi) until
all of the alcohol has been removed. The resulting aerogels have a density of 0.02-
0.05 g/cm3 depending on the relative amounts of starting sugar derivative and
solvents utilized.
The dried aerogels are then milled to a uniform particle size of 1 to 3
microns, by fluid energy milling in a 100 AS Alpine Spiral Jet Mill. Filtered high
purity N2 gas (from liquid nitrogen boil-off) is used to drive the milling process and
to cool the product and mill surfaces. The cooling is important to minimize
destruction of the insulin structure. This milling process is carried out in an inert
atmosphere to minimize exposure to potentially active insulin powders.
The pulmonary drug delivery ability of these powders is tested by means of
a standardized airway replica system of the nasal, oral, pharyngeal, laryngeal,
tracheal, and bronchial regions of the human airways. Repeated deposition and
distribution studies under exacting and consistent flow and volume conditions
without subject variability are done. Gamma scintilography analyses are used to
measure total, regional, and local deposition in the replicas. This allows for the
precise standardized comparison of formulations and the influences of particle size
and inhalation pattern in individuals of different sizes and ages.
The concentration and biological integrity of the insulin is determined by
enzyme linked immunosorbant assay, (ELISA), and sodium dodecyl sulfate-
polyacrylimide gel electrophoresis, (SDS-PAGE). The ELISA determines the
concentration of insulin that has maintained in its active tertiary structure. The
SDS-PAGE shows that no breakdown of the insulin occurs during the processing
of the aerogel containing insulin.
To determine the biological activity of the insulin in the aerogel prepara-
* tions, a competitive binding assay is used to quantify the binding and activation of
the insulin receptor. Insulin receptor transfected NIH 3T3.fibroblasts are incubated
in the presence of the reconstituted powders with varying concentrations of an anti-
insulin receptor antibody, which blocks the binding insulin to its receptor. The rate
of autophosphorylation of the insulin receptor is measured qualitatively and
quantitatively by auto-radiography of SDS-PAGE gels, and scintilla-tion counting
of the incorporated 32P in each samples.
Speed of dissolution for the insulin containing aerogel powder is measured
against that of a regular insulin powder, by having the powder land on simulated
mucous membrane and observing the dissolution process under a microscope and
also by measuring the pH of the solution immediately behind the membrane. Rate
of dissolution in situ is determined by using a hydrogel coated pH electrode that is
exposed to insulin aerogel powders. The pH change or glucose/lactose level change
in case the glucose/lactose gel is used as a carrier gel as a function of time to give
diffusion of insulin to electrode surface. Rate of powder dissolution to form
solvated insulin is proportional to the pH change at the electrode surface. The
larger, slower to dissolve compounds have a slower pH change.
The aerogel-insulin powder more rapidly dissolves in a more uniform manner
than conventional insulin.
Example 2
The procedure of Example 1 is repeated except the low density aerogel
powder containing insulin is formed by the transacetalation of derivatized trehelose
compounds instead of the derivatized mannitol compounds. Substantially similar
results are obtained.
Example 3
The procedure of Example 1 is repeated except the low density aerogel
powder is made to further contain morphine.
The concentration and biological activity of the morphine in the aerogel
preparations is determined by a competitive binding assay that quantifies the
binding and activation of the opioid receptor. Cultured neural cells expressing the
opioid receptor are incubated in the presence of the reconstituted powders with
varying concentrations of an anti-morphine receptor antibody, which blocks the
binding morphine to its receptor. The rate of autophosphorylation of the opioid
receptor is measured qualitatively and quantitatively by autoradiography of SDS-
PAGE gels, and scintillation counting of the incorporated 32P in each sample.
Example 4
The procedure of Example 3 is repeated except but the low density aerogel
powder containing insulin is formed by the transacetalation of derivatized trehelose
compounds instead of the derivitized mannitol compounds. Substantially similar
results occur.
Example 5
The procedure of Example 1 is repeated, except the low density aerogel
powder is made to contain Viagra™. Viagra™, chemical name 5-[2-ethoxy-5-(4-
methyl-piperazin-1-ylsulfonyl)phenyl]-1-methyl-3-propyl-1 ,6-dihydro-7H-
pyrazolo[4,3-d]pyrimidin-7-one, formula C22H30N6O4S, is a potent selective
inhibitor of the enzyme phosphodiesterase-5 (PDE-5), which destroys cyclic
guanosine monophosphate (cGMP), allowing cyclic GMP to persist, itself a dilator
of blood vessels.
In order to determine the biological activity of the Viagra™ in the aerogel
powder preparations, a competitive enzyme assay is used to quantify the inactiva-
tion of the phosphodiesterase-5 enzyme. Cytosol homogenatcs from cells incubated
in the presence of 32P-ATP are incubated in the presence of varying concentrations
f the reconstituted powders. The rate of cyclic GMP elimination is measured
uantitatively scintillation counting of the incorporated P in each sample.
Example 6
The procedure of Example 5 is repeated except that the low density aerogel
powder containing Viagra is formed by the transacylation of derivitized trehalose
compounds instead of the derivitized mannitol compounds. Substantially similar
results occur.
WE CLAIM:
1. A dispersible dry powder for pulmonary delivery comprising a
therapeutically effective amount of a therapeutic agent in combination
with an aerogel particle such as herein described which can react the
alveoli of subject's lung and is soluble in human pulmonary surfactant.
2. The powder as claimed in claim 1, wherein the aerogel particle is
prepared by supercritical drying at a temperature of less than 40°C.
3. The powder as claimed in claim 1, wherein the aerogel particle
contains pores of 1 to 100 nm.
4. The powder as claimed in claim 1, wherein the aerogel particle has a
surface area of 100 to 1,200 m2/g.
5. The powder as claimed in claim 1, wherein the aerogel particle has a
density of 0.01 to 0.001 g/cc.
6. The powder as claimed in claim 1, wherein the aerogel particle has
particle size of submicron up to 3 microns.
7. The powder as claimed in claim 1, wherein the aerogel particle is a
carrier selected from the group consisting of sugars and carbohydrates.
8. The powder as claimed in claim 1, wherein by co-gelling the
therapeutic agent with a gel-forming material selected from the group
consisting of sugars and carbohydrates.
9. A process of manufacturing a powder as defined in claim 1 (i)
preparing porous gels of a carrier material which is soluble in pulmonary
surfactant, (ii) soaking the porous gels in a solution of the therapeutic
agent; (iii) removing the solvent and forming aerogels by supercritical
drying; and (iv) optionally comminuting the aerogels.
10. The powder as claimed in claim 1, wherein the therapeutic agent is
insulin, methadone, or naltrexone.

A dispersible dry powder for pulmonary delivery comprising a therapeutically
effective amount of a therapeutic agent in combination with an aerogel particle
such as herein described which can react the alveoli of subject's lung and is
soluble in human pulmonary surfactant.

Documents:

647-KOLNP-2003-(11-07-2012)-FORM-27.pdf

647-KOLNP-2003-(23-11-2011)-FORM-27.pdf

647-KOLNP-2003-ABSTRACT-1.1.pdf

647-kolnp-2003-abstract.pdf

647-KOLNP-2003-AMANDED CLAIMS.pdf

647-kolnp-2003-claims.pdf

647-KOLNP-2003-CORRESPONDENCE-1.1.pdf

647-kolnp-2003-correspondence.pdf

647-kolnp-2003-description (complete).pdf

647-kolnp-2003-examination report-1.1.pdf

647-kolnp-2003-examination report.pdf

647-kolnp-2003-form 1.pdf

647-KOLNP-2003-FORM 13.pdf

647-kolnp-2003-form 18-1.1.pdf

647-kolnp-2003-form 18.pdf

647-kolnp-2003-form 2.pdf

647-kolnp-2003-form 26-1.1.pdf

647-kolnp-2003-form 26.pdf

647-kolnp-2003-form 3-1.1.pdf

647-kolnp-2003-form 3.pdf

647-kolnp-2003-form 5-1.1.pdf

647-kolnp-2003-form 5.pdf

647-kolnp-2003-granted-abstract.pdf

647-kolnp-2003-granted-claims.pdf

647-kolnp-2003-granted-description (complete).pdf

647-kolnp-2003-granted-form 1.pdf

647-kolnp-2003-granted-form 2.pdf

647-kolnp-2003-granted-specification.pdf

647-kolnp-2003-others.pdf

647-kolnp-2003-reply to examination report-1.1.pdf

647-kolnp-2003-reply to examination report.pdf

647-kolnp-2003-specification.pdf

647-kolnp-2003-translated copy of priority document.pdf


Patent Number 246761
Indian Patent Application Number 647/KOLNP/2003
PG Journal Number 11/2011
Publication Date 18-Mar-2011
Grant Date 15-Mar-2011
Date of Filing 20-May-2003
Name of Patentee ASPEN AEROGELS, INC.
Applicant Address 184 CEDAR HILL STREET, MARLBOROUGH, MA
Inventors:
# Inventor's Name Inventor's Address
1 GOULD GEORGE 174 MILLVILLE STREET, MENDON, MA 01756
2 LEE KANG 100 PURITAN LANE, SUDBURY, MA 01776
PCT International Classification Number A61K 9/16
PCT International Application Number PCT/US2001/49541
PCT International Filing date 2001-12-21
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 60/257,436 2000-12-22 U.S.A.