Title of Invention

CELLULOSE POWDER AND A PROCESS FOR PRODUCING THE SAME.

Abstract Cellulose powder, having an average polymerization degree of 150 - 450, and average L/D (the ratio of the major axis to the minor axis) value of particles of 75 mm or less of 2.0 - 4.5, an average particle size of 20 - 250 mm, an apparent specific volume of 4.0 - 7.0 cmVg, an apparent tapping specific volume of 2.4 - 4.5 cm3/g, and an angle of repose of 55° or less, wherein the average polymerization degree is higher than a polymerization degree measured by a viscosity method after hydrolysis carried out under the following conditions: 2.5N hydrochloric acid, boiling temperature, and 15 minutes, by 5 to 300.
Full Text DESCRIPTION
CELLULOSE POWDER
TECHNICAL FIELD
The present invention relates to cellulose
powder suitable as an excipient for compression, molding
in medicir.al, food and industrial applications. More
particularly, the present invention relates to
cellulose suitable as an excipient for compression
molding that has excellent fluidity and disintegrating
properties while retaining good compression mold-
ability, when, used in medicinal applications; and to an
excipient comprising the cellulose.
BACKGROUND ART
Tablettir.g of a drug has advantages such as
high productivity and easy handling of the resulting
tablets during their transportation or upon their use.
Therefore, an excipient for compression melding needs
to have sufficient molaability to inapart such hardness
that the tablets are not worn away or destroyed during
their transportation or upon their use. Tablets used
as medicine are required to be uniform in drug centert
per tablet in order tc accurately exhibit their
efficacy. Therefore, when mixed powder of a drug and
an excipient for compression molding is compressed into
the tablets, a uniform amount of the powder should be

packed into the die of a tabletting machine. Accord-
ingly, the excipient for compression molding needs to
have not only moldability but also sufficient fluidity.
Moreover, the tablets as medicine should have not only
the properties described above but also a short
disintegration time to rapidly exhibit their efficacy
after taking. With an increase of the rate of disinte-
gration, the medicine is dissolved more rapidly in
digestive fluid, so that the transfer of the medicine
into blood is more rapid, resulting in easy absorption
of the medicine. Therefore, the excipient for compres-
sion molding should have rapid disintegrating property
in addition to moldability and fluidity.
Many active ingredient materials cannot be
molded by compression and hence are tabletted by blend-
ing with an excipient for compression molding. In
general, the larger the amount of the excipient for
compression molding blended into the tablets, the
higher the hardness of the resulting tablets. The
higher the compression stress, the higher the strength
of the resulting tablets. Crystalline cellulose is
often used as an excipient for compression molding from
the viewpoint of safety and the above-mentioned
properties.
When an active ingredient and the like which,
are poor in moldability are tabletted in the field of
medicine, an excessive compression stress is
unavoidably applied attain a practical tablet hardness.

The excessive compression stress on a tabletting
machine accelerates the abrasion of dies and punches,
and the disintegration time of the resulting tablets is
increased. For example, where an amount of an active
ingredient, such as a drug, to be blended is large
(i.e. where the starting powder has a large specific
volume) such as a Chinese orthodox medicine, is
blended, or where tablets are miniturized so that the
tablets are taken more easily, the problems, such as
abrasion or destruction of the tablets during their
transportation, are caused since the amount of an
excipient blended is so remarkably limited, that
desirable tablet hardness cannot be attained. More-
over, there is, for example, the problem that when the
active ingredient to be used is that sensitive to
striking pressure, such as an enzyme, antibiotic or the
like, the active ingredient is inactivated by heat
generation by striking pressure or striking pressure
per se, it cannot be formulated into tablets because
its content is decreased in an attempt to attain a
practical hardness. In order to solve such problems,
an excipient for compression molding is desired which
has sufficient fluidity and disintegrating property and
has a moldability higher than before, which can impart
a sufficient tablet hardness even when added in a small
amount, or impart a sufficient tablet hardness even at
a low striking pressure.
For cellulose powder used as an excipient for

medicine, compression moldability, disintegrating
property and fluidity are desired to be satisfactorily
high at the same time. However, since compression
moldability and the other properties, i.e.,
disintegrating property and fluidity are contrary to
each other, no previous cellulose powder that has a
high moldability has exhibited excellent disintegrating
property and fluidity.
Cellulose powder, crystalline cellulose and
powdered cellulose have been known and used in
medicinal, food and industrial applications.
JP-B-40-26274 discloses crystalline cellulose
having an average polymerization degree of 15 to 375,
an apparent specific volume of 1.84 to 8.92 cmVg and a
particle size of 300 nm or less. JP-B-56-2047
discloses crystalline cellulose having an average
polymerization degree of 60 to 375, an apparent
specific volume of 1.6 to 3.1 cmVg, a specific volume
of 1.40 cmVg or more, a content of powder of 200-mesh
size or more of 2 - 80 wt% and an angle of repose of 35
- 42°. DE2921496 discloses that cellulose powder
having an average polymerization degree of 150 is
produced by carrying out acid hydrolysis of a cellulose
material in the form of flowable, non-fibrous and
water-insoluble cellulose powder to adjust the solid
content to 30 - 40 wt%, followed by drying on trays at
140 - 150°C. RU2050362 discloses a process in which in
order to produce a stable gel of powdered cellulose,

powdered cellulose having an average polymerization
degree of 400 or less is obtained by impregnating a
starting material containing cellulose with a mineral
acid or an acid salt solution, and then hydrolyzing the
starting material at a high temperature while stirring
a starting material layer at a shear rate of 10 -
1,000 s"1 for 1-10 minutes. The crystalline
celluloses and powdered celluloses concretely disclosed
in these references, however, are disadvantageous in
that the average L/D value of particles of 75 |im or
less after drying, the apparent specific volume and the
apparent tapping specific volume are so small that the
compression moldability is low.
JP-A-63-267731 discloses cellulose powder
having a certain average particle size (30 (xm or less)
and a specific surface area of 1.3 m2/g or more. This
cellulose powder involves the following problems
because it is produced through a grinding step: its
moldability is insufficient because the average L/D
value of particles of 75 fim or less is small; its
fluidity is low because its particles are small and
light; and its disintegrating property is very low
because its apparent tapping specific volume is too
low.
JP-A-1-272643 discloses cellulose powder
having a specified crystal form (cellulose I type), a
porosity for pores with a diameter of 0.1 pm or more of
20% or more, and a content of powder of 350-mesh size
or more of 90% or more. JP-A-2-84401 discloses
cellulose powder having a crystal form of type I, a
specific surface area of 20 m2/g or more, a total volume
of pores with a diameter of 0.01 mm or more of 0.3 cm3/g
or more, and an average particle size of at most 100
mm. Although they have a relatively high moldability,
these cellulose powders, however, are different from
the cellulose powder of the present invention as the
L/D value of dried powder is less than 2.0. In
addition, the cellulose powders are not desirable
because the nitrogen specific surface area of their
particles is too large, so that their conduits are
decreased during compression, resulting in low
disintegrating property. Moreover, the cellulose
powders disclosed in the above references are obtained
by hydrolysis followed by spray drying using an organic
solvent as a medium for a slurry before drying. These
powders have not been put to practical use because the
use of the organic solvent requires, for example, a
dryer having an explosion-proof structure and a system
for recovering the organic solvent and hence entails
high cost.
JP-A-6-316535 discloses crystalline cellulose
obtained by acid hydrolysis or alkali oxidative
decomposition of a cellulosic material, which has an
average polymerization degree of 100 - 375, an acetic
acid retention of 280% or more, compression character-
istics represented by Kawakita's equation wherein the

constants a and b are 0.85 - 0.90 and 0.05 - 0.10,
respectively, an apparent specific volume of 4.0 - 6.0
cmVg, a specific volume of 2.4 cm3/g or more, a
specific surface area of less than 20 m2/g, substantially
no particles of 355 mm. or more, and an average
particle size of 30 - 120 mm. The crystalline
cellulose powder disclosed in the above reference is
described as having an excellent balance between
moldability and disintegrating property. The angle of
repose of the concretely disclosed crystalline
cellulose powder of an example having the best balance
between moldability and disintegrating property is
measured and found to be more than 55°. The fluidity
of this crystalline cellulose powder is thus not
satisfactory. Particularly when molded under a high
striking pressure, the crystalline cellulose disclosed
in the above reference can be given a high hardness but
has the following problems: the water vapor specific
surface area of particles after drying is so small that
the conduits in the resulting tablets is decreased to
retard the disintegration of the tablets; and in the
case of, for example, a recipe in which the proportion
of an active ingredient having a low fluidity is high,
the coefficient of variation of the weight of the
resulting tablets is increased because of the low
fluidity to affect the uniformity of the content of a
drug.
In addition, JP-A-11-152233 discloses
crystalline cellulose having an average polymerization
degree of 100 - 375, a content of particles capable of
passing through a 75-mm screen and remaining on a 38-mm
screen of 70% or more based on the total weight of the
crystalline cellulose, and an average L/D (the ratio of
the major axis to the minor axis) value of particles of
2.0 or more. This reference, however, does not
describe the angle of repose of the crystalline
cellulose disclosed therein. The crystalline cellulose
specifically disclosed which is obtained by sieving the
crystalline cellulose disclosed in JP-A-6-316535 has
problems of worse fluidity and disintegrating property
than the crystalline cellulose of JP-A-6-316535 itself.
JP-A-50-19917 discloses a process for producing an
additive for molding tablets which comprises
depolymerizing purified pulp to an average polymeriza-
tion degree of 450 - 650 by pretreatment, and subject-
ing the depolymerization product to mechanical grinding
treatment until the apparent tapping specific volume
becomes 1.67 - 2.50 cmVg and the particle size becomes
such a value that 50% or more of the particles pass
through a 200-mesh screen. The cellulose powder
disclosed in this reference is disadvantageous in that
its polymerization degree is so high it exhibits
fibrousness, the average L/D value of its particles of
75 mm or less and its apparent specific volume are too
large, so that it is poor in disintegrating property
and fluidity. The fact that the apparent tapping

specific volume of this cellulose powder is small for
its apparent specific volume is also a cause for the
deterioration of the disintegrating property of tablets
obtained by compression.
As described above, no cellulose powder
having moldability, fluidity and disintegrating
property at the same time with a good balance among
them has been known as conventional cellulose powder.
Medicine often has a form of a granular
preparation such as granules or fine granules, to which
a coating is applied to improve the stability of an
active ingredient, adjust the release rate of a drug,
mask a taste, or impart enteric properties; or a form
of a matrix type granular preparation obtained by
granulating a mixture of a coating agent and a drug
together with other ingredients. When the granular
preparation has a particle size of about 1 mm or less,
it is made into capsules in most cases from the view-
point of ease of handling, but it is preferably made
into tablets by compression molding of a mixture of the
granular preparation and an excipient, from the
viewpoint of cost and ease of taking. However, when
granules having a coating film, such as sustained
release coated granules, bitter-taste-masked granules,
enteric coated granules or the like are tabletted by
compression, there is the following problem: the
coating film is damaged by compression stress and hence
the rate of dissolution and release is increased in

mouth, stomach and intestines, so that the exhibition
of an expected drug efficacy is not achieved. In order
to solve this problem, the following methods have been
disclosed. JP-A-53-142520 discloses a method wherein
crystalline cellulose is used. JP-A-61-221115
discloses a method wherein crystalline cellulose is
used in a proportion of approximately 10 - 50% based on
the amount of tablets. JP-A-3-36089 discloses a method
wherein crystalline cellulose having an average
particle size of 30 (jia or less and a specific surface
area of 1.3 m2/g or more is used. JP-A-5-32542 _
discloses a method wherein crystalline cellulose having
a specific surface area of 20 nr/g or more and a porous
structure in which the total volume of pores having a
diameter of 0.01 mm or more is 0.3 cmVg or more. JP-A-
8-10465H—discloses a method wherein a microcrystalline
cellulose having an average polymerization degree of
150 - 220, an apparent specific volume of 4.0 - 6.0
cmVg, an apparent tapping specific volume of 2.4 cmVg
or more, a specific surface area of less than 20 m2/g,
an acetic acid retention of 280% or more, a content of
particles of 355 mm or more of less than 5 wt%, a
particle size distribution with an average particle
size of 30 - 120 mm compression characteristics
represented by Kawakita's equation wherein the
constants a and b are 0.85 - 0.90 and 0.05 - 0.10,
respectively, and such compression molding character-
istics that a cylindrical molded product with a base

area of 1 cm2 obtained by compressing 500 mg of the
crystalline cellulose at 10 MPa for 10 seconds has a
fracture strength in the direction of diameter of 10 kg
or more (100 N or more in terms of a fracture strength
in SI system of units) and a disintegration time of 100
seconds or less, is used.
The methods disclosed in JP-A-53-142520 and
JP-A-61-221115, however, are disadvantageous in that
because of the low compression moldability of the
microcrystalline cellulose, high compression stress is
unavoidably applied in order to attain a practical
hardness, so that the damage to the coating film cannot
be sufficiently prevented. The method disclosed in JP-
A-3-36089 is disadvantageous in that the microcrystal-
line cellulose has a low fluidity and hence is apt to
be separated and segregated from granules during the
preparation of tablets. The microcrystalline cellulose
disclosed in JP-A-5-32542 is disadvantageous in that it
is not practical due to high cost which attributes to
the use of an organic solvent for the preparation
thereof. In the case where high compression stress
cannot be applied, for example, the case where the
strength of granules is low, the content of crystalline
cellulose should be increased in order to reduce the
compression stress. In such a case, the crystalline
cellulose disclosed in JPz-A-8-104650 is disadvantageous
in that the use of the crystalline cellulose is
limited, as it makes the disintegration of the result-

ing tablets very difficult.
Many active ingredients for medicine are
often used after being made into fine particles, and
have such a low fluidity that they are not easily
compression-molded by a direct compression method (a
direct striking method). In particular, the larger the
amount of the active ingredient for medicine to be
added, the more difficult the compression molding. The
above JP-A-8-104650 describes that the use of the
above-mentioned microcrystalline cellulose, a fluidiz-
ing agent and a disintegrating agent for Chinese
orthodox medicine powder or crude drug powder ensures
enough fluidity to be subjected to a direct tabletting
method, and thus makes it possible to produce tablets
having an excellent balance between moldability and
disintegrating property. However, in the case where
the content of an active ingredient for medicine having
a low moldability, which is not limited to Chinese
orthodox medicine powder or crude drug powder, is
increased in a pharmaceutical composition, there is
still a problem that sufficient fluidity cannot be
attained. Moreover, if the amount of a disintegrating
agent is not sufficient, the retardation of disinte-
gration and a decrease of the rate of dissolution
occur. Since an active ingredient powder for medicine
is poor in compression moldability and cannot give a
molded product without the addition of an excipient, a
granule compression method is generally adopted in

which compression moldability, disintegrating property
and fluidity are assured by carrying out a step of
granulating the active ingredient for medicine together
with an excipient by a well-known wet or dry process,
and then the resulting granules are compression-molded.
An extra-granulation method is also often adopted as a
means for enhancing the effect of the addition of an
excipient by adding the excipient outside the granules
besides the excipient added inside the granules upon
producing the granules. JP-B-5-38732 discloses a
crystalline cellulose having an average particle size
of 30 |am or less and a specific surface area of 1.3 m2/g
or more. JP-A-8-104650 discloses a process for
tabletting, using specific crystalline cellulose, by
the granule compression method. These crystalline
celluloses, however, are disadvantageous in that when
compression stress is increased, the disintegration is
retarded and the rate of dissolution is decreased.
DISCLOSURE OF THE INVENTION
The present invention is intended to provide
cellulose powder having various properties, i.e.,
moldability, fluidity and disintegrating property, at
the same time with a good balance among them. Further-
more, the present invention is intended to provide the
following tablets by incorporating said cellulose
powder into the tablets: tablets having high hardness
without the retardation of their disintegration,

especially when molded under a high striking pressure;
granule-containing tablets having less destruction of
granules, and less damages to the coating films of the
granules and having only a slight change in drug-
releasing property when compression molded; and tablets
which are uniform in their weight even when their drug
content is high, and which have a good balance between
hardness and disintegrating property.
In view of the situation described above, the
present inventors earnestly investigated and conse-
quently succeeded in controlling the physical
properties of cellulose powder to be within specific
ranges and found cellulose powder having an excellent
balance among various properties, i.e., moldability,
fluidity and disintegrating property, whereby the
present invention has been accomplished. The present
invention is as follows:
(1) cellulose powder having an average
polymerization degree of 150 - 450, an average L/D (the
ratio of the major axis to the minor axis) value of
particles of 75 mm or less of 2.0 - 4.5, an average
particle size of 20 - 250 mm, an apparent specific
volume of 4.0 - 7.0 cmVg, an apparent tapping specific
volume of 2.4 - 4.5 cmVg, and an angle of repose of 55°
or less;
(2) the cellulose powder according to item
(1), wherein the average polymerization degree is 230 -
450;

(3) the cellulose powder according to item
(1) or (2), wherein the average polymerization degree
is not a level-off polymerization degree;
(4) the cellulose powder according to any
one of items (1) to (3), wherein the angle of repose is
54° or less;
(5) the cellulose powder according to any
one of items (1) to (4), wherein the cellulose powder
has a specific surface area of 85 m2/g or more as
measured by water vapor adsorption;
(6) the cellulose powder according to any
one of items (1) to (5), wherein a breaking load of
tablets obtained by compressing 0.5 g of the cellulose
powder at 20 MPa is 170 N or more and the disintegra-
tion time of the tablets is 130 seconds or less;
(7) the cellulose powder according to any
one of items (1) to (6), wherein the breaking load of
tablets obtained by-compressing 0.5 g of a mixture of
equal amounts of the cellulose powder and lactose at 80
MPa is 150 N or more and the disintegration time of the
tablets is 120 seconds or less;
(8) a process for producing cellulose
powder, comprising:
i) obtaining a cellulose dispersion
containing cellulose particles, wherein
a) an average polymerization degree is 150 -
450, and
b) the average L/D value in wet state is 3.0

by controlling a solution-stirring force in hydrolyzing
a natural cellulosic material or in a subsequent step,
and
ii) spray-drying the thus obtained cellulose
dispersion at an article temperature lower than 100°C;
(9) the process for producing cellulose
powder according to item (8), wherein the average
polymerization degree is 230 - 450;
(10) the process for producing cellulose
powder according to item (8) or (9), wherein the
average polymerization degree is not a level-off
polymerization degree;
(11) the process for producing cellulose
powder according to any one of items (8) to (10),
wherein the drying step is a step of spray drying at an
article temperature lower than 100°C;
(12) cellulose powder obtained by a produc-
tion process according to any one of items (8) to (11);
(13) an excipient comprising cellulose
powder according to any one of items (1) to (7) and
item (12);
(14) a molded product containing cellulose
powder according to any one of items (1) to (7) and the.
item (12) or an excipient according to item (13);
(15) the molded product according to the
item (14), wherein the molded product is tablets
containing one or more active ingredients;

(16) the molded product according to the
item (15), wherein the molded product contains the
active ingredient(s) in a proportion of 30 wt% or more;
(17) the molded product according to any one
of the items (14) to (16), wherein the molded product
contains the active ingredient(s) vulnerable to
compression;
(18) the molded product according to the
item (17), wherein the active ingredient(s) is coated;
(19) the molded product according to any one
of the items (14) to (18), wherein the molded product
is rapidly disintegrable; and
(20) the molded product according to any one
of the items (14) to (19), wherein the molded product:
contains a fluidizing agent.
BEST MODE FOR CARRYING OUT THE INVENTION
The present invention is described below in
detail.
The cellulose powder according to the present
invention should have an average polymerization degree
of 150 - 450, preferably 200 - 450, more preferably 230
- 450. When the average polymerization degree is less
than 150, the moldability of the cellulose powder is
undesirably insufficient. When the average polymeriza-
tion degree is more than 450, the cellulose powder
shows remarkable fibrousness, so that its fluidity and
disintegrating property are undesirably deteriorated.

When the average polymerization degree is 230 - 450,
the cellulose powder has an especially excellent
balance among moldability, disintegrating property and
fluidity, and thus preferred- The average polymeriza-
tion degree is preferably not a level-off polymeriza-
tion degree. When hydrolysis is carried out to the
level-off polymerization degree, the L/D value of
particles is liable to be low by a stirring operation
in a production process, so that the moldability is
undesirably deteriorated. The term "level-off
polymerization degree" used herein means a polymeriza-
tion degree measured by a viscosity method (a copper
ethylenediamine method) after hydrolysis carried out
under the following conditions: 2.5N hydrochloric acid,
boiling temperature, and 15 minutes. It is known that
when a cellulosic material is hydrolyzed under mild
conditions, its region other than crystals permeable
with an acid, i.e., the so-called noncrystalline region
is selectively depolymerized, so that the cellulosic
material hydrolyzed has a definite average polymeriza-
tion degree called a level-off polymerization degree
(INDUSTRIAL AND ENGINEERING CHEMISTRY, Vol. 42, No. 3,
p. 502-507 (1950)). After the polymerization degree
reaches the level-off polymerization degree, it does
not become lower than the level-off polymerization
degree even if the hydrolysis time is prolonged.
Therefore, when the polymerization degree is not
lowered by hydrolysis of dried cellulose powder under

the following conditions: 2.5N hydrochloric acid,
boiling temperature, and 15 minutes, it can tell that
the polymerization degree has reached the level-off
polymerization degree. When the polymerization degree
is lowered by the hydrolysis, it can tell that the
polymerization degree has not yet reached the level-off
polymerization degree.
The polymerization degree should be higher
than the level-off polymerization degree by preferably
about 5 to about 300, more preferably about 10 to about
250. When the difference is less than 5, it becomes
difficult to control the L/D value of particles to be
within a specific range, so that the moldability is
undesirably deteriorated. When the difference is more
than 300, the fibrousness is increased, to give
inferior disintegrating property and the fluidity,
which is not preferred.
In the cellulose powder according to the
present invention, the content of particles capable of
remaining on a 250-|am screen is preferably 50 wt% or
less. Since particles of more than 250 (jia form a dense
structure when granulated, their presence in a propor-
tion of more than 50 wt% undesirably deteriorates the
moldability and the disintegrating property. The
content is preferably 30 wt% or less, more preferably
10 wt% or less, in particular, 5 wt% or less.
The average particle size of the cellulose
powder of the present invention should be 20 - 250 fam.

When the average particle size is less than 20 mm, the
adhesive and cohesive properties of the cellulose
powder are increased, resulting in not only difficult
handling but also a low fluidity. When the average
particle size is more than 250 mm, the cellulose powder
is separated and segregated from an active ingredient,
so that the content uniformity of the resulting
pharmaceutical composition is undesirably apt to be
decreased. The average particle size is preferably 20
- 120 |im.
In the cellulose powder of the present
invention, the average L/D value of particles of 75 mm
or less should be 2.0 - 4.5, preferably 2.2 - 4.2.
When the average L/D value of particles of 75 mm or
less is less than 2.0, the plastic deformation
properties and the moldability are deteriorated, which
is not preferred. When the average L/D value of
particles of 75 mm or less is more than 4.5, the
fluidity and the disintegrating property are deterio-
rated, which is not preferred. Moreover, the mold-
ability tends to be deteriorated probably because the
cellulose fiber attains fibrousness and tends to have
elastic recovery.
Average yield pressure is employed as an
indication of the plastic deformation properties of
powder. The lower the value of the average yield
pressure, the higher the plastic deformation properties
and compression moldability of the powder. The highly

moldable excipient of the present invention preferably
has an average yield pressure of 35 MPa or less when
0.5 g of this powder is compressed to 10 MPa. When the
average yield pressure is more than 35 MPa, the
moldability is deteriorated, which is not preferred.
The average yield pressure is preferably, in
particular, 30 MPa or less.
The cellulose powder of the present invention
should have an apparent specific volume of 4.0 - 7.0
cmVg. When the apparent specific volume is less than
4.0 cmVg, the moldability is deteriorated. When the
apparent specific volume is more than 7.0 cmVg, the
disintegrating property and the fluidity are deterio-
rated, which is not preferred. Moreover, the mold-
ability tends to be deteriorated probably because the
cellulose fiber attains fibrousness and tends to have
elastic recovery. The apparent specific volume is
preferably 4.0 - 6.5 cmVg, in particular, 4.2 - 6.0
cmVg.
The apparent tapping specific volume of the
cellulose powder of the present invention should be 2.4
- 4.5 cmVg, preferably 2.4 - 4.0 cmVg, in particular,
2.4 - 3.5 cmVg. Even when the apparent specific volume
is in a range of 4.0 - 7.0 cmVg, if the apparent
tapping specific volume is less than 2.4 cmVg, the
disintegrating property of tablets prepared from the
cellulose powder are undesirably deteriorated because
of excessive consolidation.

The cellulose powder of the present invention
should have an angle of repose of 55° or less. When
the angle of repose of the cellulose powder is more
than 55°, its fluidity is remarkably deteriorated.
Particularly when tablets are produced by blending a
large amount of an active ingredient with poor
fluidity, the weight variation of the tablets becomes
remarkable if the fluidity of the excipient for
compression molding is low, so that the tablets cannot
be put to practical use. The angle of repose of the
cellulose powder of the present invention is preferably
54° or less, more preferably 53° or less, in
particular, 52° or less. The term "angle of repose"
used herein means an angle of repose measured by a
powder tester (mfd. by Hosokawa Micron Corporation)
after adjusting the water content of the powder to 3.5
to 4.5%. To impart such high fluidity, the cellulose
powder preferably has compressibility [%] (= 100 x
(apparent tapping density [g/cm3] - apparent density
[g/cm3] ) / apparent tapping density [g/cm3]) in a
specific range. The compressibility is preferably in a
range of approximately 30 - 50%, more preferably 30 -
49%, in particular, 30 ~ 47%.
The terms "apparent tapping density" and
"apparent density" used herein mean the reciprocal
numbers of the apparent tapping specific volume and
apparent specific volume, respectively, defined herein.
The cellulose powder of the present invention

preferably has a specific surface area of 85 m7g or
more as measured by water vapor adsorption. When the
specific surface area is less than 85 itiVg, an area for
water infiltration into particles is small and hence
the amount of conduits of the tablets prepared from the
cellulose powder is small, to lower disintegrating
property of the tablets, which is not preferred.
Although the upper limit of the specific surface area
is not particularly limited, that of the cellulose
powder before drying is about 200 mVg as a measure
because specific surface area is considered as a value
which is decreased by drying.
The cellulose powder of the present invention
preferably has a specific surface area in a range of
0.5 - 4.0 mVg as measured by a nitrogen adsorption
method. When the specific surface area is less than
0.5 mVg, the moldability is deteriorated, which is not
preferred. When the specific surface area is more than
4.0 mVg, the disintegrating property are remarkably
deteriorated, which is preferred. The specific surface
area is preferably 0.8 - 3.8 mVg, more preferably 0.8 -
3.5 mVg.
When the nitrogen specific surface area is
increased, spaces among particles (i.e. conduits) are
crushed during compression, so that the disintegrating
property tend to be deteriorated. However, even if the
nitrogen specific surface area is high, as long as the
nitrogen specific surface area is in a definite range,

the amount of the conduits can be maintained to prevent
the deterioration of the disintegrating property, by
controlling the water vapor specific surface area at a
definite value or more. A practical physical property
value indicating the moldability is the hardness of a
molded product. The higher this hardness, the higher
the compression moldability. A practical physical
property value indicating the disintegrating property
is the disintegration time of a molded product. The
shorter this disintegration time, the better the
disintegrating property. The balance between the
tablet hardness and disintegration time of a molded
product obtained by compression at a high striking
pressure is important in practice, considering that the
disintegrating property are generally deteriorated with
an increase of the hardness and that the compression at
a high striking pressure is unavoidable because many
active ingredients for medicine or the like have low
moldability.
The breaking load in the direction of
diameter of a cylindrical molded product with a
diameter of 1.13 cm obtained by compressing 0.5 g of
the cellulose powder of the present invention at 20 MPa
for 10 seconds is preferably 170 N or more, more
preferably 180 N or more, in particular, 190 N or more.
The disintegration time (a solution in pure water at
37°C, a disc is present) of the cylindrical molded
product is preferably 130 seconds or less, more prefer-

ably 120 seconds or less, in particular, 100 seconds or
less. The breaking load in the direction of diameter
of a cylindrical molded product with a diameter of 1.13
cm obtained by compressing 0.5 g of a mixture of equal
amounts of the cellulose powder of the present inven-
tion and lactose (Pharmatose 100M, available from DMV
Corp.) at 80 MPa for 10 seconds is preferably 150 N or
more, more preferably 170 N or more, in particular, 180
N or more. The disintegration time (a solution in pure
water at 37°C, a disc is present) of this cylindrical
molded product is preferably 120 seconds or less, more
preferably 110 seconds or less, in particular, 90
seconds or less.
In addition, a cylindrical molded product
with a diameter of 0.8 cm obtained by compressing 0.05
g of the cellulose powder of the present invention at
90 MPa for 10 seconds preferably has adsorption
characteristics represented by the following equation
(1), after its immersion treatment with acetonitrile
solvent:
In[9e/ (9e-6) ] = Ka-t (1)
wherein Ka > 0.0200 min"1, 9e is the saturated water
vapor adsorption rate [%] of tablets at a relative
humidity of 55% RH, and 9 is the water vapor adsorption
rate [%] of the tablets at a relative humidity of 55%
RH and a water vapor adsorption time of t [min.]).
The term "immersion treatment with aceto-
nitrile solvent" used herein means immersing the

cylindrical molded product in acetonitrile solvent fcr
48 hours to permeate the same with the acetonitrile
solvent sufficiently, and drying the cylindrical molded
product at 25°C in a nitrogen stream until the relative
humidity becomes 0% RH. In the case where the occur-
rence of moisture absorption or adsorption during
operations is conjectured, for example, the case where
the linearity of the equation (1) is low, the cellulose
surface should be cleaned by vacuum drying with heat.
When the Ka value is less than 0.0200 min"1, the adsorp-
tion rate of water is slow, so that the disintegration
time tends to be prolonged, which is not preferred.
The effect of the immersion treatment with acetonitrile
solvent is conjectured as follows. The compression of
the cellulose powder causes an increase of inter-
particle hydrogen bonds and crush of micro-spaces
(conduits) in particles. When the cylindrical molded
product compressed to have a high density is immersed
in acetonitrile, acetonitrile enters the micro-spaces
(conduits) in particles but not sites of the inter-
particle hydrogen bonds to increase the diameter of the
conduits.
That is, it can be speculated that with an
increase of the number of the inner-particle micro-
spaces (conduits) in the cellulose powder which remain
in tablets after the compression, the acetonitrile
solvent permeates the cellulose powder more easily to
increase the diameter of the conduits to give higher

water vapor adsorption rate of the tablets. It can
also be speculated that since such tablets adsorb water
rapidly, their disintegration time in water is reduced.
Although the upper limit of the Ka value is not
particularly limited, the Ka value is preferably 0.0400
min"1 or less because with an increase of the Ka value,
the disintegration time tends to be reduced. The Ka
value is preferably in a range of 0.0210 - 0.0400 min"1,
more preferably 0.0220 - 0.0400 min"1.
A process for producing cellulose powder of
the present invention needs to comprise: i) obtaining a
cellulose dispersion containing cellulose particles
wherein, a) an average polymerization degree is 150 -
450, and b) the average L/D value in wet state is 3.0 -
5.5, by controlling a solution-stirring force in
hydrolyzing a natural cellulosic material or in a
subsequent step, and ii) spray-drying the thus obtained
cellulose dispersion at an article temperature lower
than 100°C.
The natural cellulosic material referred to
herein is a vegetable fibrous material derived from a
natural material containing cellulose, such as wood,
bamboo, cotton, ramie or the like and is preferably a
material having a crystalline structure of cellulose I
type. From the viewpoint of production yield, the
natural cellulosic material is preferably pulp obtained
by purifying such natural materials and preferably has
an a-cellulose content of 85% or more.

Conditions for obtaining the cellulose
dispersion having an average polymerization degree of
150 - 450 are, for example, carrying out the hydrolysis
under mild conditions in a 0.1 - 4N aqueous hydro-
chloric acid solution at 20 - 60°C. However, when the
cellulosic material is hydrolyzed to the level-off
polymerization degree, the L/D value of particles is
liable to be decreased by stirring operation in the
production process, so that the moldability is
deteriorated, which is not preferred.
Particles in the cellulose dispersion before
drying preferably such that, have the average L/D value
of the particles capable of remaining on 75- to 38-um
screens in a range of 3.0 - 5.5, more preferably 3.2 -
5.2, when sieved (through JIS standard screens) in a
wet state. Since particles in the cellulose dispersion
are aggregated by drying, resulting in a small L/D
value, cellulose powder having a high moldability and
good disintegrating property can be obtained by keeping
the average L/D value of particles before drying in a
definite range. The average L/D value of particles
before drying can be kept in the definite range by
controlling a stirring force in the hydrolyzing
reaction or in a subsequent step at a specific
intensity.
The stirring during the reaction or in the
subsequent step shortens cellulose fiber. When the
stirring is too vigorous, the average L/D value of

particles is decreased, so that no sufficient mold-
ability can be attained. Therefore, the stirring force
should be controlled so that the average L/D value of
particles becomes 3.0 or more. When the stirring is
too mild, the fibrousness is enhanced, resulting in a
low moldability and remarkably deteriorated
disintegrating property. Therefore, the stirring force
is preferably maintained so that the average L/D value
of particles is not more than 5.5.
The intensity of the stirring force can be
controlled, for example, in consideration of P/V
(kg-m"1-sec"3) value obtained by the empirical equation
(2) described below. The P/V value, however, is not an
absolute numerical value because it is dependent on the
size and shape of a agitation vessel, the size and
shape of an agitating blade, the number of revolutions,
the number of turning blades, etc. The maximum value
of P/V in each step-before drying ranges from 0.01 to
10,000, and the lower and upper limits of P/V can be
determined by controlling the number of revolutions,
depending on the kind of the agitation vessel and the
agitating blade. It is sufficient that the lower and
upper limits is properly determined by comparing values
of P/V obtained by varying the agitation vessel used
and the number of revolutions of the agitating blade
with the average L/D value of particles of 75 urn to 38
\m, for example, as follow: P/V is adjusted so as to
fall within a range of 0.3 to 80 in the case where Np «¦

8/,V = 0.03 and d = 0.3; P/V is adjusted so as to fall
within a range of 0.01 to 5 in the case where Np = 2.2,
V = 0.07 and d = 0.05; and P/V is adjusted so as to
fall within a range of 1 to 10,000 in the case where Np
« 2.2, V - 1 and d = 1.
P/V = (Np x p x n3 x d5)/V (2)
wherein Np (-) is a power number of impeller, p (kg/m3)
is the density of a liquid, n (rps) is the number of
revolutions of the agitating blade, d (m) is the
diameter of the agitating blade, and V (m3) is the
volume of the liquid.
The cellulose dispersion obtained by the
above procedure should be made into powder by drying.
The IC (electric conductivity) value of the cellulose
dispersion before drying which has been washed and
subjected to pH adjustment after the reaction is
preferably 200 |iS/cm or less- When the IC value is
more than 200 nS/cm,' the dispersibility of particles in
water is deteriorated, resulting in unsatisfactory
disintegration. The IC value is preferably 150 nS/cm
or less, more preferably 100 |aS/cm or less. In
preparing the cellulose dispersion, besides water,
water containing a low proportion of an organic solvent
may be used so long as it does not lessen the effect of
the present invention.
For obtaining cellulose powder having a good
balance among moldability, fluidity and disintegrating
property, spray drying is preferably conducted at an

article temperature lower than 100°C. The term

"article temperature" used herein means exhaust temper-
ature, not inlet temperature, in the spray drying. In
the spray drying, aggregated particles in the cellulose
dispersion after the reaction are consolidated by heat
shrinkage stress applied from all directions to be
densified (become heavy-duty) and attain a good
fluidity. Furthermore, the aggregated particles attain
good disintegrating property because of weak hydrogen
bonds among them. The concentration of the cellulose
dispersion before the drying is preferably 25 wt% or
less, more preferably 20 wt% or less. When the
concentration of the cellulose dispersion is too high,
particles are excessively aggregated during the drying
and hence the average L/D value of the particles after
drying is decreased, so that the bulk density is
increased to give a low moldability, which is
undesirable. The lower limit of the concentration of
the cellulose dispersion is preferably 1 wt% or more.
When the lower limit is less than 1 wt%, the fluidity
is deteriorated, which is not preferred. Moreover,
such a lower limit is not desirable from the viewpoint
of productivity because it raises the cost.
As compared with the drying method according
to the present invention in which the spray drying is
conducted at an article temperature lower than 100°C,
the methods as described in JP-A-6-316535 and JP-A-11-
152233 wherein a cellulose dispersion is heated at a
temperature of 100°C or higher and then subjected to

spray drying or drum drying, or a cellulose dispersion
is dried in the form of a thin film without heating,
are not preferable because hydrogen bonds among
aggregated particles are firmly formed, so that the
disintegrating property is deteriorated in these
methods. In these methods, cellulose particles in a
slurry are easily aggregated in the state where the
particles are arranged along the direction of their
major axis even if the L/D value of particles before
drying is less than the lower limit of a specific
range. Therefore, the decrease of the L/D value of
particles by drying can be suppressed to give good
moldability. However, disintegrating property and
fluidity cannot be imparted together with the
moldability. Cellulose powder having good fluidity and
disintegrating property in addition to good moldability
can be obtained only by controlling the L/D value of
particles to be within a specific range before drying
and conducting spray drying at an article temperature
lower than 100°C. For controlling the L/D value of
particles before drying to be within a specific range,
it is preferred to carry out hydrolysis under
conditions where the average polymerization degree does
not reach a level-off polymerization degree, as
described above.
In addition, for the cellulose powder
obtained by drum drying or thin film drying, it is
essential to grind it after the drying in order to

impart desirable powder physical properties. However,
when all particles are ground, the amount of static
electricity generated by friction among the particles
becomes large probably because the surfaces of the
particles become non-dense and uneven. This generation
of a large amount of static electricity is not prefer-
able because it also causes deterioration of the
fluidity. However, the cellulose powder may be ground
after the drying as long as the effect of the present
invention is not lessened.
A method in which a slurry before drying is
dried after complete or excessive replacement of a
solvent in the slurry with an organic solvent is not
desirable because capillary force at the time of the
evaporation of the organic solvent through spaces among
particles is weak as compared with water, so that the
formation of interparticle hydrogen bonds is
suppressed. Therefore, the nitrogen specific surface
area is increased too much to deteriorate the
disintegrating property, which is not preferred. The
proportion of the organic solvent added is 50 wt% or
less, preferably 30 wt% or less, in particular, 20 wt%
or less, based on the weight of the solvent in the
slurry. Employment of a large amount of the organic
solvent is not preferred because it requires large-
scale equipments such as an explosion-proof drying
equipment and an equipment for recovering the organic
solvent and hence entails a high cost.

The loss in weight on drying of the cellulose
powder of the present invention is preferably in a
range of 8% or less. When the loss in weight on drying
is more than 8%, the moldability is deteriorated, which
is not preferred.
The excipient referred to herein is that used
as a binder, disintegrating agent, granulation
assistant, filler, fluidizing agent or the like in the
formulation of an active ingredient into a pharma-
ceutical composition by a well-known method in
medicinal, food or industrial applications. The
excipient is preferably an excipient for compression
molding having an excellent balance among compression
moldability, disintegrating property and fluidity.
The molded product referred to herein is a
molded product containing the cellulose powder of the
present invention and obtained by processing by well-
known methods properly selected from mixing, stirring,
granulation, compression into tablets, particle size
regulation, drying, etc. When used in medicines, the
molded product includes, for example, solid pharma-
ceutical compositions such as tablets, powders, fine
granules, granules, extracts, pills, capsules, troches,
cataplasmas, etc. The molded product of the present
invention includes not only molded products used in
medicines but also molded products used in foods (e.g.
confectionery, health food, texture improvers, and
dietary fiber supplements), solid foundations, bath

agents, animal drugs, diagnostic drugs, agrochemicals,
fertilizers, ceramics catalysts, etc.
It is sufficient that the molded product
referred to herein contains the cellulose powder of the
present invention. Although the content of the
cellulose powder is not particularly limited, it should
be 1 wt% or more based on the weight of the molded
product. When the content is less than 1 wt%, satis-
factory physical properties cannot be imparted to the
molded product; for example, the molded product is woirn
away or destroyed. The content is preferably 3 wt% or
more, more preferably 5 wt% or more.
Furthermore, the molded product referred to
herein may freely contain, besides the cellulose powder
of the present invention, other additives such as
active ingredients, disintegrating agents, binders,
fluidizing agents, lubricants, correctives, flavoring
materials, coloring matters, sweeteners, surfactants,
etc. if necessary.
The disintegrating agents include, for
example, celluloses such as sodium croscarmellose,
carmellose, calcium carmellose, sodium carmellose, low-
substituted hydroxypropyl cellulose, etc.; starches
such as sodium carboxymethyl starch, hydroxypropyl
starch, rice starch, wheat starch, corn starch, potato
starch, partly pregelatinized starch, etc.; and
crospovidone.
The binders include, for example, sugars such

as white sugar, glucose, lactose, fructose, etc.; sugar
alcohols such as mannitol, xylitol, maltitol,
erythritol, sorbitol, etc.; water-soluble poly-
saccharides such as gelatin, pullulan, carrageenan,
locust bean gum, agar, konjak mannan, xanthan gum,
tamarind gum, pectin, sodium alginate, gum arabic,
etc.; celluloses such as crystalline cellulose,
powdered cellulose, hydroxypropyl cellulose, hydroxy-
propylmethyl cellulose, methyl cellulose, etc.;
starches such as pregelatinized starch, starch paste,
etc.; synthetic polymers such as poly(vinyl-
pyrrolidone)s, carboxyvinyl polymers, poly(vinyl
alcohol)s, etc.; and inorganic compounds such as
calcium hydrogenphosphate, calcium carbonate, synthetic
hydrotalcite, magnesium aluminate silicate, etc.
The fluidizing agents include hydrated
silicon dioxide, light silicic anhydride, etc. The
lubricants include magnesium stearate, calcium
stearate, stearic acid, sucrose fatty acid esters,
talc, etc. The correctives include glutamic acid,
fumaric acid, succinic acid, citric acid, sodium
citrate, tartaric acid, malic acid, ascorbic acid,
sodium chloride, 1-menthol, etc.
The flavoring materials include orange,
vanilla, strawberry, yogurt, menthol, oils (e.g. fennel
oil, cinnamon oil, orange-peel oil and peppermint oil),
green tea powder, etc. The coloring matters include
food colors (e.g. food red No. 3, food yellow No. 5 and

food blue No. 1), copper chlorophyllin sodium, titanium
oxide, riboflavin, etc. The sweeteners include
aspartame, saccharin, dipotassium glycylrrhizinate,
stevia, maltose, maltitol, thick malt syrup, powdered
sweet hydrangea leaf, etc. The surfactants include
phospholipids, glycerin fatty acid esters, polyethylene
glycol fatty acid esters, sorbitan fatty acid esters,
polyoxyethylenes, hydrogenated castor oil, etc.
The active ingredient referred to herein
includes pharmaceutically active ingredients,
agrochemical ingredients, ingredients for fertilizer,
ingredients for feed, ingredients for food, ingredients
for cosmetic, coloring matters, flavoring materials,
metals, ceramics, catalysts, surfactants, etc., and may
be in any form such as powder, crystals, oil, solution
or the like. The active ingredient may be that coated
for, for example, the control of dissolution and
release or the reduction of a bitter taste.
For example, the pharmaceutically active
ingredients are those administered orally, such as
antipyretic analgesic antiphlogistics, hypnotic
sedatives, sleepiness inhibitors, dinics, infant
analgesics, stomachics, antacids, digestives,
cardiotonics, drugs for arrhythmia, hypotensive drugs,
vasodilators, diuretics, antiulcer drugs, drugs for
controlling intestinal function, therapeutic drugs for
osteoporosis, antitussive expectorants, antasthmatics,
antibacterials, drugs for pollakiurea, tonics, vitamin

preparations, etc.
The content of the active ingredient(s) in
the molded product of the present invention is 0.01 to
99 wt% based on the weight of the molded product. When
the content of the active ingredient(s) is less than
0.01 wt%, no sufficient drug efficacy can be expected.
When the content is more than 99 wt%, the content of
the excipient is not sufficient, so that satisfactory
physical properties cannot be imparted; for example,
the molded product is worn away or destroyed.
When the cellulose powder of the present
invention is used in the case where the content of the
active ingredient(s) in the molded product is high, it
is especially advantageous because it has, for example,
the following advantages: it can impart a sufficient
moldability without accelerating the retardation of
disintegration even at a high striking pressure; it
permits reduction of the amount of the cellulose powder
to be added and hence miniaturization of the molded
product; and the degree of wear of the resulting
tablets is low and their powdering and breakage during
packing into bottles and transportation is minimal.
The cellulose powder of the present invention is
advantageous when the content of the active
ingredient(s) is 5 wt% or more, preferably 10 wt% or
more, still more preferably 30 wt% or more, in
particular, 50 wt% or more.
Since the cellulose powder of the present

invention has an excellent compression moldability, it
can be molded with a small blending amount thereof or a
low compressive force and hence is very suitable for
tabletting the active ingredient(s). The cellulose
powder of the present invention enables the tabletting
of a pharmaceutically active ingredient with poor
moldability, the miniaturization of large tablets of a
Chinese orthodox medicine, crude drug, cold remedy,
vitamin preparation or the like, and the preparation of
intraoral rapidly soluble tablets, granule-containing
tablets, or the like.
The tablets referred to herein are molded
products containing the cellulose powder of the present
invention and optionally other additives and obtained
by any of a direct tabletting method, a granule
compression method and an extra-granulation method.
Tablets obtained by direct compression are especially
preferable.
The cellulose powder of the present invention
is especially advantageously used for an active
ingredient for medicine having a low moldability,
because of the advantages, for example, that compres-
sion into tablets can be carried out at a high striking
pressure without accelerating the retardation of
disintegration. Whether the moldability is low or not
can be determined by the hardness of tablets obtained
by placing 0.5 g of the pharmaceutically active
ingredient in a die (manufactured by Kikusui Seisakusho

Ltd. from material SUK 2,3) and compressing the active
ingredient with a flat punch and a base area of 1 cm2
(manufactured by Kikusui Seisakusho Ltd. from material
SUK 2,3) until the pressure becomes 100 MPa (a static
compressing machine such as PCM-1A manufactured by
Aikoh Engineering Co., Ltd. is used and the compression
rate is approximately 20 - 30 cm/min). The cellulose
powder of the present invention is especially
effectively used when the tablet hardness of the
pharmaceutically active ingredient is less than 100 N,
preferably less than 50 N, more preferably less than 10
N. Such a drug includes phenacetin, acetaminophen,
ethenzamide, etc.
When the cellulose powder of the present
invention is used in combination with a fluidizing
agent and a disintegrating agent, tablets especially
excellent in moldability and disintegrating property
can be produced without deteriorating the fluidity
during the production of the tablets. As the
disintegrating agent, a super-disintegrating agent such
as sodium croscarmellose (e.g. "Ac-Di-Sol" manufactured
by FMC Corp.) is preferably used because it is
effective even when added in a small amount. As the
fluidizing agent, light silicic anhydride is especially
preferable, and the fluidizing agent includes "Aerosil"
(mfd. by Nippon Aerosil Co., Ltd.), "Carplex" (mfd. by
Shionogi & Co., Ltd.), "Cyroid" (mfd. by Fuji Davisson
Co., Ltd.), "Adsolider" (mfd. by Freund Sangyo K.K.),

etc. Although the proportions of the components
described above are not particularly limited, suitable
examples thereof are as follows: the microcrystalline
cellulose of the present invention 1 to 99 wt%, the
disintegrating agent 0.5 to 20 wt%, and the fluidizing
agent 0.1 to 5 wt%.
It is preferable to adopt a method comprising
premixing the active ingredient(s) and the fluidizing
agent at first, mixing therewith the cellulose powder
of the present invention, the disintegrating agent and
optionally other additives, and then making the result-
ing mixture into tablets, because this method gives
higher fluidity and moldability than a method in which
all the components are mixed at once. With a decrease
of the fluidity of the active ingredient(s) and an
increase of the proportion of the active ingredient(s),
the timing of addition of the fluidizing agent has a
more remarkable effect.
Particularly when rapidly-disintegrating
property is required, the molded product of the present
invention is especially effective since the molded
product of the present invention can have a sufficient
hardness even when produced at a low striking pressure
and thus may be made thick, so that many conduits can
be left in the molded product. The term "rapidly-
disintegrating property" means that a molded product is
disintegrated within 1 minute in a medium such as
water, artificial gastric juice, artificial intestinal

juice, saliva or the like. Pharmaceutical compositions
having such a characteristic include intraoral rapidly-
soluble tablets, intraoral rapidly-disintegrable
tablets, etc.
The cellulose powder of the present invention
is very suitable also for tabletting, for example,
granules each having a coating film. When a mixture of
coated granules, the cellulose powder of the present
invention and optionally other additives are made into
tablets, a practical hardness can be attained even if
the compression stress is greatly reduced. Therefore,
damages to the coating films by the compression stress
can be suppressed, so that the mixture can be made into
tablets while enabling the granules to retain their
expected dissolving and releasing properties.
The active ingredient vulnerable to compres-
sion herein is, for example, an active ingredient which
is inactivated by compression stress or heat, or an
active ingredient which cannot exhibit expected
dissolving and releasing properties because the coating
portion of the active ingredient is damaged by
pressure.
The molded product containing a coated active
ingredient(s) of the present invention refers to a
molded product having the molded product form defined
above, such as powder, granular preparations (e.g. fine
granules or granules), or the like and containing one
or more active ingredients, wherein the active

ingredient(s) per se is coated with a film; particles
made of the active ingredient(s) and additives are
coated with a film; the active ingredient(s) is coated
by granulating a mixture of the active ingredient(s)
and a coating agent; or the mixture thereof. The
coating agent is used, for example, masking a taste,
imparting sustained-release properties or enteric
properties, or preventing moisture, and includes, for
example, cellulose type coating agents (e.g. ethyl
cellulose, hydroxypropylmethyl cellulose phthalate,
carboxymethylethyl cellulose, hydroxypropylmethyl
cellulose acetate succinate, cellulose acetate
succinate, cellulose acetate phthalate, and cellulose
acetate), acrylic polymer type coating agents (e.g.
Eudragit RS, Eudragit L and Eudragit NE), shellac and
silicone resins. These may be used singly or in
combination. As a method for using these coating
agents, a well-known method may be used. The coating
agent may be dissolved in an organic solvent or
suspended in water. The coating agent suspended in
water may be freely granulated together with one or
more active ingredients for medicine and other
components.
With an increase of the proportion of the
cellulose powder of the present invention blended in
the molded product containing one or more coated active
ingredients of the present invention, the suppression
of the damage to the coating film by the cellulose

powder becomes more effective. The proportion to be
blended is preferably 1 to 90 wt%. When the proportion
is less than 1 wt%, no sufficient effect can be
obtained. When the proportion is more than 90 wt%, the
proportion of the active ingredient(s) is undesirably
insufficient. The proportion is more preferably 5 to
80 wt%, in particular, 5 to 70 wt%.
The cellulose powder of the present invention
can be used in wet granulation as, for example, a
reinforcing agent for a sugar coating in sugar-coated
tablets, an extrudability improver in extrusion
granulation, or a granulation assistant in crushing
granulation, fluidized-bed granulation, high-shear
granulation, tumbling fluidized-bed granulation or the
like, and permits preparation of a granular pharma-
ceutical composition or granules to be compressed into
tablets. For preparing the granules to be compressed
into tablets, a dry granulation method may be adopted.
In addition, tabletting by the method wherein the
cellulose powder of the present invention is added to
such granules that are obtained by a well-known method
and the mixture is compression molded (an extra-
granulation method) is also applicable. Since the
cellulose powder of the present invention has high
water absorption properties, the rate of granulation
can be reduced even when a highly water-soluble
pharmaceutical active ingredient is granulated. It,
therefore, reduces the formation of coarse particles

and, thus, contributes to the increase of granulation
yield. The cellulose powder of the present invention
gives a bulky granulation product because of its low
particle density and hence contributes also to the
preparation of granules for compression tabletting with
high compression moldability. Furthermore, the
cellulose powder of the present invention may be
blended into a powder in order to, for example, prevent
blocking or improve the fluidity, or it may be blended
into capsules in order to, for example, improve the
degree of filling.
The present invention is described in detail
by way of the following examples, which do not limit
the scope of the invention. Method for measuring
physical properties in the examples and comparative
examples are as follows.
1) Average polymerization degree
A value measured by the copper ethylene-
diamine solution viscosity method described in the
crystalline cellulose identification test (3) in the
13th revised Japanese Pharmacopoeia.
2) L/D of particles before drying
The average L/D value of particles in a
cellulose dispersion before drying was measured as
follows. The cellulose dispersion was sifted through
JIS standard screens (Z8801-1987), and a photo-
micrograph of particles that had passed through a 75-um
screen and had remained on a 38-(jm screen was subjected

to image analysis processing (apparatus: Hyper 700,
software: Imagehyper, manufactured by Interquest Inc.).
L/D of the particles was defined as the ratio between
the long side and short side (long side/short side) of
a rectangle having the smallest area among rectangles
circumscribed about any of the particles. As the
average L/D value of the particles, the average of the
L/D values of at least 100 of the particles was used.
3) Loss in weight on drying [%]
After 1 g of powder was dried at 105°C for 3
hours, the loss in weight was expressed as a percentage
by weight.
4) Proportion of particles capable of remaining on a
250-mm screen [%]
Using a low-tap type sieve shaker (Sieve
Shaker Model A, mfd. by Heikoh Seisaku-sho Co., Ltd.),
10 g of a sample was sifted through a JIS standard
screen (Z8801-1987) with a screen opening of 250 mm for
10 minutes, and the weight of particles remaining on
the 250-mm screen was expressed as a percentage by
weight based on the total weight.
5) Average L/D value of particles of 75 mm or less
A photomicrograph of particles that had
passed through a 75-mm JIS standard screen in sifting
with Air Jet Sieve (Model A200LS, mfd. by ALPINE) was
subjected to image analysis processing (apparatus:
Hyper 700, software: Imagehyper, manufactured by
Interquest Inc.). L/D was defined as the ratio between

the long side and short side (long side/short side) of
a rectangle having the smallest area among rectangles
circumscribed about any of the particles. As the
average L/D value of the particles, the average of the
L/D values of at least 400 of the particles was used..
The average L/D value should be measured
after previously making the particles discrete so that
they are not entangled with one another.
6) Apparent specific volume [cm3/g]
A powder sample was roughly packed into a
100-cm3 glass measuring cylinder over a period of 2 - 3
minutes by the use of a metering feeder or the like,
and the top surface of the powder layer was made level
with a soft brush such as a writing brush, after which
the volume of the powder sample was read. The apparent
specific volume was expressed as a value obtained by
dividing the read value by the weight of the powder
sample. The weight of the powder was properly
determined so that its volume might be approximately 70
- 100 cm3.
7) Apparent tapping specific volume [cmVg]
Using a commercial powder physical property
measuring machine (Powder Tester Model T-R, mfd. by
Hosokawa Micron Corporation), a 100-cm3 cup was filled
with powder and tapped 180 times. Then, the apparent
tapping specific volume was calculated by dividing the
volume of the cup by the weight of the powder layer
remaining in the cup.

8) Angle of repose [°]
The water content of powder (measured by
means of an infrared moisture meter (Model FD-220, mfd.
by KETT Science Laboratory; lg, 105°C)) was adjusted to
3.5 - 4.5%. Thereafter, using a commercial powder
physical property measuring machine (Powder Tester
Model T-R, mfd. by Hosokawa Micron Corporation), the
powder fell under the following conditions: a metal
funnel (made of a material incapable of generating
static electricity) with an orifice diameter of 0.8 cm,
and vibration graduation 1.5. The angles of the
ridgelines (the angles of two ridgelines; measurement
distance 3°) of a heap formed by the powder were
measured. The angle of repose [°] was expressed as the
average of three measurements.
9) Compressibility [%]
Compressibility was calculated by the
following equation (3) by using the apparent specific
volume and apparent tapping specific volume defined
above:
Compressibility = 100 x [(I/apparent tapping
specific volume) - (I/apparent specific volume)] /
(I/apparent tapping specific volume) (3)
10) Average particle size [fom]
Using a low-tap type sieve shaker (Sieve
Shaker Model A, mfd. by Taira Kosaku-sho Co., Ltd.) and
JIS standard screens (Z8801-1987), 10 g of a powder
sample was sieved for 10 minutes to measure the

particle size distribution. The average particle size
was expressed as a particle size corresponding to a
cumulative weight percentage of 50%.
11) Water vapor specific surface area [irr/g]
Using a dynamic water vapor adsorption
apparatus DVS-1 (mfd. by Surface Measurement Systems
Ltd.) and water vapor as an adsorption gas, the amount
of water vapor adsorbed by a sample was measured in a
range of 0 - 30% RH according to the measuring steps
described below, and the water vapor specific surface
area was calculated by a BET method. The calculation
was carried out by taking the molecular occupied area
of water as 8.lA. As the sample, 0.01 - 0.02 g of a
sample obtained by removing water from about 0.10 g of
cellulose powder by vacuum drying in 5-cm3 sample tube
at 100°C for 3 hours was placed in the aforesaid
apparatus and subjected to the measurement.
(Measuring steps)
The sample was allowed to stand at each of
the following relative humidities for the following
measurement time and the amount of water vapor adsorbed
onto the sample was measured.
Relative humidity Measurement time
0% RH 200 min. or less
3% RH 150 min. or less
6, 9, 12, 15, 18, 21, 24, 27 or 30% RH
100 min. or less.

12) Nitrogen adsorption specific surface area [mVg]
Measured by a BET method using a Flowsorb
II2300 manufactured by Shimadzu Corp. and nitrogen as
an adsorption gas.
13) Average yield pressure [MPa]
The water content (measured by means of an
infrared moisture meter (Model FD-220, mfd. by KETT
Science Laboratory; lg, 105°C)) of powder was adjusted
to 3.5 - 4.5%. Then, 0.5 g of a sample of the powder
was placed in a die (manufactured by Kikusui Seisakusho
Ltd. from material SUK 2,3) and compressed with a flat
punch having a base area of 1 cm2 (manufactured by
Kikusui Seisakusho Ltd. from material SUK 2,3) until
the pressure became 10 MPa (a compressing machine PCM-
1A manufactured by Aikoh Engineering Co., Ltd. was used
and the compression rate was adjusted to 1 cm/min). A
stress P and the height h [cm] of the powder layer at
the stress P were input into a computer at a data input
rate of 0.02 second and recorded therein.
The relationship between the stress P and
In[l/(1 - D)] calculated from the volume V [cm3] of the
powder layer at the stress P was graphically
illustrated, followed by linear regression in a stress
P [MPa] range of 2 - 10 MPa by a method of least
squares. The average yield pressure was defined as the
reciprocal number of the slope k of the regression
line. V [cm3] was expressed as the product of the base
area (1 cm2) of the punch with a flat surface and the

height h [cm] of the powder layer at the stress P. The
height h of the powder layer should be measured without
strain in the system of the compressing machine (the
total strain in the die, punch, load cell, plunger,
etc.). D was calculated by the following equation (4):
D = [(0.5 x (1 - W / 100)) / V] / 1.59 (4)
wherein D is the packing rate of tablets, W is the
water content [%] measured by means of an infrared
moisture meter (Model FD-220, mfd. by KETT Science
Laboratory; lg, 105°C), and the value 1.59 is the true
density [g/cm3] of the cellulose powder measured with an
air comparison type gravimeter (Pycnometer 930, mfd. by
Beckmann AG).
14) Water vapor adsorption rate of tablets Ka [1/min]
A cylindrical molded product with a diameter
of 0.8 cm obtained by compressing 0.05 g of a sample at
90 MPa for 10 seconds (a compressing machine PCM-1A
manufactured by Aikoh Engineering Co., Ltd. was used
and the compression rate was adjusted to 29 cm/min) was
immersed in acetonitrile (for liquid chromatography)
for 48 hours, placed in a dynamic vapor adsorption
measurement apparatus (Model DVS-1, mfd. by Microtec
Nichion Co., Ltd.), and then dried at 25°C and a
relative humidity of 0% RH in a nitrogen stream until
the tablet weight reached sufficient equilibrium (the
degree of variability of the weight for 5 minutes was
0.0015%/ min or less). Then, the relative humidity was
55% RH, and the tablet weight was recorded every

1 minute until the tablet weight reached equilibrium
(the degree of variability of the weight for 5 minutes
was 0.0015%/ min or less). The relationship between
the water vapor adsorption time t and In [6e/(0e-9) ] was
graphically illustrated, followed by linear regression
in a range of 20 - 100 minutes by a method of least
squares. The slope of the regression line was taken as
Ka. The saturated water vapor adsorption rate 0e[%] of
the tablet at a relative humidity of 55% RH and the
water vapor adsorption rate 6[%] of the tablet at a
relative humidity of 55% RH and a water vapor adsorp-
tion time of t were calculated as follows:
9e = 100 x ms/m0 [%] (5)
9 = 100 x mt/m0 [%] (6)
wherein m0 is a tablet weight [g] at the time when
equilibrium was sufficiently reached at a relative
humidity of 0% RH, mt is a tablet weight [g] at a
relative humidity of 55% RH and a water vapor adsorp-
tion time of t, and ms is a tablet weight [g] at the
time when equilibrium was sufficiently reached at a
relative humidity of 55% RH.
15) Hardness [N]
Using a Schleuniger hardness meter (Model 6D,
mfd. by Freund Sangyo K.K.), a load was applied to a
cylindrical molded product or a tablet in the direction
of diameter, and a load at the time of the destruction
thereof was measured. The hardness was expressed as
the number average of load values obtained for five

samples. A cylindrical molded product of 100%
cellulose powder and a cylindrical molded product of a
mixture of equal amounts of cellulose powder and
lactose were produced as follows. In a die (manufac-
tured by Kikusui Seisakusho Ltd. from material SUK 2,3)
was placed 0.5 g of a sample, and compressed with a
flat punch having a diameter of 1.13 cm (base area: 1
cm2) (manufactured by Kikusui Seisakusho Ltd. from
material SUK 2,3). The cylindrical molded product of
100% cellulose powder was produced by compression at 20
MPa and maintenance of the compression stress for 10
seconds (a compressing machine PCM-1A manufactured by
Aikoh Engineering Co., Ltd. was used and the compres-
sion rate was adjusted to about 10 cm/min). The
cylindrical molded product of a mixture of equal
amounts of cellulose powder and lactose was produced by
compression at 8 0 MPa and maintenance of the compres-
sion stress for 10 seconds (a compressing machine PCM-
1A manufactured by Aikoh Engineering Co., Ltd. was used
and the compression rate was adjusted to about 25
cm/min).
16) Disintegration time [seconds]
A disintegration test was carried out
according to the general test method and tablet
disintegration test method prescribed in the 13th
revised Japanese Pharmacopoeia. The disintegration
time of cylindrical molded articles or tablets in pure
water at 37°C was measured by means of a disintegration

tester (Model NT-40HS, mfd. by Toyama Sangyo Co., Ltd.,
fitted with a disc). The disintegration time was
expressed as the number average of values measured for
six samples.
17) CV value of tablets [%]
Ten tablets were accurately weighed and the
CV value was defined as the coefficient of variation of
the tablet weight.
18) Degree of wear of tablets [%]
The weight (Wa) of 20 tablets was measured,
and the tablets were placed in a tablet degree-of-wear
tester (mfd. by PTFR-A, PHARMA TEST), followed by
revolution at 25 rpm for 4 minutes. Then, fine powder
adhering to the tablets was removed and the weight (Wb)
of the tablets was measured again. The degree of wear
was calculated by the equation (7):
Degree of wear = 100 x (Wa - Wb) / Wa (7)
19) Rate of dissolution of a drug [%]
The rate of dissolution is measured by a
paddle method by using an automatic dissolution tester
DT-610 (mfd. by Nippon Bunko Kogyo Co., Ltd.). As a
test liquid, the first liquid among the test liquids in
the general test method and degradation test method
prescribed in the 13th revised Japanese Pharmacopoeia.
The measurement was carried out three times and the
average of the measured values was calculated.

Example 1
Two kilograms of commercially available SP
pulp (polymerization degree: 1030, and level-off
polymerization degree: 220) was chopped, placed in 30 L
of a 4N aqueous hydrochloric acid solution, and then
hydrolyzed at 60°C for 72 hours with stirring (rate of
stirring: 10 rpm) by a low-rate stirrer (30LGL reactor,
mfd. by Ikebukuro Hohroh Kogyo Co., Ltd.; blade
diameter: about 30 cm). The resulting acid-insoluble
residue was filtered by the use of a Buchner funnel,
and the filtration residue was washed 4 times with 70 L
of pure water, neutralized with aqueous ammonia, and
then placed in a 90-L polyethylene bucket. Pure water
was added thereto and the resulting mixture was made
into a cellulose dispersion having a concentration of
10% (pH: 6.7, and IC: 45 (j.S/cm) , while being stirred
(rate of stirring: 100 rpm) with Three-One Motor (Type
1200G, 8M/M, mfd. by HEIDON; blade diameter: about 5
cm) .
The cellulose dispersion was subjected to
spray drying (dispersion feed rate 6L/hr, inlet temper-
ature 180 to 220°C, and outlet temperature 50 to 70°C)
to obtain cellulose powder A (loss in weight on drying:
3.5%). Table 1 shows physical properties of cellulose
powder A and physical properties of a cylindrical
molded product obtained by compressing 100% cellulose
powder A. Table 2 shows physical properties of a
cylindrical molded product obtained by compressing a

mixture of equal amounts of cellulose powder A and
lactose.
Example 2
Cellulose powder B (loss in weight on drying:
4.2%) was obtained by the same procedure as in Example
1 except for using commercially available SP pulp
(polymerization degree: 790, and level-off polymeriza-
tion degree: 220) and changing the hydrolysis condi-
tions to: 4N, 40°C and 48 hours, the concentration of
the cellulose dispersion to 8%, its pH to 6.0, and its
IC to 35 fiS/cm. Table 1 shows physical properties of
cellulose powder B obtained and physical properties of
a cylindrical molded product obtained by compressing
100% cellulose powder B. Table 2 shows physical
properties of a cylindrical molded product obtained by
compressing a mixture of equal amounts of cellulose
powder B and lactose.
Example 3
Cellulose powder C (loss in weight on drying:
3.8%) was obtained by the same procedure as in Example
2 except for changing the rate of stirring during the
reaction to 5 rpm, the concentration of the cellulose
dispersion to 12% (rate of stirring for preparing the
dispersion: 50 rpm), its pH to 6.5, and its IC to 40
uS/cm. Table 1 shows physical properties of cellulose
powder C obtained and physical properties of a

cylindrical molded product obtained by compressing 100%
cellulose powder C. Table 2 shows physical properties
of a cylindrical molded product obtained by compressing
a mixture of equal amounts of cellulose powder C and
lactose.
Example 4
Cellulose powder D (loss in weight on drying:
3.2%) was obtained by the same procedure as in Example
2 except for changing the concentration of the
cellulose dispersion to 16%, its pH to 6.9, and its IC
to 65 (j.S/cm. Table 1 shows physical properties of
cellulose powder D obtained and physical properties of
a cylindrical molded product obtained by compressing
100% cellulose powder D. Table 2 shows physical
properties of a cylindrical molded product obtained by
compressing a mixture of equal amounts of cellulose
powder D and lactose.
Example 5
Cellulose powder E (loss in weight on drying:
4.0%) was obtained by the same procedure as in Example
2 except for changing the hydrolysis conditions to a 3N
aqueous hydrochloric acid solution, 40°C and 40 hours,
the concentration of the cellulose dispersion to 8%,
its pH to 6.3, and its IC to 38 (J.S/cm. Table 1 shows
physical properties of cellulose powder E obtained and
physical properties of a cylindrical molded product

obtained by compressing 100% cellulose powder E. Table
2 shows physical properties of a cylindrical molded
product obtained by compressing a mixture of equal
amounts of cellulose powder E and lactose.
Example 6
Cellulose powder F was obtained by the same
procedure as in Example 1 except for using commercial
SP pulp (polymerization degree: 870, and level-off
polymerization degree: 220), and changing the
hydrolysis conditions to a 3N aqueous hydrochloric acid
solution, 40°C and 24 hours, the rate of stirring
during the reaction to 15 rpm, the concentration of the
cellulose dispersion to 8%, its pH to 5.7, and its IC
to 30 (J.S/cm. Table 1 shows physical properties of
cellulose powder F obtained and physical properties of
a cylindrical molded product obtained by compressing
100% cellulose powder F. Table 2 shows physical
properties of a cylindrical molded product obtained by
compressing a mixture of equal amounts of cellulose
powder F and lactose.
Example 7
Cellulose powder G was obtained by the same
procedure as in Example 1 except for changing the
hydrolysis conditions to a 3N aqueous hydrochloric acid
solution, 40°C and 20 hours, the rate of stirring
during the reaction to 20 rpm, the concentration of the

cellulose dispersion to 6%, its pH to 7.1, and its IC
to 180 mm/cm. Table 1 shows physical properties of
cellulose powder G obtained and physical properties of
a cylindrical molded product obtained by compressing
100% cellulose powder G. Table 2 shows physical
properties of a cylindrical molded product obtained by
compressing a mixture of equal amounts of cellulose
powder G and lactose.
Comparative Example 1
Commercial SP pulp (polymerization degree:
790, and level-off polymerization degree: 220) was
hydrolyzed in 30 L of a 3N aqueous hydrochloric acid
solution at 105°C for 30 minutes with stirring (rate of
stirring: 30 rpm) by a low-rate stirrer (30LGL reactor,
mfd. by Ikebukuro Hohroh Kogyo Co., Ltd.; blade
diameter: about 30 cm). The resulting acid-insoluble
residue was filtered by the use of a Buchner funnel,
and the filtration residue was washed 4 times with 70 L
of pure water, neutralized with aqueous ammonia, and
then placed in a 90-L polyethylene bucket. Pure water-
was added thereto and the resulting mixture was made
into a cellulose dispersion having a concentration of
17% (pH: 6.4, and IC: 120 mS/cm), while being stirred
(rate of stirring: 500 rpm) with a Three-One Motor
(Type 1200G, 8M/M, mfd. by HEIDON; blade diameter:
about 5 cm).
The cellulose dispersion was dried in a drum

dryer (Model KDD-1 of Kusunoki Seisakusho Co., Ltd.,
steam pressure: 0.35 MPa, drum surface temperature:
136°C, number of revolutions of drum: 2 rpm, and
temperature of the dispersion in a reservoir: 100°C)
and then ground with a hammer mill, and coarse
particles were removed by a screen with opening of 425
mm to obtain cellulose powder H (loss in weight on
drying: 3.9%, corresponding to Example 1 described in
JP-A-6-316535). Table 1 shows physical properties of
cellulose powder H obtained and physical properties of
a cylindrical molded product obtained by compressing
cellulose powder H. Table 2 shows physical properties
of a cylindrical molded product obtained by compressing
a mixture of equal amounts of cellulose powder H and
lactose.
Comparative Example 2
Two kilograms of commercial SP pulp (polymer-
ization degree: 1030, and level-off polymerization
degree: 220) was chopped and then hydrolyzed in 30L of
a 0.14N aqueous hydrochloric acid solution at 121°C for
1 hour with stirring (rate of stirring: 30 rpm) by a
low-rate stirrer (30LGL reactor, mfd. by Ikebukuro
Hohroh Kogyo Co., Ltd.; blade diameter: about 30 cm).
The resulting acid-insoluble residue was filtered by
the use of a Buchner funnel, and the filtration residue
was washed 4 times with 70 L of pure water, neutralized
with aqueous ammonia, placed in a 90-L polyethylene

bucket, and then made into a cellulose dispersion
having a concentration of 17% (pH: 6.4, and IC: 64
mS/cm), while being stirred (rate of stirring: 500 rpm)
with a Three-One Motor (Type 1200G, 8M/M, mfd. by
HEIDON; blade diameter: about 5 cm).
The cellulose dispersion was subjected to
spray drying (dispersion feed rate: 6L/hr, inlet
temperature: 180 to 220°C, and outlet temperature:
70°C), after which coarse particles were removed by a
325-mesh screen to obtain cellulose powder I (loss in
weight on drying: 4.1%, corresponding to Example 1 in
JP-B-40-26274). Table 1 shows physical properties of
cellulose powder I obtained and physical properties of
a cylindrical molded product obtained by compressing
cellulose powder I. Table 2 shows physical properties
of a cylindrical molded product obtained by compressing
a mixture of equal amounts of cellulose powder I and
lactose.
Comparative Example 3
A pulp sheet of needle leaf tree and broad-
leaf tree for dissolution (a-cellulose 90.5%, p-
cellulose 4.7%, cuprammonium relative viscosity 4.70,
and whiteness 93) was disintegrated, immersed in 12 L
of a sodium hypochlorite solution (available chloride:
1.6 g/L) to adjust the pH to 10.9, and then treated at
60°C for 310 minutes. The pulp thus treated was
thoroughly washed with water, centrifugally dehydrated,

and then dried by air blowing at 105°C. The pulp dried
was ground with an oscillating ball mill for 30
minutes, after which coarse particles were removed with
a 100-mesh screen to obtain cellulose powder J (loss in
weight on drying: 2.0,%corresponding to Example 2 in
JP-A-50-19917). Table 1 shows physical properties of
cellulose powder J obtained and physical properties of
a cylindrical molded product obtained by compressing
cellulose powder J. Table 2 shows physical properties
of a cylindrical molded product obtained by compressing
a mixture of equal amounts of cellulose powder J and
lactose.
Comparative Example 4
Commercial KP pulp (polymerization degree:
840, and level-off polymerization degree: 145) was
hydrolyzed in a 0.7% aqueous hydrochloric acid solution
at 125°C for 150 minutes, and the hydrolysis residue
was neutralized, washed Sand then filtered to obtain a
wet cake. The wet cake was thoroughly ground in a
kneader, after which ethanol was added thereto so that
the volume ratio of ethanol to the ground product of
the cake becomes 1. The resulting mixture was filtered
by expression and then air-dried. The resulting dried
powder was ground with a hammer mill and coarse
particles were removed with a 40-mesh screen to obtain
cellulose powder K (loss in weight on drying: 3.0%,
corresponding to Example 1 in JP-A-56:2 04 7) . Table 1

shows physical properties of cellulose powder K
obtained and physical properties of a cylindrical
molded product obtained by compressing cellulose powder
K. Table 2 shows physical properties of a cylindrical
molded product obtained by compressing a mixture of
equal amounts of cellulose powder K and lactose.
Comparative Example 5
Cellulose powder I of Comparative Example 2
was ground with a pneumatic grinding mill (Single-Track
Jet Mill Model STJ-200, mfd, by Seishin Enterprise Co.,
Ltd.), and coarse particles were removed by a screen
with a opening of 75 ^m to obtain cellulose powder L
(loss in weight on drying: 4.1%, corresponding to
Example 1 in JP-A-63-267731). Table 1 shows physical
properties of cellulose powder L obtained and physical
properties of a cylindrical molded product obtained by
compressing cellulose powder L. Table 2 shows physical
properties of a cylindrical molded product obtained by
compressing a mixture of equal amounts of cellulose
powder L and lactose.
Comparative Example 6
Cellulose powder E of Example 5 was ground
with a magnetic ball mill for 12 hours to obtain
cellulose powder M (loss in weight on drying: 5.1%).
Table 1 shows physical properties of cellulose powder M
obtained and physical properties of a cylindrical

molded product obtained by compressing cellulose powder
M. Table 2 shows physical properties of a cylindrical
molded product obtained by compressing a mixture of
equal amounts of cellulose powder M and lactose.
Comparative Example 7
The same process as in Comparative Example 2
was carried out except for changing the hydrolysis
conditions to a 7% aqueous hydrochloric acid solution,
105°C and 20 minutes. After the filtration and washing
isopropyl alcohol was added to the filtration residue
washed, and the residue was dispersed with a Gohrin
Homogenizer Model 15M manufactured by Nihon Seiki
Seisakusho Ltd. The solid content of the resulting
dispersion was adjusted to 10%, followed by spray
drying. Coarse particles were removed by the use of a
screen with opening of 250 (am to obtain cellulose
powder N (loss in weight on drying: 3.5%, corresponding
to Example 2 in JP-A-2-84401). Table 1 shows physical
properties of cellulose powder N obtained and physical
properties of a cylindrical molded product obtained by
compressing cellulose powder N.
Table 2 shows physical properties of a
cylindrical molded product obtained by compressing a
mixture of equal amounts of cellulose powder N and
lactose.

Comparative Example 8
Using Air Jet Sieve, coarse particles were
removed from cellulose powder H of Comparative Example
1 with a 75-|um screen and fine particles were removed
therefrom with a 38-(am screen to obtain cellulose
powder 0 (loss in weight on drying: 4.0%, corresponding
to Example in JP-A-11-152233). Table 1 shows physical
properties of cellulose powder 0 obtained and physical
properties of a cylindrical molded product obtained by
compressing cellulose powder 0.
Table 2 shows physical properties of a
cylindrical molded product obtained by compressing a
mixture of equal amounts of cellulose powder 0 and
lactose.
Comparative Example 9
The same cellulose dispersion as obtained in
Example 5 was stirred (rate of stirring: 4,000 rpm)
with a TK homomixer and then subjected to spray drying
(dispersion feed rate: 6L/hr, inlet temperature: 180 zo
220°C, and outlet temperature: 50 to 70°C) to obtain
cellulose powder P (loss in weight on drying: 3.8%).
Table 1 shows physical properties of cellulose powder P
obtained and physical properties of a cylindrical
molded product obtained by compressing cellulose powder
P. Table 2 shows physical properties of a cylindrical
molded product obtained by compressing a mixture of
equal amounts of cellulose powder P and lactose.

Comparative Example 10
Commercially available SP pulp (polymer-
ization degree: 790, and level-off polymerization
degree: 220) was chopped and then hydrolyzed in a 10%
aqueous hydrochloric acid solution at 105°C for 5
minutes, and the resulting acid-insoluble residue was
filtered, washed and then subjected to pH adjustment
and concentration adjustment to obtain a cellulose
particle dispersion having a solid content of 17%, a pH
of 6.4 and an electric conductivity of 120 mS/cm. The
dispersion was dried in a drum dryer (Model KDD-1, mfd.
by Kusunoki Kikai Seisakusho Co., Ltd.: steam pressure:
0.35 MPa, drum surface temperature: 136°C, number of
revolutions of drum: 2 rpm, and temperature of the
dispersion in a reservoir: 100°C) and then ground with
a hammer mill, and coarse particles were removed by the
use of a screen with opening of 425 mm to obtain
cellulose powder Q (loss in weight on drying: 4.5%,
corresponding to Comparative Example 8 in JP-A-6-
316535) . Table 1 shows physical properties of
cellulose powder Q obtained and physical properties of
a cylindrical molded product obtained by compressing
cellulose powder Q. Table 2 shows physical properties
of a cylindrical molded product obtained by compressing
a mixture of equal amounts of cellulose powder Q and
lactose.

Comparative Example 11
Ten grams of chopped commercially available
SP pulp (polymerization degree: 1030, and level-off
polymerization degree: 220) was impregnated with a
0.25N solution of hydrochloric acid in isopropyl
alcohol and then hydrolyzed at 90°C for 10 minutes
while being stirred so that the shear rate of the
starting-material layer became 10 s"1. Then, the
hydrolysis residue was dried on trays at 40°C for 24
hours to obtain cellulose powder R (loss in weight on
drying: 2.5%, corresponding to Example 8 in RU2050362).
Table 1 shows physical properties of cellulose powder R
obtained and physical properties of a cylindrical
molded product obtained by compressing cellulose powder
R. Table 2 shows physical properties of a cylindrical
molded product obtained by compressing a mixture of
equal amounts of cellulose powder R and lactose.
Example 8
In a polyethylene bag, 20 wt% of cellulose
powder C of Example 3, 19.5 wt% of lactose (Pharmatose
100M, available from DMV Corp.), 60 wt% of ethenzamide
(mfd. by Iwaki Seiyaku Co., Ltd.) and 0.5 wt% of light
silicic anhydride (Aerosil 200, mfd. by Nippon Aerosil
Co., Ltd.) were thoroughly mixed for 3 minutes, and
magnesium stearate (mfd. by Taihei Kagaku Sangyo Co.,
Ltd.) was added thereto in an amount of 0.5 wt% based
on the total weight of the mixed powder, followed by

slow mixing for another 30 seconds. Table 3 shows the
angle of repose of the resulting mixed powder.
This mixed powder was compressed into tablets
each weighing 100 mg with a rotary tabletting machine
(CLEANPRESS CORRECT 12HUK, mfd. by Kikusui Seisakusho
Ltd.) at a turntable rotational speed of 24 rpm and a
compressive force of 3,000 N by the use of a 11R punch
with a diameter of 0.6 cm. Table 3 shows physical
properties of the tablets.
Example 9
Mixed powder and tablets were prepared by the
same procedure as in Example 8 except for using
cellulose powder E of Example 5. Table 3 shows the
angle of repose of the mixed powder and physical
properties of the tablets.
Comparative Example 12
Mixed powder and tablets were prepared by the
same procedure as in Example 8 except for using
cellulose powder H of Comparative Example 1. Table 3
shows the angle of repose of the mixed powder and
physical properties of the tablets.
Comparative Example 13
Mixed powder and tablets were prepared by the
same procedure as in Example 8 except for using
cellulose powder I of Comparative Example 2 in Example

8. Table 3 shows the angle of repose of the mixed
powder and physical properties of the tablets.
Example 10
In a polyethylene bag, 60 wt% of
acetaminophen (fine powder type, mfd. by Yoshitomi Fine
Chemical Co., Ltd.) and 0.5 wt% of light silicic
anhydride (Aerosil 200, mfd. by Nippon Aerosil Co.,
Ltd.) were mixed for 3 minutes to previously improve
the fluidity of the drug. Then, 30 wt% of cellulose
powder C of Example 3 and 9.5 wt% of corn starch
(available from Nippon Starch Chemical Co., Ltd.) were
added thereto, followed by thorough mixing for 3
minutes in the polyethylene bag. Magnesium stearate
(mfd. by Taihei Kagaku Sangyo Co., Ltd.) was added
thereto in an amount of 0.5 wt% based on the total
weight of the mixed powder, followed by slow mixing for
further 30 seconds. Table 4 shows the angle of repose
of the resulting mixed powder.
This mixed powder was compressed into tablets
each weighing 100 mg with a rotary tabletting machine
(CLEANPRESS CORRECT 12HUK, mfd. by Kikusui Seisakusho
Ltd.) at a turntable rotational speed of 53 rpm and a
compressive force of 5,000 N by the use of a 11R punch
with a diameter of 0.6 cm. Table 4 shows physical
properties of the tablets. As the disintegration time
of the tablets, a value obtained without a disc is
shown. As the rate of dissolution of the drug

contained in the tablets, a value obtained at a number
of revolutions of a paddle of 100 rpm is shown.
Example 11
In a polyethylene bag, 30 wt% of cellulose
powder C of Example 3, 9.5 wt% of crospovidone (Colidon
CL, mfd. by BASF), 60 wt% of acetaminophen (fine powder
type, mfd. by Yoshitomi Fine Chemical Co., Ltd.) and
0.5 wt% of light silicic anhydride (Aerosil 200, mfd.
by Nippon Aerosil Co., Ltd.) were mixed all at once for
3 minutes. Magnesium stearate (mfd. by Taihei Kagaku
Sangyo Co., Ltd.) was added thereto in an amount of 0.5
wt% based on the total weight of the mixed powder,
followed by slow mixing for further 30 seconds. Table
5 shows the angle of repose of the resulting mixed
powder.
This mixed powder was compressed into tablets
each weighing 100 mg with a rotary tabletting machine
(CLEANPRESS CORRECT 12HUK, mfd. by Kikusui Seisakusho
Ltd.) at a turntable rotational speed of 53 rpm and a
compressive force of 5,000 N by the use of a 11R punch
with a diameter of 0.6 cm. Table % shows physical
properties of the tablets. As the disintegration time
of the tablets, a value obtained without a disc is
shown.
Example 12
In a polyethylene bag, 60 wt% of

acetaminophen (fine powder type, mfd. by Yoshitomi Fine
Chemical Co., Ltd.) and 0.5 wt% of light silicic
anhydride (Aerosil 200, mfd. by Nippon Aerosil Co.,
Ltd.) were mixed for 3 minutes to previously improve
the fluidity of the drug. Then, 30 wt% of cellulose
powder C of Example 3 and 9.5 wt% of crospovidone
(Colidon CL, mfd. by BASF) were added thereto, followed
by thorough mixing for 3 minutes in the polyethylene
bag. Magnesium stearate (mfd. by Taihei Kagaku Sangyo
Co., Ltd.) was added thereto in an amount of 0.5 wt%
based on the total weight of the mixed powder, followed
by slow mixing for further 30 seconds. Table 5 shows
the angle of repose of the resulting mixed powder.
This mixed powder was compressed into tablets
each weighing 100 mg with a rotary tabletting machine
(CLEANPRESS CORRECT 12HUK, mfd. by Kikusui Seisakusho
Ltd.) at a turntable rotational speed of 53 rpm and a
compressive force of 5,000 N by the use of a 11R punch
with a diameter of 0.6 cm. Table ^ shows physical
properties of the tablets. As the disintegration time
of the tablets, a value obtained without a disc is
shown.
Example 13
The process of Example 12 was repeated except
for using cellulose powder E of Example 5. Table 5
shows the angle of repose of the resulting mixed powder
and physical properties of tablets made of the mixed

powder.
Example 14
In a polyethylene bag, 70 wt% of
acetaminophen (fine powder type, mfd. by Yoshitomi Fine
Chemical Co., Ltd.) and 0.5 wt% of light silicic
anhydride (Aerosil 200, mfd. by Nippon Aerosil Co.,
Ltd.) were mixed for 3 minutes to previously improve
the fluidity of the drug. Then, 25 wt% of cellulose
powder C of Example 3 and 4.5 wt% of sodium
croscarmellose (Ac-Di-Sol, mfd. by FMC Corp., sold by
Asahi Kasei Co.) were added thereto, followed by
thorough mixing for 3 minutes in the polyethylene bag.
Magnesium stearate (mfd. by Taihei Kagaku Sangyo Co.,
Ltd.) was added thereto in an amount of 0.5 wt% based
on the total weight of the mixed powder, followed by
slow mixing for further 30 seconds. Table 6 shows the
angle of repose of the resulting mixed powder.
This mixed powder was compressed into tablets
each weighing 180 mg with a rotary tabletting machine
(CLEANPRESS CORRECT 12HUK, mfd. by Kikusui Seisakusho
Ltd.) at a turntable rotational speed of 53 rpm and a
compressive force of 10,000 N by the use of a 12R punch
with a diameter of 0.8 cm. Table 6 shows physical
properties of the tablets. As the disintegration time
of the tablets, a value obtained without a disc is
shown.

Example 15
The process of Example 14 was repeated except
for using cellulose powder E of Example 5. Table 6
shows the angle of repose of the resulting mixed powder
and physical properties of tablets made of the mixed
powder. As the disintegration time of the tablets, a
value obtained without a disc is shown.
Comparative Example 14
The process of Example 10 was repeated except
for using cellulose powder H of Comparative Example 1.
Table 4 shows the angle of repose of the resulting
mixed powder and physical properties of tablets made of
the mixed powder. As the disintegration time of the
tablets, a value obtained without a disc is shown. As
the rate of dissolution of the drug contained in the
tablets, a value obtained at a number of revolutions of
a paddle of 100 rpm is shown.
Comparative Example 15
The process of Example 10 was repeated except
for using cellulose powder I of Comparative Example 2.
Table 4 shows the angle of repose of the resulting
mixed powder and physical properties of tablets made of
the mixed powder. As the disintegration time of the
tablets, a value obtained without a disc is shown. As
the rate of dissolution of the drug contained in the
tablets, a value obtained at a number of revolutions of

a paddle of 100 rpm is shown.
Comparative Example 16
The process of Example 11 was repeated except
for using cellulose powder H of Comparative Example 1.
Table 5 shows the angle of repose of the resulting
mixed powder and physical properties of tablets made of
the mixed powder. As the disintegration time of the
tablets, a value obtained without a disc is shown.
Comparative Example 17
The process of Example 11 was repeated except
for using cellulose powder I of Comparative Example 2.
Table 5 shows the angle of repose of the resulting
mixed powder and physical properties of tablets made of
the mixed powder. As the disintegration time of the
tablets, a value obtained without a disc is shown.
Comparative Example 18
The process of Example 12 was repeated except
for using cellulose powder H of Comparative Example 1.
Table 5 shows the angle of repose of the resulting
mixed powder and physical properties of tablets made of
the mixed powder. As the disintegration time of the
tablets, a value obtained without a disc is shown.
Comparative Example 19
The process of Example 12 was repeated except

for using cellulose powder I of Comparative Example 2.
Table 5 shows the angle of repose of the resulting
mixed powder and physical properties of tablets made of
the mixed powder. As the disintegration time of the
tablets, a value obtained without a disc is shown.
Comparative Example 2 0
The process of Example 14 was repeated except
for using cellulose powder H of Comparative Example 1.
Table 6 shows the angle of repose of the resulting
mixed powder and physical properties of tablets made of
the mixed powder. As the disintegration time of the
tablets, a value obtained without a disc is shown.
Comparative Example 21
The process of Example 14 was repeated except
for using cellulose powder I of Comparative Example 2.
Table 6 shows the angle of repose of the resulting
mixed powder and physical properties of tablets made of
the mixed powder. As the disintegration time of the
tablets, a value obtained without a disc is shown.
Example 16
(Preparation of nucleus particles)
Into a rolling fluidized-bed coating
apparatus ("Multiplex" Model MP-01, mfd. by Powrex;
using a Wurster column with side air) was charged 0.7
kg of trimebutin maleate (available from Sumitomo Fine

Chem. Co., Ltd.), and sprayed with a 5 wt% hydroxy-
propylmethyl cellulose (TC-5E, available from Shin-etsu
Chemical Co., Ltd.) binder solution (spray air
pressure: 0.13 MPa, spray air flow rate: 35 L/min, side
air pressure: 0.10 MPa, charged air temperature: 75°C,
exhaust temperature: 37°C, air flow rate: 40 m3/hr, and
binder solution feed rate: 7 g/min) until its
proportion becomes 3 wt% (in terms of solids) based on
the weight of trimebutin maleate, followed by pre-
granulation. Coarse particles were removed from the
pre-granulation product by the use of a screen having
opening of 250 |jjn, and 0.7 kg of the residue was
charged into the aforesaid coating apparatus and
sprayed with a film coating liquid consisting of 38.1
wt% of an aqueous ethyl cellulose dispersion
("Aquacoat" ECD-30, mfd. by FMC Corp., sold by Asahi
Chemical Industry Co.; solid content 30 wt%), 2.9 wt%
of triacetin, 38.1 wt% of a 15 wt% aqueous mannitol
solution and 20.9 wt% of water (spray air pressure:
0.10 MPa, spray air flow rate: 30 L/min, side air
pressure: 0.02 MPa, charged air temperature: 70°C,
exhaust temperature: 36°C, air flow rate: 40 mVhr, and
liquid
film-coating/ feed rate: 8 g/min) until its propor-
tion becomes 30 wt% (in terms of solids) based on the
weight of the trimebutin maleate pre-granulation
product to obtain coated granules. The coated granules
were dried on trays at 40°C for 30 minutes and then
subjected to curing (film formation by heating) treat-

merit by drying on trays at 80°C for 60 minutes to
obtain nucleus particles A. Table 7 shows the rate of
dissolution of trimebutin maleate in nucleus particles
A after 1 minute.
(Preparation of nucleus particle-containing tablets)
In a die (manufactured by Kikusui Seisakusho
Ltd. from material SUK 2,3) was placed 0.2 g of a
sample consisting of 59 wt% of cellulose powder B of
Example 2, 26 wt% of nucleus particles A and 15 wt% of
sodium croscarmellose (Ac-Di-Sol, mfd. by FMC Corp.,
sold by Asahi Kasei Co.), and compressed with a flat
punch having a diameter of 0.8 cm (manufactured by
Kikusui Seisakusho Ltd. from material SUK 2,3). The
compression stress was maintained at 1,400 N for 10
seconds to obtain nucleus particle-containing tablets
A. As a compressing machine, PCM-1A manufactured by
Aikoh Engineering Co., Ltd. was used. Table 7 shows
the tablet hardness of nucleus particle-containing
tablets A and the rate of dissolution of trimebutin
maleate in nucleus particle-containing tablets A after
1 minute.
Example 17
Nucleus particle-containing tablets B were
obtained by the same procedure as in Example 16 except
for changing their composition and the compression
stress as follows; cellulose powder B of Example 2: 59
wt%, nucleus particles A: 26 wt%, corn starch: 10 wt%,

sodium croscarmellose: 5 wt%, and compression stress:
1,500 N. Table 7 shows the tablet hardness of nucleus
particle-containing tablets B and the rate of dissolu-
tion of trimebutin maleate in nucleus particle-
containing tablets B after 1 minute.
Example 18
Nucleus particle-containing tablets C were
obtained by the same procedure as in Example 16 except
for changing their composition as follows; cellulose
powder B of Example 2: 59 wt%, nucleus particles A: 26
wt%, partly pregelatinized starch ("PCS" PC-10,
available from Asahi Kasei Co.): 10 wt%, and sodium
croscarmellose: 5 wt%. Table 7 shows the tablet
hardness of nucleus particle-containing tablets C and
the rate of dissolution of trimebutin maleate in
nucleus particle-containing tablets C after 1 minute.
Example 19
(Preparation of nucleus particles)
A spherical nucleus ("Celfia" CP-305,
available from Asahi Kasei Co.) was charged into a
rolling fluidized-bed coating apparatus ("Multiplex"
Model MP-25, mfd. by Powrex) and sprayed with a drug-
coating solution consisting of 10 parts of riboflavin,
2 wt% of hydroxypropyl cellulose (L type, available
from Nippon Soda Co., Ltd.) and 88 wt% of water, to
obtain layering granules containing 2 wt% of

riboflavin. Into a rolling fluidized-bed coating
apparatus ("Multiplex" Model MP-01, mfd. by Powrex) was
charged 1.5 kg of the layering granules, and sprayed
with a film coating liquid consisting of 32.0 wt% of an
aqueous ethyl cellulose dispersion ("Aquacoat" ECD-30,
mfd. by FMC Corp., sold by Asahi Kasei Co.; solid
content 30 wt%), 2.4 wt% of triethyl citrate, 30 wt% of
a 10 wt% aqueous hydroxypropylmethyl cellulose solution
and 35.6 wt% of water (spray air pressure: 0.16 MPa,
spray air flow rate: 40 L/min, charged air temperature:
75°C, exhaust temperature: 36°C, air flow rate: 75
liquid
m/hr, and fiim-coating/ " feed rate: 21 g/min) until
its proportion becomes 50 wt% (in terms of solids)
based on the weight of the layering granules to obtain
coated granules. The coated granules were dried on
trays at 50°C for 30 minutes and then subjected to
curing (film formation by heating) at 80°C for 60
minutes to obtain nucleus particles B. Table 8 shows
the rate of dissolution of riboflavin in nucleus
particles B after 30 minutes.
(Preparation of nucleus particle-containing tablets)
Nucleus particle-containing tablets D were
obtained by the same procedure as in Example 16 except
for changing their composition and the compression
stress as follows; cellulose powder B of Example 2: 50
parts, nucleus particles B: 45 parts, sodium
croscarmellose: 5 parts, and compression stress: 2,200
N. Table 8 shows the tablet hardness of nucleus

particle-containing tablets D and the rate of dissolution
of riboflavin in nucleus particle-containing
tablets D after 30 minutes.
Comparative Example 22
Nucleus particle-containing tablets E were
obtained by the same procedure as in Example 16 except
for using cellulose powder H of Comparative Example 1.
Table 7 shows the tablet hardness of nucleus particle-
containing tablets E. Nucleus particle-containing
tablets E were hardly disintegrated in a dissolution
test, so that the rate of dissolution of trimebutin
maleate in nucleus particle-containing tablets E could
not be measured.
Comparative Example 23
Nucleus particle-containing tablets F were
obtained by the same procedure as in Example 16 except,
for using cellulose powder I of Comparative Example 2
and changing the compression stress to 1,700 N. Table
7 shows the tablet hardness of nucleus particle-
containing tablets F and the rate of dissolution of
trimebutin maleate in nucleus particle-containing
tablets F after 1 minute.
Comparative Example 2 4
Nucleus particle-containing tablets G were
obtained by the same procedure as in Example 17 except

for using cellulose powder I of Comparative Example 2
and changing the compression stress to 2,000 N. Table
7 shows the tablet hardness of nucleus particle-
containing tablets G and the rate of dissolution of
trimebutin maleate in nucleus particle-containing
tablets G after 1 minute.
Comparative Example 25
Nucleus particle-containing tablets H were
obtained by the same procedure as in Example 18 except
for using cellulose powder I of Comparative Example 2
and changing the compression stress to 1,800 N. Table
7 shows the tablet hardness of nucleus particle-
containing tablets H and the rate of dissolution of
trimebutin maleate in nucleus particle-containing
tablets H after 1 minute.
Comparative Example 2 6
Nucleus particle-containing tablets I were
obtained by the same procedure as in Example 19 except
for using cellulose powder I of Comparative Example 2
and changing the compression stress to 3,300 N. Table
8 shows the tablet hardness of nucleus particle-
containing tablets I and the rate of dissolution of
riboflavin in nucleus particle-containing tablets I
after 30 minutes.

INDUSTRIAL APPLICABILITY
Since the cellulose powder of the present
invention is excellent in fluidity and disintegrating
property while retaining a good compression mold-
ability, the cellulose powder makes it possible to
provide tablets having high hardness without retarda-
tion of their disintegration, especially, even when the
tablets are molded under a high striking pressure.
Furthermore, the cellulose powder makes it possible to
provide tablets which maintain their uniformity in
weight even when their drug content is high and have a
good balance between hardness and disintegrating
property. Therefore, the cellulose powder of the
present invention is very useful for miniaturizing, for
example, tablets containing an active ingredient having
a large specific volume, or tablets having a high
content of an active ingredient. Moreover, in granule-
containing tablets containing a coated active
ingredient, the cellulose powder of the present inven-
tion exhibits such an advantage that the compression
molding of the tablets hardly destroys the granules,
hardly damages the coating films of the granules and
hardly cause a change in drug-releasing properties.

We claim:
1. Cellulose powder, having an average polymerization degree of 150 - 450,
and average L/D (the ratio of the major axis to the mirror axis) value of
particles of 75 mm or less of 2.0 - 4.5, an average particle size of 20 - 250
mm, an apparent specific volume of 4.0 - 7.0 cm3/ g, an apparent tapping
specific volume of 2.4 - 4.5 cm3/g, and an angle of repose of 55° or less,
wherein the average polymerization degree is higher than a
polymerization degree measured by a viscosity method after hydrolysis
carried out under the following conditions: 2.5N hydrochloric acid,
boiling temperature, and 15 minutes, by 5 to 300.
2. The cellulose powder as claimed in claim 1, wherein the average
polymerization degree is 230 - 450.
3. The cellulose powder as claimed in any one of claims 1 and 2, wherein the
angle of ropes is 54° or less.
4. The cellulose powder as claimed in any one of claims 1 to 3, wherein the
cellulose powder having a specific surface area of 85 m2/g or more as
measure by water vapor adsorption.
5. The cellulose powder as claimed in any one of claims 1 to 4, wherein a
breaking load tablets obtained by compressing 0.5 g of the cellulose
powder at 20 Mpa is 170 N or more and the disintegration time of the
tablets is 130 seconds or less.
6. The cellulose powder as claimed in any one of claims 1 to 5, wherein the
breaking load of tablets obtained by compressing 0.5 g of a mixture of
equalamounts of the cellulose powder and lactose at 80 MPa is 150 N or
more and the disintegration time of the tablets is 120 seconds or less.
7. A process for producing cellulose powder comprising:
i) obtaining a cellulose dispersion containing cellulose particles,
wherein
a) an average polymerizatiott is 150 - 450, the average
polymerization degree being higher than a polymerization
degree measured by a viscosity method after hydrolysis
carried out under the following conditions: 2.5N
hydrochloric acid, boiling temperature, and 15 minutes, by
5 to 300, and
b) the average L/D value in wet state is 3.0 - 5.5, by
controlling a solution-stirring force in hydrolyzing a
natural cellulose material or in a subsequent step, and
ii) spray-drying the thus obtained cellulose dispersion at an article
temperature lower than 100°C.
8. The process as claimed in claim 7, wherein the average polymerization
degree is 230-450;
9. The process as claimed in any one of claims 7 or 8, wherein the drying is
spray drying at an article temperature lower than 100°C.

10. Cellulose powder obtained by the production process as claimed in any
one of claims 7 to 9.
11. An excipient comprising the cellulose powder as claimed in any one of
claims 1 to 6 and claim 10.
12. A molded product comprising the cellulose powder as claimed in any one
of claims 1 to b and claim 10 or the excipient as claimed in claim 11.
13. The molded product as claimed in claim 12, wherein the molded product
is tablets containing one or more active ingredients.
14. The molded product as claimed in claim 13, wherein the molded product
contains the active ingredient (s) in a proportion of 30 wt% or more.
15. The molded product as claimed in any one of claims 12 to 14, wherein the
molded product contains at least one active ingredient vulnerable to
compression.
16. The molded product as claimed in claim 15, wherein the active ingredient
(s) is coated.
17. The molded product as claimed in any one of 12 to 16, wherein the
molded product is rapidly disintegrate.
18. The molded product as claimed in any one of claims 12 to 17, wherein the
molded product contains a ftuidizing agent.
Cellulose powder, having an average polymerization degree of 150 - 450, and
average L/D (the ratio of the major axis to the minor axis) value of particles of 75
mm or less of 2.0 - 4.5, an average particle size of 20 - 250 mm, an apparent specific
volume of 4.0 - 7.0 cmVg, an apparent tapping specific volume of 2.4 - 4.5 cm3/g,
and an angle of repose of 55° or less, wherein the average polymerization degree is
higher than a polymerization degree measured by a viscosity method after hydrolysis
carried out under the following conditions: 2.5N hydrochloric acid, boiling
temperature, and 15 minutes, by 5 to 300.

Documents:

in-pct-2002-1544-kol-granted-abstract.pdf

in-pct-2002-1544-kol-granted-claims.pdf

in-pct-2002-1544-kol-granted-correspondence.pdf

in-pct-2002-1544-kol-granted-description (complete).pdf

in-pct-2002-1544-kol-granted-examination report.pdf

in-pct-2002-1544-kol-granted-form 1.pdf

in-pct-2002-1544-kol-granted-form 18.pdf

in-pct-2002-1544-kol-granted-form 2.pdf

in-pct-2002-1544-kol-granted-form 3.pdf

in-pct-2002-1544-kol-granted-form 5.pdf

in-pct-2002-1544-kol-granted-gpa.pdf

in-pct-2002-1544-kol-granted-priority document.pdf

in-pct-2002-1544-kol-granted-reply to examination report.pdf

in-pct-2002-1544-kol-granted-specification.pdf

in-pct-2002-1544-kol-granted-translated copy of priority document.pdf


Patent Number 225480
Indian Patent Application Number IN/PCT/2002/1544/KOL
PG Journal Number 46/2008
Publication Date 14-Nov-2008
Grant Date 12-Nov-2008
Date of Filing 18-Dec-2002
Name of Patentee ASAHI KASEI KABUSHIKI KAISHA
Applicant Address 2-6, DOJIMAHAMA 1-CHOME, KITA-KU, OSAKA
Inventors:
# Inventor's Name Inventor's Address
1 KAMADA ETSUO 2-4, INABAZAKIMACHI, NOBEOKA-SHI, MIYAZAKI
2 HONDA YOHSUKE 382-3, MUKABAKIMACHI, NOBEOKA-SHI, MIYAZAKI
3 GOMI SHUN ICHI 36-712, SAKURAZONOMACHI, NOBEOKA-SHI MIYAZAKI
4 YAMAZAKI NAOAKI 2167-316, ATAGOMACHI-3-CHOME, NOBEOKA-SHI, MIYAZAKI
5 OBAE KAZUHIRO 23-341, SAKURAZONOMACHI, NOBEOKA-SHI MIYAZAKI
PCT International Classification Number A61K 47/38, 9/20
PCT International Application Number PCT/JP01/05576
PCT International Filing date 2001-06-28
PCT Conventions:
# PCT Application Number Date of Convention Priority Country
1 2000-204000 2000-07-05 Japan