Autoclavable suspensions of cyclosporin A Form 2

Information

  • Patent Grant
  • 9919028
  • Patent Number
    9,919,028
  • Date Filed
    Thursday, June 2, 2016
    8 years ago
  • Date Issued
    Tuesday, March 20, 2018
    6 years ago
Abstract
Disclosed herein are autoclavable formulations of cyclosporin A Form 2, methods of making such formulations, and methods of treating diseases of the eye with such formulations.
Description
BACKGROUND

Aseptic processing of cyclosporin A suspensions in a hyaluronic acid media (a hydrogel used as a suspending agent), is complicated by the fact that both the drug and the hyaluronic acid need to be pre-sterilized. Pre-sterilized hyaluronic acid is extremely expensive, costing roughly $1 million dollars for a few kilograms (roughly $10,000 per ounce) of sterile raw material. Additionally, in the process of pre-sterilizing cyclosporin A, the drug is degraded upon irradiation, as shown below and in FIGS. 1 and 2:









TABLE 1







Impact of Irradiation on Cyclosporin Stability











Sterilization
Form 1 CsA
Form 2 CsA
Form 3 CsA
Amorph, CsA


Mode
(Potency and Imp.)
(Potency and Imp.)
(Potency and Imp.)
(Potency and Imp.)





None
98.4% w/w
94.6% w/w
97.7% w/w
96.5% w/w



Total Imp: 0.6%
Total Imp: 0.6%
Total Imp: 0.8%
Total Imp: 0.7%


15 kGy Gamma
93.9% w/w
91.8% w/w
94.3% w/w
92.1% w/w



% Rel. Change: 4.5%
% Rel. Change: 2.9%
% Rel. Change: 3.6%
% Rel. Change: 4.6%



Total Imp: 1.7%
Total Imp: 1.8%
Total Imp: 1.3%
Total Imp: 1.4%


30 kGy Gamma
90.7% w/w
88.5% w/w
91.0% w/w
87.7% w/w



% Rel. Change: 7.8%
% Rel. Change: 6.4%
% Rel. Change: 6.9%
% Rel. Change: 9.2%



Total Imp: 2.8%
Total Imp: 2.4%
Total Imp: 2.3%
Total Imp: 2.3%


E-Beam
92.6% w/w
90.3% w/w
93.4% w/w
92.0% w/w



% Rel. Change: 5.9%
% Rel. Change: 4.6%
% Rel. Change: 4.5%
% Rel. Change: 4.7%



Total Imp: 1.5%
Total Imp: 1.7%
Total Imp: 1.6%
Total Imp: 1.3%










Cooling the cyclosporin during irradiation does not significantly improve the results, as shown in Table 2, below:









TABLE 2







Impact on Cyclosporin Stability after irradiation under Cold Conditions











Sterilization
Form 1 CsA
Form 2 CsA
Form 3 CsA
Amorph, CsA


Mode
(Potency and Imp.)
(Potency and Imp.)
(Potency and Imp.)
(Potency and Imp.)





None
99.4% w/w
97.6% w/w
98.4% w/w
96.5% w/w



Total Imp: 0.7%
Total Imp: 0.5%
Total Imp: 0.7%
Total Imp: 0.7%


Cold E-beam
94.6% w/w
91.1% w/w
94.6% w/w
92.3% w/w



% Rel. Change: 4.8%
% Rel. Change: 6.7%
% Rel. Change: 3.9%
% Rel. Change:



Total Imp: 1.5%
Total Imp: 1.5%
Total Imp: 1.8%
4.4%






Total Imp: 1.3%


Regular E-Beam
% Rel. Change: 5.9%
% Rel. Change: 4.6%
% Rel. Change: 4.5%
% Rel. Change:


(from Previous
Total Imp: 1.5%
Total Imp: 1.7%
Total Imp: 1.6%
4.7%


Study) % Relative



Total Imp: 1.3%


Change in






Potency on






Sterilization










Additional levels of degradants need to be qualified in preclinical safety studies. Moreover, a suspension, prepared with only 90-95% of the labeled Cyclosporin A (due to the pre-sterilization process), has a substantial probability of failure to meet regulatory guidelines for shelf-life, since regulatory authorities generally prohibit shelf-lives below 90% of label.


The present invention solves these problems. Disclosed herein are formulations of cyclosporin A, combined with a parenterally-biocompatible suspending agent, which are sterile, exceptionally stable to heat sterilization, and have excellent long-term stability.





BRIEF DESCRIPTION OF THE DRAWINGS


FIGS. 1 and 2 show change in cyclosporin A potency with change in crystal form and sterilization method.



FIG. 3 shows x-ray powder diffraction pattern data of cyclosporin A Form 2 after autoclaving.



FIG. 4 shows congestion seen on slit lamp examination with eight different formulations.



FIG. 5 depicts characteristic X-ray powder diffraction (XRPD) patterns of CsA in a new crystalline form (designated as Form 2 herein), tetragonal form (designated as Form 1 herein), and orthorhombic form (designated as Form 3 herein).



FIG. 6 depicts the XRPD diffractogram of CsA crystalline Form 2.



FIG. 7 depicts the water sorption/desorption profile of CsA Form 2.



FIG. 8 depicts MDSC analysis of CsA Form 2 recovered from 0.04% formulation with 1% PS80.



FIG. 9 shows gross ocular congestion after an injection of 100 ul of CMC, HEC, HPMC, Pluronic and PVP in phosphate buffered saline was administered subconjunctivally to New Zealand white rabbits. The rabbits were observed for seven days.



FIG. 10 shows gross ocular discharge in the experiment described in FIG. 9.



FIG. 11 shows gross ocular swelling in the experiment described in FIG. 9.



FIG. 12 shows the simulated XRPD pattern of cyclosporin A forms.





DETAILED DESCRIPTION

Cyclosporin A


Cyclosporin A (CsA) is a cyclic peptide having the following chemical structure:




embedded image



Its chemical name is cyclo[(E)-(2S,3R,4R)-3-hydroxy-4-methyl-2-(methylamino)-6-octenoyl]-2-aminobutyryl-N-methylglycyl-N-methyl-L-leucyl-L-valyl-N-methyl-L-Ieuc yl-L-alanyl-D-alanyl-N-methyl-L-leucyl-N-methyl-L-leucyl-N-methyl-L-valyl]. It is also known by the names cyclosporin, cyclosporine A, ciclosporin, and ciclosporin A. It is the active ingredient in Restasis® (Allergan, Inc., Irvine, Calif.), an emulsion comprising 0.05% (w/v) cyclosporin. Restasis® is approved in the United States to increase tear production in patients whose tear production is presumed to be suppressed due to ocular inflammation associated with keratoconjunctivitis sicca.


Cyclosporin A Form 2


Cyclosporin A is known to exist in an amorphous form, liquid crystal form, tetragonal crystalline form (form 1), and an orthorhombic form (form 3). A new crystalline form, cyclosporin A Form 2, has recently been discovered.


The XRPD pattern of CsA Form 2 differs significantly from the tetragonal form and orthorhombic form (FIG. 1). The major crystalline peaks for CsA form 2 appear at (26) when scanned by an X-ray diffractometer with X-ray source as Cu Kα radiation, A=1.54 Å, at 30 kV/15 mA: 7.5, 8.8, 10.2, 11.3, 12.7, 13.8, 14.5, 15.6 and 17.5 (d-spacing in crystal lattice at about 11.8, 10.0, 8.7, 7.8, 7.0, 6.4, 6.1, 5.6 and 5.1 Å, respectively, FIG. 2). These major peaks are defined as those being unique to Form 2 relative to the orthorhombic or tetragonal forms; as well as, peaks having an intensity greater than 5 times the background.


In one embodiment, the new crystalline form (Form 2) of CsA is a nonstoichiometric hydrate of Cyclosporin A. In another embodiment, the crystalline Form 2 is represented by the formula:




embedded image



wherein X is the number of molecules of water and varies from 0 to 3. In one embodiment, X in the above formula is 2.


Form 2 appears to be a kinetically stable form of CsA in aqueous suspensions. Suspensions containing Form 2 show no conversion to other known polymorphic or pseudomorphic forms upon storage. It has been found that Form 1 and the amorphous form convert to Form 2 in the presence of water.


The single crystal structure of the hydrate form of CsA Form 2 has been determined and the crystal structure parameters are listed in Table 2. These results indicate that Form 2 is unique compared to other known crystalline forms of cyclosporin A.









TABLE 1





Crystal data and data collection parameters of crystal


structure solution of CsA Form 2.
















formula
C62H115N35O14


formula weight
1236.67


space group
P 21 21 21 (No. 19)


a (Å)
12.6390 (5)


b (Å)
19.7582 (8)


c (Å)
 29.588 (2)


volume (Å3)
 7383.8 (7)


Z
4


dcalc (g cm−3)
1.114


crystal dimensions (mm)
0.27 × 0.18 × 0.12


temperature (K)
150


radiation (wavelength in Å)
Cu K2 (1.54184)


monochromator
confocal optics


linear abs coef (mm−1)
0.840


absorption correction applied
empiricala


transmission factors (min, max)
0.80, 0.93


diffractometer
Rigaku RAPID-II


h, k, l range
−13 to 13 −21 to 21 −32 to 21


2θ range (deg)
5.38-115.00


mosaicity (deg)
1.31


programs used
SHELXTL


Fexo
2704.0


weighting
1/[σ2(Fo2) + (0.0845P)2 + 0.0000P]



where P = (Fo2+ 2Fc2)/3


data collected
37360


unique data
9964


Rexo
0.077


data used in refinement
9964


cutoff used in R-factor calculations
Fe2 > 2.0s(Fea2)


data with I > 2.0s(I)
6597


number of variables
834


targest shift/esd in final cycle
0.00


R(Fa)
0.061


R*(Fa2)
0.145


goodness of fit
1.037


absolute structure determination
Flack parametera (0.0(3))










The asymmetric unit of this CsA Form 2 contains one cyclosporin A molecule and two water molecules. It is possible that any small molecule that can hydrogen bond to water could play the role of space filler, which would give a range of potential structures running from the orthorhombic dihydrate to distorted monoclinic dihydrate The XRPD pattern calculated from the single-crystal structure is shown in FIG. 12 and it matches the experimental pattern shown in FIG. 2. These matching patterns further corroborate that Form 2 is a unique and pure crystalline form of cyclosporin A.


Without wishing to be bound by theory, thermogravimetric analysis combined with KF titration and vapor sorption desorption analysis (VSA) suggest that CsA Form 2 is a non-stoichiometric hydrate of CsA. The vapor sorption analysis of Cyclosporin Form 2 indicates that water content in the new crystal form reversibly varies with relative humidity as shown in FIG. 7. Similar to the tetragonal form, the new CsA form undergoes a phase transition to a liquid crystal or amorphous form at 124.4° C. prior to melting as indicated by the modulated differential calorimetric (MDSC) analysis (FIG. 8).


Cyclosporin A Form 2 may be obtained by suspending amorphous 0.05% cyclosporin A (w/v) in 1% Polysorbate 80, heating the solution to 65° C., holding it at that temperature for 24 hours, and then recovering the precipitate by vacuum filtration. One can then use the cyclosporin A Form 2 thus obtained to generate additional amounts, using Cyclosporin A Form 2 as a seed crystal; in this method, one suspends about 30 g cyclosporin A in a solution of 900 ml water containing 1% (w/v) Polysorbate 80, heats the solution to 65° C., and then seeds it with 0.2 g of cyclosporin A Form 2 at a temperature of 52° C. The solution is then stirred for about 22 hours at a temperature of between about 61° C. and 65° C., and then recovers the precipitate that results.


Further details regarding CsA Form 2 may be found in U.S. patent application Ser. No. 13/480,710, the entire contents of which are incorporated by reference herein.


Heat-Stable, Heat-Sterilized Suspensions of Cyclosporin A Form 2


Compositions of the invention are ophthalmically acceptable suspensions of Cyclosporin A form 2. By “ophthalmically acceptable,” the inventors mean that the suspensions are formulated in such a way as to be non-irritating when administered to the eye of a mammal, such as a human.


The suspensions of the invention comprise cyclosporin A form 2 and a vehicle comprising a suspending agent such as hyaluronic acid, a cellulose, polyvinylpyrrolidone (PVP), Pluronic® copolymers based on ethylene oxide and propylene oxide, and Carbopol® polymers.


In one embodiment, the suspension comprises cyclosporin A Form 2 at a concentration of about 0.001% to about 10% (w/v). In one embodiment, the suspension comprises cyclosporin A form 2 at a concentration of about 0.001% (w/v) to about 0.01%, about 0.001% (w/v) to about 0.04% (w/v), about 0.001% (w/v) to about 0.03% (w/v), about 0.001% (w/v) to about 0.02% (w/v), or about 0.001% (w/v) to about 0.01% (w/v). In another embodiment, the suspension comprises cyclosporin A form 2 at a concentration of about 0.01% (w/v) to about 0.05%, about 0.01% (w/v) to about 0.04% (w/v), about 0.01% (w/v) to about 0.03% (w/v), about 0.01% (w/v) to about 0.02% (w/v), or about 0.01% (w/v) to about 0.01% (w/v). In another embodiment, the suspension comprises cyclosporin A form 2 at a concentration of about 0.01% (w/v) to about 0.1%, about 0.1% (w/v) to about 0.5% (w/v), about 0.01% (w/v) to about 1% (w/v), or about 1% (w/v) to about 10%.


For example, the suspensions may comprise about 0.001% (w/v), about 0.002% (w/v), about 0.003% (w/v), about 0.004% (w/v), about 0.005% (w/v), about 0.006% (w/v), about 0.007% (w/v), about 0.008% (w/v), about 0.009% (w/v), about 0.01% (w/v), about 0.015% (w/v), about 0.02% (w/v), about 0.025% (w/v), about 0.03% (w/v), about 0.035% (w/v), about 0.04% (w/v), about 0.045% (w/v), about 0.05% (w/v), about 0.055% (w/v), about 0.06% (w/v), about 0.065% (w/v), about 0.07% (w/v), about 0.075% (w/v), about 0.08% (w/v), about 0.085% (w/v), about 0.09% (w/v), about 0.095% (w/v), about 0.1% (w/v), about 0.15% (w/v), about 0.2% (w/v), about 0.25% (w/v), about 0.3% (w/v), about 0.35% (w/v), about 0.4% (w/v), about 0.45% (w/v), about 0.5% (w/v), about 0.55% (w/v), about 0.6% (w/v), about 0.65% (w/v), about 0.7% (w/v), about 0.75% (w/v), about 0.8% (w/v), about 0.85% (w/v), about 0.9% (w/v), about 0.95% (w/v), or about 1.0% (w/v) cyclosporin A form 2.


Examples are provided in Table 3, below:









TABLE 3







Autoclavable suspensions of cyclosporin A Form 2.

















Autoclave



CsA


Gelling
Conditions



(Crystal
CsA
Gelling Agent
Agent
(Temp


Formulation
form)
(%)
(Type)
(%)
(° C.)/min)















1
2
20
CMC
5
121/10


2
3
20
CMC
3
121/10


3
NA
0
Carbopol Ultrez
1.5
121/15





10




4
NA
0
Carbopol Ultrez
2.0
121/15





10




5
NA
0
Carbopol Ultrez
2.5
121/15





10




6
NA
0
Carbopol Ultrez
1.0
121/15





10




7
NA
0
Carbopol Ultrez
4.0
121/15





10




8
2
5
CMC
3
121/15


9
2
5
CMC
2
121/15


10
2
20
CMC
10
121/15


11
2
0
CMC
10
121/15


12
2
5
HPMC
3
121/15


13
2
5
HPMC
6
121/15


14
2
20
HPMC
6
121/15


15
2
20
HPMC
10
121/15


16
2
5
HPMC
6
121/15


17
2
20
HPMC
3
121/15


18
2
5
HPMC
3
121/15


19
2
20
HPMC
3
121/15


20
2
10
HPMC
4.5
121/15


21
2
10
HPMC
4.5
121/15


22
2
10
HEC
3
121/15


23
2
10
HEC
3
121/15


24
2
30
HEC
1
121/15


25
2
10
HA
3.5
121/15*


26
2
10
HA
2.5
121/15


27
2
30
HEC
1
121/15


28
2
30
HA
1
121/15*


29
2
10
HA
2.5
121/15


30
2
10
HA
3.5
121/15


31
2
10
HA
4.5
121/15


32
2
30
HA
3.0
121/15


33
2
20
HA
1.5
121/15


34
2
20
HA
2.5
121/15


35
2
20
HA
3.5
121/15


36
2
10
HA
4
121/15,







121/30, and







123/15


37
2
10
HA
4
121/15,







121/30, and







123/15


38
2
10
HA
4
121/15,







121/30, and







123/15


39
2
35
HA
1
121/15*


40
2
5
HA
3.5
121/15*


41
2
10
HA
3.5
121/15*


42
2
20
HA
2.0
121/15*


43
2
20
HA
2.0
121/15*


44
2
10
HA
3.5
121/15*


45
2
10
HA
3.5
121/15*


46
2
25
N/A
0
120/15


47
2
25
N/A
0
118/20


48
2
25
N/A
0
120/12


HEC1
2
5
HEC
5
121/15


HEC2
2
20
HEC
5
121/15


HEC3
2
5
HEC
2
121/15


HEC4
2
20
HEC
2
121/15


HEC5
2
5
HEC
5
121/15


HEC6
2
20
HEC
5
121/15


HEC7
2
5
HEC
2
121/15


HEC8
2
20
HEC
2
121/15


HEC9
2
10
HEC
3
121/15


PVP1
2
10
PVP
25
121/15


PVP2
2
10
PVP
25
121/15


PVP3
2
10
PVP
15
121/15


PVP4
2
10
PVP
15
121/15


PVP5
2
25
PVP
25
121/15


PVP6
2
25
PVP
25
121/15


PVP7
2
25
PVP
15
121/15


PVP8
2
25
PVP
15
121/15


PVP9
2
10
PVP
25
121/15


PVP10
2
25
PVP
25
121/15





CsA = cyclosporin A.


CMC = carboxymethyl cellulose.


HPMC = hydroxypropyl methyl cellulose.


HEC = hydroxyethyl cellulose.


HA = hyaluronic acid.


PVP = polyvinylpyrrolidone.


*= slurry autoclaved prior to addition of gelling agent.







Methods of Preparation


Suspensions of the invention contain cyclosporin A Form 2 and a suspending agent. In another embodiment, the suspension also contains one or more of water, buffer, and salt, in sufficient quantities to provide a biocompatible formulation. By “biocompatible,” the inventors mean that the suspension is appropriate for administration to the eye (for example, by parenteral administration).


The formulations of the invention may be manufactured by using either a heat-sterilized slurry of Form 2 cyclosporin mixed aseptically with a sterile parenterally-biocompatible suspending agent and other excipient; or by combining Form 2 cyclosporin with a parenterally-biocompatible suspending agent and other excipients and heat sterilizing the entire formulation.


These methods address various important problems with cyclosporin formulation: 1) solid cyclosporin cannot be pre-sterilized by irradiation without significant drug degradation and formation of degradation products; 2) sterile filtration is also not feasible because the formulation is a suspension; and 3) terminal sterilization by heat will decrease gel viscosity. Also, in one embodiment, the final viscosity of the drug formulation is sufficiently high to keep the cyclosporin suspended throughout the product's shelf-life. In another embodiment, the viscosity is sufficiently low to permit the final formulation to flow through a narrow gauge syringe, such as a 22, 23, 24, 25, or 26 gauge needle or narrower. In still another embodiment, the formulation is sufficiently high to keep the cyclosporin suspended throughout the product's shelf-life, and also sufficiently low to permit the final formulation to flow through a syringe with a 22, 23, 24, 25, or 26 gauge needle or narrower.


Methods 1 and 2, below, use hyaluronic acid as the suspending agent but, other suitable suspending agents may be substituted.


It should be noted that sterile hyaluronic acid is very expensive and that method 2 provides a unique method of sterilization, which allows the use of non-sterile hyaluronic acid by heat-reducing the polymer to the correct molecular weight range, so that it reaches the target viscosity range. Method 2, therefore, requires precision manufacturing, where each new lot of hyaluronic acid may shift to a different viscosity range, under identical manufacturing conditions. Consequently, in order to assure the correct viscosity range is reached in every commercial batch, the heat cycle will need to be adaptive—that is—adjusted according to a set of guidelines and experiments on the raw material lot prior to manufacture of the drug product.


Furthermore, it should be noted that Method 2 prepares all steps of the formulation in a single vessel. These two methods allow for the rapid production of the drug product and consequently, have substantial value in saving one day or more of valuable manufacturing time over Method 1.


These methods depend on the inventors' surprising discovery that cyclosporin A Form 2 may be autoclaved and still retain its potency and stability. Other forms of cyclosporin—amorphous, Form 1 and Form 3—cannot be autoclaved, without unacceptable loss of drug substance from the suspension.


Method 1—Aqueous Slurry Method


The appropriate amount of cyclosporin A Form 2 is suspended and mixed in phosphate buffered saline solution and the slurry is heat sterilized by autoclave. In an aseptic environment, the appropriate amount of pre-sterilized hyaluronic acid is added to the sterile cyclosporin slurry, is mixed, and then dissolved. The drug product is brought to volume with sterile water for injection. The final product has a viscosity in the correct range to create a long-term stable suspension, while allowing the final formulation to flow through a syringe fitted with a narrow-gauge needle, such as 25 gauge needle or narrower.


Method 2—Single Vessel Method


An excess of non-sterile hyaluronic acid is dissolved in phosphate buffered saline solution. Cyclosporin A Form 2 is suspended and mixed. The resulting suspension formulation is heat-sterilized by autoclave (using an “adaptive” heat cycle), at the appropriate temperature and for the appropriate amount of time, to both sterilize the formulation and bring the viscosity into the desired range.


For parenteral formulations, it may be desirable to achieve a viscosity that is sufficiently high to keep the cyclosporin suspended throughout the product's shelf-life, and also sufficiently low to permit the final formulation to flow through a syringe with a 22, 23, 24, 25, or 26 gauge needle or narrower. While hydrogel solutions are generally recognized as safe for topical use, very few have been used for parenteral administration, and none have been demonstrated to be safely injected through a 25 gauge needle (or narrower) into subconjunctival tissue at high hydrogel concentrations. A high concentration of suspending agent (up to 25%) is necessary in order to maintain the suspendability of the 5-40% cyclosporin parenteral formulations described herein. In one embodiment, parenteral formulations for use in subconjunctival tissue are (1) injectable through a narrow-gauge needle, such as 25 gauge or narrower, in order to minimize tissue damage by the needle, to allow for quick healing of the needle entry-point, and to limit the back-flow of the injected formulation; (2) sterile; (3) biocompatible; and (4) sufficiently viscous to maintain suspendability throughout the shelf-life of the formulation and to prevent tissue reflux out of the subconjunctival space. In such formulations viscosity is sufficiently high to retain long-term suspendability of the drug but sufficiently low to allow the entire formulation to readily pass through a narrow gauge needle.


In one embodiment of the invention, the formulations have a very high viscosity (e.g., ≥100,000 cps) yet may still able to be injected out of syringe through a narrow-gauge needle. The following table gives examples of such formulations.














Formulation











5% CsA, 3.5% HA
10% CsA, 3.5% HA
20% CsA, 2.0% HA



(10203X)
(10204X)
(10205X)



Viscosity: TBD
Viscosity: 1,300,000 cps
Viscosity: 700,000 cps
















Needle size
BD
TSK Steriject
BD
TSK Steriject
BD
TSK Steriject


and type
Precision
27 G × 0.5″
Precision
27 G × 0.5″
Precision-
27 G × 0.5″



Glide
UTW (Ultra
Glide
UTW (Ultra
Glide
UTW (Ultra



27 G × 0.5″
Thin Wall)
27 G × 0.5″
Thin Wall)
27 G × 0.5″
Thin Wall)



Needle
Needle
Needle
Needle
Needle
Needle


Injectabiltiy
















Methods of Treatment


Compositions of the invention may be used to treat any condition of the eye which is known to be amenable to topical treatment with cyclosporin A (such as with Restasis®) at the concentrations stated here. For example, compositions of the invention may be used to treat patients suffering from dry eye, to treat blepharitis and meibomian gland disease, to restore corneal sensitivity that has been impaired due to refractive surgery on the eye, to treat allergic conjunctivitis and atopic and vernal keratoconjunctivitis, and to treat pterygium, conjunctival and corneal inflammation, keratoconjunctivitis, graft versus host disease, post-transplant glaucoma, corneal transplants, mycotic keratitis, Thygeson's superficial punctate keratitis, uveitis, and Theodore's superior limbic keratoconjunctivitis, among other conditions.


The International Dry Eye Workshop (DEWS) defines dry eye as “a multifactorial disease of the tears and ocular surface that results in symptoms of discomfort, visual disturbance, and tear film instability with potential damage to the ocular surface, accompanied by increased osmolarity of the tear film and inflammation of the ocular surface.” It includes those conditions, such as keratoconjunctivitis sicca, that are caused by tear deficiency or excessive evaporation of tears.


Blepharitis is a chronic disorder producing inflammation of the anterior and posterior lid margin, with involvement of skin and its related structures (hairs and sebaceous glands), the mucocutaneous junction, and the meibomian glands. It can also affect the conjunctiva, tear film, and the corneal surface in advanced stages and may be associated with dry eye. Blepharitis is commonly classified into anterior or posterior blepharitis, with anterior affecting the lash bearing region of the lids, and posterior primarily affecting the meibomian gland orifices.


Meibomian gland disease most often occurs as one of three forms: primary meibomitis, secondary meibomitis, and meibomian seborrhea. Meibomian seborrhea is characterized by excessive meibomian secretion in the absence of inflammation (hypersecretory meibomian gland disease). Primary meibomitis, by contrast, is distinguished by stagnant and inspissated meibomian secretions (obstructive hypersecretory meibomian gland disease). Secondary meibomitis represents a localized inflammatory response in which the meibomian glands are secondarily inflamed in a spotty fashion from an anterior lid margin blepharitis.


Impaired corneal sensitivity often occurs after refractive surgery, such as photorefractive keratectomy, laser assisted sub-epithelium keratomileusis (LASEK), EPI-LASEK, customized transepithelial non-contact ablation, or other procedures in which the corneal nerves are severed. Impaired corneal sensitivity may also occur after viral infection, such as by HSV-1, HSV-2, and VZV viruses. Patients with impaired corneal sensitivity often complain that their eyes feel dry, even though tear production and evaporation may be normal, suggesting that “dryness” in such patients is actually a form of corneal neuropathy that results when corneal nerves are severed by surgery or inflamed after viral infection.


Allergic conjunctivitis is an inflammation of the conjunctiva resulting from hypersensitivity to one or more allergens. It may be acute, intermittent, or chronic. It occurs seasonally, that is, at only certain time of the year, or it occurs perennially, that is, chronically throughout the year. Symptoms of seasonal and perennial allergic conjunctivitis include, in addition to inflammation of the conjunctiva, lacrimation, tearing, conjunctival vascular dilation, itching, papillary hyperplasia, chemosis, eyelid edema, and discharge from the eye. The discharge may form a crust over the eyes after a night's sleep.


Atopic keratoconjunctivitis is a chronic, severe form of allergic conjunctivitis that often leads to visual impairment. Symptoms include itching, burning, pain, redness, foreign body sensation, light sensitivity and blurry vision. There is often a discharge, especially on awakening from a night's sleep; the discharge may be stringy, ropy, and mucoid. The lower conjunctiva is often more prominently affected than the upper conjunctiva. The conjunctiva may range from pale, edematous, and featureless to having the characteristics of advanced disease, including papillary hypertrophy, subepithelial fibrosis, formix fornix foreshortening, trichiasis, entropion, and madarosis. In some patients the disease progresses to punctate epithelial erosions, corneal neovascularization, and other features of keratopathy which may impair vision. There is typically goblet cell proliferation in the conjunctiva, epithelial pseudotubular formation, and an increased number of degranulating eosinophils and mast cells in the epithelium. CD25+T lymphocytes, macrophages, and dendritic cells (HLA-DR+, HLA-CD1+) are significantly elevated in the substantia propria.


Like atopic keratoconjunctivitis, vernal keratoconjunctivitis is a severe form of allergic conjunctivitis, but it tends to affect the upper conjunctiva more prominently than the lower. It occurs in two forms. In the palpebral form, square, hard, flattened, closely packed papillae are present; in the bulbar (limbal) form, the circumcorneal conjunctiva becomes hypertrophied and grayish. Both forms are often accompanied by a mucoid discharge. Corneal epithelium loss may occur, accompanied by pain and photophobia, as may central corneal plaques and Trantas' dots.


EXAMPLES

The invention is further illustrated by the following examples.


When the inventors autoclaved aqueous suspensions of cyclosporin A, the drug particles aggregated, making the product unacceptable. Additionally, the inventors found that hyaluronic acid also degrades upon autoclaving, causing a marked drop in viscosity. Lower viscosity, in turn, reduces the suspendability of the drug particles and causes them to settle. Formulations having drug particles in suspension that too rapidly settle, or irreversibly settle, may be useful for laboratory tests, but are not commercially viable.


The inventors explored formulations of four cyclosporin A polymorphic forms, the amorphous form, the tetragonal crystalline form (form 1), the orthorhombic form (form 3), and cyclosporin A Form 2.


A suspension of form 1 converts to the amorphous form and aggregates upon autoclaving; clumping of the cyclosporin is also observed. Consequently, neither form 1 nor the amorphous form is suitable for autoclave stabilization. Furthermore, an autoclaved suspension of F3 in water lost 11-28% of its potency during autoclaving (Table 4); this, too, is unacceptable. In contrast, a suspension of Form 2 in water was quite stable to autoclaving, resisting degradation when compared to a pre-sterilization control. X-ray analysis of filtered solid from the Form 2 formulation also confirms that Form 2 is polymorphically stable to autoclaving (FIG. 3). These latter two findings are extremely surprising, considering the lack of either chemical or polymorphic stability of the other three forms.


The inventors explored the autoclavability of a series of concentrated solutions of various polymers (no drug) which, when loaded in a syringe, will flow through a narrow-gauge needle (25 gauge or narrower). The polymers evaluated were as follows: crosslinked hyaluronic acid (Juvederm®), carbomer, carboxymethylcellulose-medium molecular weight, carboxymethylcellulose-high molecular weight, hydroxyethylcellulose, hydroxypropylcellulose, Pluronic F127 and polyvinylpyrrolidone K90. All of these are readily available from commercial suppliers.


One hundred microliters of each of the autoclaved solutions was injected into rabbit conjunctiva, in order to evaluate the propensity for causing inflammation. Those polymers producing an inflammatory reaction were eliminated from consideration (FIG. 4, carbomer, both CMC's, and HPMC were eliminated). Additionally, Juvederm® was eliminated because it formed a long-lasting bleb which, in humans, might cause irritation as the eyelid moves over the site of injection. Both HPMC and Pluronic separated from the solution during/after autoclaving and consequently were also eliminated. Of the commercially viable hydrogels, only HEC and PVP demonstrated that they produced no inflammation in rabbit conjunctiva after autoclaving. These two hydrogels were used to formulate cyclosporin A suspensions for further evaluation. The results of the studies are shown in Table 5.


Initially, the inventors explored the possibility of heat-sterilizing a slurry of cyclosporin A of Form 1 (which converts to the amorphous form). This approach resulted in agglomeration of the drug and consequently, the formulation was not viable. Further studies, adding PVP to suppress the agglomeration of Form 1/amorphous form, also failed.


Since heat-sterilization of an aqueous suspension of cyclosporin did not appear to be viable, the inventors planned to prepare suspensions by aseptic technique, using pre-sterilize solid cyclosporin. Various solid cyclosporins (Forms 1, 2, and 3 and amorphous) were treated with gamma or e-beam irradiation. In all cases, significant loss of drug (3-9%) occurred (FIG. 2 and Table 1). Furthermore, the substantial loss of drug indicates that high levels of degradation products (around 3-9%) are generated in the irradiation-sterilized material. These impurities may have negative toxicological and/or regulatory implications; consequently, this approach to sterilization appears to be undesirable.









TABLE 1







Effect of Irradiation Sterilization on Cyclosporin (CsA) Drug Substance (solid)











Sterilization
Form 1 CsA
Form 2 CsA
Form 3 CsA
Amorph. CsA


Mode
(Potency and Imp.)
(Potency and Imp.)
(Potency and Imp.)
(Potency and Imp.)





None
98.4% w/w
94.6% w/w
97.7% w/w
96.5% w/w



Total Imp: 0.6%
Total Imp: 0.6%
Total Imp: 0.8%
Total Imp: 0.7%


15 kGy Gamma
93.9% w/w
91.8% w/w
94.3% w/w
92.1% w/w



% Rel. Change:
% Rel. Change: 2.9%
% Rel. Change: 3.6%
% Rel. Change:



4.5%
Total Imp: 1.8%
Total Imp: 1.3%
4.6%



Total Imp: 1.7%


Total Imp: 1.4%


33 kGy Gamma
90.7% w/w
88.5% w/w
91.0% w/w
87.7% w/w



% Rel. Change:
% Rel. Change: 6.4%
% Rel. Change: 6.9%
% Rel. Change:



7.8%
Total Imp: 2.4%
Total Imp: 2.3%
9.2%



Total Imp: 2.8%


Total Imp: 2.3%


E-Beam
92.6% w/w
90.3% w/w
93.4% w/w
92.0% w/w



% Rel. Change:
% Rel. Change: 4.6%
% Rel. Change: 4.5%
% Rel. Change:



5.9%
Total Imp: 1.7%
Total Imp: 1.6%
4.7%



Total Imp: 1.5%


Total Imp: 1.3%









Subsequently, the inventors attempted to irradiate solid cyclosporin (Forms 1, 2, and 3 and amorphous), under the best conditions above, at cold temperatures. No significant improvement was noted with any of the Forms of cyclosporin (Table 2).









TABLE 2







Effect of E-Beam Sterilization of Cyclosporins under Cold Conditions











CsA Drug






Substance Sample
CsA Potency for
CsA Potency 15 kGy
CsA Potency 30 kGy Gamma
CsA Potency


Treatment
Control Sample
Gamma Treatment
Treatment
E-Beam 15 kGyTreatment





Dry Ice
99.2% w/w
96.7% w/w
93.8% w/w
93.8% w/w




(% Rel. Change: 2.5%)
(% Rel. Change: 5.4%)
(% Rel. Change: 5.4%)


Cold Pack
96.5% w/w
93.0% w/w
92.1% w/w
93.2% w/w




(% Rel. Change: 3.6%)
(% Rel. Change: 4.6%)
(% Rel. Change: 3.4%)









After it became apparent that irradiation of solid cyclosporins produced too much degradation, the inventors attempted to irradiate an aqueous suspension of cyclosporin, using hyaluronic acid as a suspending agent. This approach resulted in 4-10% degradation of the drug within the formulation.









TABLE 3







Effect of Sterilization by Irradiation on Aqueous Suspensions of


Cyclosporin [CsA] using Hyaluronic Acid [HA] as a


Suspending Agent, at Various Temperatures













%



CsA Potency
CsA Potency
Relative



for Control
Post-
Change in


Sterilization Treatment
Sample
Sterilization
Potency





Cold Pack Control CsA
103.2% w/w
Not
Not


Hydrogel Sample

Applicable
Applicable


CsA-HA Sample (Cold Pack)
103.2% w/w
98.9% w/w
4.2%


Treated with 15 kGy Gamma





CsA-HA Sample (Cold Pack)
103.2% w/w
92.3% w/w
10.6%


Treated with 30 kGy Gamma





CsA-HA Sample (Cold Pack)
103.2% w/w
92.8% w/w
10.1%


Treated with E-Beam (15 kGy)









Finally, the inventor turned their focus on steam sterilization of slurries and full formulations of cyclosporins. Slurries of Form 1 (which converts to amorphous) agglomerate during heat-sterilization. Slurries of Form 3, while physically stable and more chemically stable than Form 1, degraded significantly during heat sterilization. But, to the inventors' surprise, slurries of Form 2 were both physically and chemically stable (Tables 4 and 5).









TABLE 4







Heat-Sterilization of Slurries of Cyclosporin (ScA) Form 2 (F-2) in Water










CsA-F2 Slurry %
CsA-F3 Slurry %














Initial
96.86
101.41



120 C. 15 min
96.88
88.61



108 C. 60 min
106.69
71.72
















TABLE 5







Physical Stabiltiy of Forms 2 and 3 Before and After Heat Sterilization













Formulation
Material
Spec.
D90
D50
D10
Conditions





A
CsA-F2
Slurry
198.6313
116.8544
8.2711
Slurry control for steam




control



sterilization study


A, autoclaved
CsA-F2
Autoclaved
186.4431
99.902
7.0518
Autoclaved at 120 C. for 15




slurry



minutes


A, autoclaved
CsA-F2
Autoclaved
195.603
112.532
9.209
Autoclaved at 108 C. for 60




slurry



minutes


B
CsA-F3
Slurry
110.8281
63.3348
7.1711
Slurry control for steam




control



sterilization study


B, autoclaved
CsA-F3
Autoclaved
116.8761
67.523
12.1564
Autoclaved at 120 C. for 15




slurry



minutes


B, autoclaved
CsA-F3
Autoclaved
115.556
65.3309
10.5518
Autoclaved at 108 C. for 60




slurry



minutes


















% potency






compared to CsA



Formulation
Material
Conditions
Form 2 standard






A
CsA-F2
Control
96.9



A
CsA-F2
120° C., 15 min
96.9



A
CsA-F2
108° C., 60 min
106.7



B
CsA-F3
Control
101.4



B
CsA-F3
120° C., 15 min
88.6



B
CsA-F3
108° C., 60 min
71.7










Ocular Congestion


Parenterally-biocompatible suspending agents were identified by injecting sterile concentrated solutions into the subconjunctival space and evaluating the toxicological response. An injection of 100 ul of the following polymers in phosphate buffered saline was administered subconjunctivally to New Zealand white rabbits and observed for a period of seven days.



























tech



Alternative




type
name
source
Lot#
info
vendor
CoA
Grade
vendor
Grade

























1
PVP
PVP K30
Sigma_Aldrich
BCBB7859
Mw 40K
Sigma_Aldrich
yes

BASF
PHEUR/





81420-500G

(PSO: 5%




USP/





(or PSO

in water,




NF/JP





R14247)

pH 3.6)







2
PVP
PVP K90
Sigma_Aldrich
BCBB3954
Mw 360K
Sigma_Aldrich
yes

BASF
PHEUR/





81440-250G






USP/












NF/JP


3
PVP
PVP 10
Sigma-Aldrich
050M0039
Mw 10K
Sigma_Aldrich
yes

BASF
PHEUR/





PVP10-500G






USP/












NF


4
HPMC
Hypromellose
PSO PM#
XB14012N11
Sigma
Dow
yes
USP/






(tested to
1018

H3785:
Chemical

PHEUR






JP)
(R19424)

4000 cP,












2%












in water







5
CMC
Carboxymethyl
PSO
96413




CMC from





cellulose
R19716Q





Ashland/





sodium
pending





Aqualon is












NF/USP,



6
CMC
Carboxymethyl
PSO
96077










cellulose
R19717











sodium










7
Hydroxyethyl
Natrosol
Kevin
F0854
Type
Ashland


HEC from




cellulose
(Type
Warner

250-HHX



Ashland./




(HEC)
250-HHX


pharm



Aqualon is





pharm)






USP/EP,



8
Acrylate/C10-
Carbopol
Kevin
EC742EK343
acrylate
Lubrizol

USP/





30 Alkyl
ETD
Warner

crosspolymer


NF





acrylate
2020NF


(Viscosity,












47-77K












cP 0.5% wt












at pH 7.5)







9
Carbomer
Carbopol
Kevin
CC83RZG726
type A
Lubrizol

USP/





Interpolymer
Ultrez 10
Warner

(Viscosity,


NF






NF


45-65K









polymer


cP 0.5% wt












at pH 7.5)







10
Carbomer-
Carbopol
Kevin
EC863CC625
type C
Lubrizol

USP/





Homopolymer
980 NF
Warner

(Viscosity,


PHEUR/






polymer


40-60K


JPE









cP 0.5% wt












at pH 7.5)







1
PVP
PVP K30
Sigma_Aldrich
BCBB7859
Mw 40K
Sigma_Aldrich
yes

BASF
PHEUR/





81420-500G

(PSO: 5%




USP/





(or PSO

in water,




NF/JP





R14247)

pH 3.6)







2
PVP
PVP K90
Sigma_Aldrich
BCBB3954
Mw 360K
Sigma_Aldrich
yes

BASF
PHEUR/





81440-250G






USP/












NF/JP


3
PVP
PVP 10
Sigma-Aldrich
050M0039
Mw 10K
Sigma_Aldrich
yes

BASF
PHEUR/





PVP10-500G






USP/












NF


4
HPMC
Hypromellose
PSO PM#
XB14012N11
Sigma
Dow
yes
USP/






(tested to
1018

H3785:
Chemical

PHEUR






JP)
(R19424)

4000 cP,












2%












in water







5
CMC
Carboxymethyl
PSO
96413




CMC from





cellulose
R19716Q





Ashland/





sodium
pending





Aqualon is












NF/USP,



6
CMC
Carboxymethyl
PSO
96077










cellulose
R19717











sodium










7
Hydroxyethyl
Natrosol
Kevin
F0854
Type
Ashland


HEC from




cellulose
(Type
Warner

250-HHX



Ashland./




(HEC)
250-HHX


pharm



Aqualon is





pharm)






USP/EP,



8
Acrylate/C10-
Carbopol
Kevin
EC742EK343
acrylate
Lubrizol

USP/





30 Alkyl
ETD
Warner

crosspolymer


NF





acrylate
2020NF


(Viscosity,












47-77K












cP 0.5% wt












at pH 7.5)







9
Carbomer
Carbopol
Kevin
CC83RZG726
type A
Lubrizol

USP/





Interpolymer
Ultrez 10
Warner

(Viscosity,


NF






NF


45-65K









polymer


cP 0.5% wt












at pH 7.5)







10
Carbomer-
Carbopol
Kevin
EC863CC625
type C
Lubrizol

USP/





Homopolymer
980 NF
Warner

(Viscosity,


PHEUR/






polymer


40-60K


JPE









cP 0.5% wt












at pH 7.5)





2% Carbomer (Carbopol Ultrez 10NF, Lubrizol)


8% Carboxymethyl Cellulose (low viscosity CMC, Lubrizol)


6% Carboxymethyl Cellulose (high viscosity CMC, Lubrizol)


6% HEC (Ashland)


6% HPMC (Dow Chemical)


Juvederm Ultra (Allergan, Inc)


Pluronic F127 (BASF)


Polyvinyl pyrrolidone (PVP K90, BASF)







Gross ocular congestion was shown to resolve within 7 days for CMC, HEC, HPMC, Pluronic and PVP. Ocular discharge was shown to resolve within three days. Ocular discharge resolved within 3 days for all groups except one. Results of the experiment are provided in FIGS. 9-11.


Impurity and Potency Analysis


The inventors prepared various formulations and evaluated their potency and purity, as well particle size distribution.

















Composition

Impurities Analysis













CsA

Pre-Autoclave
Post-Autoclave















Particle

Potency (%)
CsA Total
CsA Total
Absolute
















Size
CsA
HEC
No

Impurities
Impurities
Change


Formulation
(μm)
(%)
(%)
autoclave
Autoclave
(% a/a)
(% a/a)
(% a/a)


















HEC-1
10
5
5
117.20%
115.70%
0.71%
0.69%
−0.02%


HEC-2
10
20
5
103.60%
116.60%
0.61%
0.61%
0.00%


HEC-3
10
5
2
116.40%
118.80%
0.78%
0.70%
−0.08%


HEC-4
10
20
1
124.50%
124.70%
0.73%
0.69%
−0.04%


HEC-5
25
5
5
126.70%
116.60%
0.58%
0.58%
0.00%


HEC-6
25
20
5
140.00%
147.40%
0.56%
0.56%
0.00%


HEC-7
25
5
2
137.50%
142.50%
0.63%
0.59%
−0.04%


HEC-8
25
20
2
129.50%
119.70%
0.56%
0.57%
0.01%


HEC-9
10
10
3
118.60%
111.70%
0.61%
0.62%
0.01%























Composition













CsA






Particle



Size
CsA
PVP90
Potency (%)












Formulation
(μm)
(%)
(%)
No autoclave
Autoclace















PVP-1
10
5
25
102.51
101.01


PVP-2
10
20
25
113.81
111.82


PVP-3
10
5
15
122.42
114.04


PVP-4
10
20
15
120.28
123.3


PVP-5
25
5
25
118.56
118.46


PVP-6
25
20
25
114.55
115.28


PVP-7
25
5
15
116.37
115.66


PVP-8
25
20
15
120.9
124.05


PVP-9
10
10
25
132.51
136.36


PVP-10
25
10
25
118.03
126.6



























Autoclave




CsA

Conditions Temp



Crystal

(° C.)/Time
Particle size distribution













Lot #
Form
Excipient
(min.)
D90
D50
D10
















1
2
5% CMC
None
52.38
10.80
5.31


2
2
5% CMC
121/10
18.02
11.55
5.74


3
3
3% CMC
None
28.01
12.09
6.84


4
3
3% CMC
121/10
20.31
11.27
6.56


5
2
None
None
198.63
116.85
8.27


6
2
None
120/15
186.44
99.90
7.05


7
2
None
108/60
195.60
112.53
9.21


8
3
None
None
110.83
63.33
7.17


9
3
None
121/15
116.88
67.52
12.16


10
3
None
108/60
115.56
65.33
10.55


11
2
None
None
13.15
9.12
6.17


12
2
None
121/15
14.15
9.12
6.42


13
2
None
None
14.14
9.66
6.44


14
2
None
121/15
14.30
9.37
5.95
















TABLE 5







Key F2 Formulation Properties of Evaluated Polymers















In-vivo






Autoclavability
tolerability

CSA-F2



Syringeability
(121 C., 15 min.)
(1 wk sub-conj.)
Settling
Potency





Carbopol
Max. conc. 4%
No visible
Poorly tolerated
na
na



w/22 G
change
(congestion)




Carboxymethyl Cellulose
Max. conc. 9%
No visible
Poorly tolerated
na
na


(CMC) medium viscosity
w/22 G
change
(congestion)




Carboxymethyl Cellulose
Max. conc. 6%
No visible
Poorly tolerated
na
na


(CMC) high viscosity
w/22 G
change
(congestion)




Hydroxyethyl Cellulose
Max. conc. 6%
No visible
Well tolerated.
No settling in
No loss in


(HEC)
w/22 G
change
Slight congestion
comparison
potency





compared to
with BDP gel
post-





saline.
under same
autoclave






conditions



Hydroxypropyl Methyl
Max. conc. 7%
Full formation visibly
Well tolerated.
na
na


Cellulose (HPMC)
w/22 G
separates with moist
Comparable to






heat sterilization
saline.




Juvederm Ultra
30 g, as formulated
Pre-sterilized by
poorly tolerated
na
na



by manufacturer
manufacturer
(swelling at 1 week)




Pluronic F127
Max. cone. 40%
Placebo visibly
Tolerated. Slight
na
na



w/22 G
separates with moist
congestion and






heat sterilization
discharge







compared to







saline.




Polyvinylpyrrolidone K90
Max. conc. 27%
No visible
Ok
Some settling
No loss in


(PVPK90)
w/22 G
change

with
potency






syringeable
post-






concentrations
autoclave






(but







acceptable)








Claims
  • 1. A method of making a formulation of cyclosporin A, the method comprising the steps of a) dissolving cyclosporin A form 2 in solution;b) autoclaving the solution; andc) adding a vehicle selected from the group consisting of carboxymethyl cellulose, hydroxypropyl methyl cellulose, hydroxyethyl cellulose, hyaluronic acid, polyvinylpyrrolidone, crosslinked polyacrylic acid polymers, and copolymers based on ethylene oxide and propylene oxide.
  • 2. A method of making a formulation of cyclosporin A, the method comprising the steps of a) dissolving in solution a vehicle selected from the group consisting of carboxymethyl cellulose, hydroxypropyl methyl cellulose, hydroxyethyl cellulose, hyaluronic acid, polyvinylpyrrolidone, crosslinked polyacrylic acid polymers, and copolymers based on ethylene oxide and propylene oxide;b) adding to the solution cyclosporin A Form 2; andc) autoclaving the resulting mixture.
CROSS-REFERENCE TO RELATED APPLICATION

This patent application is a divisional of copending U.S. patent application Ser. No. 13/676,362, filed Nov. 14, 2012, now abandoned, which claims priority to U.S. Provisional Patent Application No. 61/559,849, filed Nov. 15, 2011, the entire contents of which are hereby incorporated by reference.

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5981607 Ding et al. Nov 1999 A
6254860 Garst Jul 2001 B1
6350442 Garst Feb 2002 B2
6551619 Penkler et al. Apr 2003 B1
7153834 Patel Dec 2006 B2
20010041671 Napoli Nov 2001 A1
20050059583 Acheampong et al. Mar 2005 A1
20060100288 Bague et al. May 2006 A1
20060148686 Xia et al. Jul 2006 A1
20070015691 Chang et al. Jan 2007 A1
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Related Publications (1)
Number Date Country
20160271207 A1 Sep 2016 US
Provisional Applications (1)
Number Date Country
61559849 Nov 2011 US
Divisions (1)
Number Date Country
Parent 13676362 Nov 2012 US
Child 15171866 US