Patent Application
20200022947
Therapies to prevent Alzheimer's Disease (AD) progression remain a high-unmet medical need. US Food and Drug Administration (FDA) approved acetylcholinesterase (ACNE) inhibitor drugs, such as donepezil, rivastigamine and galantamine are indicated for symptomatic relief in persons with mild to moderate AD (Cummings J L, “Alzheimer's disease,” N Engl J Med (2004) 351, 56-67; Knowles J, “Donepezil in Alzheimer's disease: an evidence-based review of its impact on clinical and economic outcomes,” Core Evidence (2006) 1, 195-219). These drugs increase levels of available acetylcholine during synaptic transmission and thus compensate for the diminished function of cholinergic neurons. However, none of the drugs approved for AD are disease-modifying treatments that affect the underlying pathophysiology of the disease, so the duration of their benefit is short-term (Knowles, 2006). The development of successful disease-modifying treatments, in contrast, would have a long-term beneficial outcome on the course of AD progression.
The treatment of AD will require addressing the multiple triggers of pathogenesis. There are two primary neuropathologies in the brains of AD patients: i) extracellular protein plaques principally composed of Aβ peptides, also known as amyloid plaques; and ii) intracellular tangles of fibrils composed of tau protein found inside of neurons, also known as tau tangles. The advent and spread of neurotoxic oligomeric aggregates of Aβ is widely regarded as the key trigger leading to neuronal damage, which then leads to the accumulation of intracellular tau tangles, and finally to neuronal cell death in AD pathogenesis.
Beta-amyloid peptides (37 to 43 amino acids in length) are formed by sequential cleavage of the native amyloid precursor protein (APP) (Karran et al., “The amyloid cascade hypothesis for Alzheimer's disease: an appraisal for the development of therapeutics,” Nature Reviews (2011) 10, 698-712). Aberrant Aβ peptide isoforms that are 40 or 42 amino acids in length (Aβ40 and 42) misfold into aggregates of oligomers that grow into fibrils that accumulate in the brain as amyloid plaques. More importantly for AD pathogenesis, the alternate fate of Aβ oligomers is to become trapped in neuronal synapses where they hamper synaptic transmission, which eventually results in neuronal degeneration and death (Haass et al., “Soluble protein oligomers in neurodegeneration: lessons from the Alzheimer's amyloid β-peptide,” Nature Reviews Mol. Cell Biol. (2007) 8:101-112; Hashimoto et al, “Apolipoprotein E, especially apolipoprotein E4, increases the oligomerization of amyloid beta Peptide,” J. Neurosci. (2012) 32, 15181-15192).
The cascade of Aβ oligomer-mediated neuronal intoxication is exacerbated by another AD trigger: chronic local inflammatory responses in the brain (Krstic et al., “Deciphering the mechanism underlying late-onset Alzheimer disease,” Nature Reviews Neurology (2013), January, 9 (1): 25-34). Alzheimer's disease has a chronic neuro-inflammatory component that is characterized by the presence of abundant microglial cells associated with amyloid plaque. (Heneka et al., “Acute treatment with the PPARγ agonist pioglitazone and ibuprofen reduces glial inflammation and Abeta1-42 levels in APPV717I transgenic mice,” Brain (2005) 128, 1442-1453; Imbimbo et al., “Are NSAIDs useful to treat Alzheimer's disease or mild cognitive impairment,” Front. Aging Neurosci (2010) 2 (article 19), 1-14). These cyclooxygenase (COX1/COX2)-expressing microglia, which phagocytose amyloid oligomers, become activated to secrete pro-inflammatory cytokines. (Hoozemans et al., “Soothing the inflamed brain: effect of non-steroidal anti-inflammatory drugs on Alzheimer's disease pathology,” CNS & Neurological Disorders—Drug Targets (2011) 10, 57-67; Griffin T S., “What causes Alzheimer's?” The Scientist (2011) 25, 36-40; Krstic 2013). This neuro-inflammatory response, besides promoting local vascular leakage through the blood brain barrier (BBB). Zlokovic (Zlokovic B., “Neurovascular pathways to neurodegeneration in Alzheimer's disease and other disorders,” Nature Reviews Neurosci. (2011) 12, 723-738) has been implicated in driving further production of aberrant Aβ peptides 40 and 42 via modulation of gamma-secretase activity (Yan et al., “Anti-inflammatory drug therapy alters β-amyloid processing and deposition in an animal model of Alzheimer's disease,” J. Neurosci. (2003) 23, 7504-7509; Karran 2011) and to be detrimental to hippocampal neurogenesis in the adult brain (Gaparini et al., “Non-steroidal anti-inflammatory drugs (NSAIDs) in Alzheimer's disease: old and new mechanisms of action,” J. Neurochem (2004) 91, 521-536). Thus, neuro-inflammation, in combination with amyloid oligomer-mediated neuronal intoxication, creates a cycle that results in progressive neural dysfunction and neuronal cell death spreading throughout the brain in subjects with AD.
Compelling evidence from multiple epidemiology studies revealed that long-term dosing with non-steroidal anti-inflammatory drugs (NSAIDs) dramatically reduced AD risk in the elderly, including delayed disease onset, reduced symptomatic severity and slowed cognitive decline. (Veld et al., “Nonsteroidal anti-inflammatory drugs and the risk of Alzheimer's disease,” N. Engl. J. Med (2001) 345, 1515-1521; Etminan et a, “Effect of non-steroidal anti-inflammatory drugs on risk of Alzheimer's disease: systematic review and meta-analysis of observational studies,” Brit. Med. Journal (2003) 327, 1-5; Imbimbo, 2010). Three mechanisms have been proposed for how NSAIDs inhibit the processes that contribute to AD progression: i) by inhibiting COX activity to reduce or prevent microglial activation and cytokine production in the brain (Mackenzie, et al., “Nonsteroidal anti-inflammatory drug use and Alzheimer-type pathology in aging,” Neurology (1998) 50, 986-990; Alafuzoff et al., “Lower counts of astroglia and activated microglia in patients with Alzheimer's disease with regular use of non-steroidal anti-inflammatory drugs,” J. Alz. Dis. (2000) 2, 37-46; Yan, 2003; Gasparini, 2004; Imbimbo, 2010); ii) by reducing amyloid deposition (Weggen et al., “A subset of NSAIDs lower amyloidogenic Abeta42 independently of cyclooxygenase activity,” Nature (2001) 414, 212-216; Yan, 2003; Imbimbo, 2010); or iii) by blocking COX-mediated prostaglandin E2 responses in synapses (Kotilinek et al., “Cyclooxygenase-2 inhibition improves amyloid-β-mediated suppression of memory and synaptic plasticity,” Brain (2008) 131, 651-664.
Therefore, NSAIDs are predicted to dampen the neuro-inflammatory response and impact AD progression via several mechanisms. When administered together with drugs that inhibit Aβ oligomerization, the combination treatment paradigm is proposed to attenuate the multiple triggers leading to neurodegeneration and neuronal death. The decline in cognitive performance may be reversed, due to neuronal plasticity and neurogenesis in the hippocampus (Kohman et al., “Neurogenesis, inflammation and behavior,” Brain, Behavior, and Immunity (2013) 27, 22-32), if AD progression is arrested at a very early stage.
The present disclosure relates to a composition comprising, consisting essentially of, or consisting of cromolyn sodium, α-lactose, and salt of a fatty acid, wherein the cromolyn sodium, α-lactose, and salt of a fatty acid are micronized, and wherein the α-lactose has a particle size distribution of D90 of 45-70 μm, D50 of 10-35 μm, and D10 of 2-13 μm.
The present disclosure relates to a method of treating a disorder selected from Alzheimer's disease, amyloidosis-associated condition (AAC), traumatic brain injury, Huntington's disease, atherosclerosis, cytokine release syndrome (CRS), dementia, head injury, infection, neuroinflammation, prion disease, stroke, amyotrophic lateral sclerosis (ALS), Parkinson's disease, and asthma in a subject in need thereof comprising administering a composition comprising, consisting essentially of, or consisting of cromolyn sodium, α-lactose, and salt of a fatty acid, wherein the cromolyn sodium, α-lactose, and salt of a fatty acid are micronized, and wherein the α-lactose has a particle size distribution of D90 of 45-70 μm, D50 of 10-35 μm, and D10 of 2-13 μm.
The present disclosure relates to compositions for inhalation delivery. The present disclosure combines powdered forms of at least two excipients and an active ingredient for administration via inhalation. The composition can be used in formulations to enable enhanced delivery of the active ingredient into the deep lung regions, thereby increasing the bioavailability of the active ingredient in the plasma as well as uptake through the blood-brain barrier for treatment of neurological diseases. The presently disclosed compositions are capable of reaching the levels of bioavailability of the active ingredient in the plasma sufficient for neurological treatment, while other existing formulations of the active ingredient are designed to only treat the respiratory tract.
The present disclosure also relates to compositions for a dosage form via inhalation comprising the following components: cromolyn sodium, α-lactose, and a magnesium salt. Preferably, the magnesium salt is magnesium stearate. Not to be limited by theory, but it is believed that during blending, the α-lactose is shaped into a rounded form by shearing forces of the mixing, as well as by the adherence of the magnesium salt to the flat regions and crevices of the α-lactose particles. It is believed that there is greater adherence between α-lactose and the magnesium salt thereby coating the α-lactose, which in turn reduces the adhesive/cohesive forces between the carrier and the active ingredient, and between the particles of the active ingredient, allowing for easy release of the cromolyn during inhalation. This greater adherence, rounded particle shape, and smaller size of the α-lactose particles contribute to depositing the cromolyn deeper into the lung region thereby providing an effective dose with less cromolyn in the drug product form.
In particular, the present disclosure is applicable for patients with diseases that impair mental performance, such as Alzheimer's disease, thereby ensuring effective dose delivery with minimal effort of inhalation. Because of its versatility, the composition and formulation may also be used to treat other diseases including, but not limited to, stroke, amyotrophic lateral sclerosis (ALS), Parkinson's disease, and asthma.
One application of the present disclosure is a composition of cromolyn sodium and α-lactose each in powdered form suitable for inhalation as a combination dosage form. In this case, each ingredient is in powdered form to facilitate administration via inhalation and to enable easy and accurate dosing. The present disclosure is based in part upon the discovery that when cromolyn sodium and α-lactose are both in powdered form, α-lactose improves the aerodynamic flow of micronized cromolyn. This improvement allows for a higher concentration of cromolyn to reach deeper within the patient's lungs, thereby achieving the same therapeutic effect with less drug. Another advantage is that a perfect dosage via inhalation may not be necessary to achieve adequate therapeutic effect. Yet, another advantage is that the presence of α-lactose helps mask the bitter taste of cromolyn, thereby making administration pleasant. In patients with impaired physical abilities (which may be due to a disease such as Alzheimer's disease), a perfect inhalation (a perfect “puff”) may not always be possible; with the present disclosure, even impaired inhalation (an imperfect “puff”) will deliver sufficient drug dosage to treat the desired disease. The advantages of the present composition can be applied to other diseases with similar problems and expand the list of indications where the improved dosage form may be applicable.
In one application, the co-administration of the composition of cromolyn sodium, α-lactose, and a metallic salt of a fatty acid can be used for the treatment of certain neurological diseases. The neurological diseases include, but are not limited to, AD, ALS, Parkinson's disease, and the effects from stroke.
The α-lactose used in the composition for the formulation is in form that is suitable for inhalation. In particular, the α-lactose particles are smoothed and rounded to allow for better carrier properties. The α-lactose particles are larger than the particle they carry, thus a larger particle distribution is mostly of larger particles. The smoother surfaces and edges prevent the API from being trapped in the carrier particle. Another prerequisite is that the α-lactose combines well with cromolyn sodium in order to enhance the delivery of cromolyn sodium via inhalation. In particular, the combination should deliver cromolyn sodium to the deep parts of the lung, e.g., DPI 4moc (stage 4 to MOC, representing the area of the lung consisting of the secondary bronchi to the alveoli).
α-Lactose was characterized to determine the parameters necessary to administer a therapeutically effective amount using an inhalation delivery system. The methodology included particle size determination (PSD); powdered x-ray crystallization diffraction (PXRD); and gravimetric vapor sorption (GVS).
The present disclosure relates to formulations wherein the α-lactose has a particle size distribution of D90 of 45-70 μm, D50 of 10-35 μm, and D10 of 3-13 μm, preferably D90 of 50-65 μm, D50 of 15-30 μm, and D10 of 5-10 μm, and more preferably D90 of 50-60 μm, D50 of 20-25 μm, and D10 of 3-6 μm.
Cromolyn used in the composition formulation may primarily be manufactured for inhalation. Generally, the cromolyn is micronized. The present disclosure relates to a composition having cromolyn, where the cromolyn has a size parameter of about <10 μm; however, particle size may also include <5 μm. The cromolyn micronization produces an ultra-fine powder (d<10 μm) of small particle size. Micronized cromolyn typically has a specification of D90≤5 μm.
The formulation also comprises a lubricant/stabilizer, which may be any pharmaceutically acceptable metallic salts of fatty acids such as stearic acid and its metallic salts. Acceptable stearic acids include, but are not limited to, magnesium stearate, calcium stearate, zinc stearate. A preferred stearic acid is magnesium stearate. The magnesium salt is micronized in a manner to create sufficiently small particles to work as a lubricant in conjunction with the carrier, lactose monohydrate to minimize agglomeration and improve carrier performance by reducing adhesion/cohesive forces between the carrier and cromolyn. Another advantage of using micronized magnesium salt is improved mixing and flow of the blend during encapsulation.
The present disclosure also relates to a composition of cromolyn sodium, α-lactose and magnesium stearate for delivery via inhalation. This composition comprises micronized cromolyn sodium, micronized α-lactose and magnesium stearate, wherein the α-lactose is prepared for inhalation and preferably has a particle size as mentioned above.
The composition improves the delivery of cromolyn, for example as compared to cromolyn only compositions or where cromolyn is delivered in sequence (not simultaneously) with α-lactose. For instance, the inhaled formulation of cromolyn only can deliver a therapeutically effective amount of cromolyn to the deep lung of about 23% to about 29% of the dosed amount. In contrast, it was found that the composition of the present disclosure delivered a therapeutically effective amount of cromolyn in a range of about 34% to about 53% and preferably 35% to about 44% of the dosed amount.
The compositions of the disclosure comprise about 45-65% by weight of cromolyn sodium, about 30-50% by weight of α-lactose, and about 1-5% by weight of magnesium stearate. A preferred composition comprises about 50-60% by weight of cromolyn sodium, about 35-45% by weight of α-lactose, and about 1-3% by weight of magnesium stearate. More preferably, the composition comprises about 58% by weight of cromolyn sodium, about 40% by weight of α-lactose, and about 2% by weight of magnesium stearate. As used herein, unless otherwise indicated, the term “cromolyn” includes cromolyn, cromolyn sodium, and other forms of pharmaceutically acceptable salts of cromolyn.
Typically, the weight ratio of cromolyn sodium to α-lactose is about 1.7:1.12 to about 1.7:1.28, preferably, from about 1.7:1.34 to about 1.7:28, and more preferably from about 1.7:1.28.
The formulation includes a salt of fatty acid as a pharmaceutical lubricant, such as magnesium stearate. Typically, the weight ratio of cromolyn sodium to magnesium stearate is about 1.7:0.057 to about 1.7:0.06, preferably, from about 1.7:0.064 to about 1.7:0.6, and more preferably from about 1.7:0.06.
The formulations using micronized cromolyn, α-lactose, and a salt of fatty acid as a pharmaceutical lubricant provided improved performance of an inhaled substance when compared to the cromolyn only formulation. The formulated product batches had a comparable emitted dose as the six clinical batches produced of the cromolyn only product. The delivery of cromolyn alone resulted in the mean of 1.98% of the product reaching the deep lung area based on the NGI test results summation of Stage 4-MOC, whereas with combination of cromolyn, α-lactose, and magnesium stearate had a mean result of 39.5% of the inhaled cromolyn reaching the deep lung area. Therefore, the compositions of the present disclosure include cromolyn, α-lactose, and magnesium stearate composition having a mean result of 34% to 44.3% of the inhaled cromolyn reaching the deep lung area. As used herein, unless otherwise defined, the term “lung area” refers to Stage 4—MOC.
As illustrated in the data of Table 1, formulations of the present disclosure have a cromolyn percent emitted dose from 34% to 44% in the deep lung regions in comparison to a cromolyn only formulation having only 1.98% of emitted dose. Further, the compositions of the present disclosure deposited from 5.3 to 6.5 mg of cromolyn in stage 4-MOC.
Particle size distribution of the components of the tested formulation are shown in Tables 2, 3, and 4:
During respiration of particles, particles <3 μm in size will deposit in the lower regions of the lung which are then adsorbed. Table 1 demonstrates formulation performance and demonstrates that a larger amount of API reached the lower lung, compared to cromolyn alone. Based on the particle distribution of the cromolyn (D90≤5 μm), most batches had a particle distribution for D90 that ranged from ≤5 μm to ≥3.5 μm. If such particles were inhaled without the α-lactose and magnesium stearate of the disclosure, cromolyn would deposit mostly in the oropharynx and upper respiratory tract, and would thus be less effective. It is believed that the ultrafine particles <3 μm size may be exhaled before contact with lung tissue. Also, these particles make up only a fraction of the dose. It is imperative to have the particles in the range of 5 μm to 3 μm in the lower regions of the lung for adsorption as they make up 90% of the API in the mixture.
Comparison experiments using inhalers Spinhaler® and Cyclohaler® delivering composition consisting of cromolyn and lactose (Tables 5-7) demonstrate significantly lower ranges of the emitted dose (60% to 78%), compared to the data presented in Table 1 (Gilani et al, “Influence of formulation variables and inhalation device on the deposition profiles of cromolyn sodium dry powder aerosols,” DARU J. Pharm. Sci. (2004) 12(3), 123-130).
The formulations of the disclosure may include additional pharmaceutically acceptable excipients. Pharmaceutically acceptable excipients for dry powdered inhalers include, but are not limited to, lactose monohydrate and magnesium stearate.
The present disclosure relates to methods of making the described compositions comprising α-lactose (inhalation grade); micronizing cromolyn; and micronizing magnesium stearate. It is understood that we shall refer to magnesium stearate however other pharmaceutical lubricants suitable for inhalation are equally applicable. The method of making the formulation of the present disclosure relates to α-lactose; micronizing cromolyn; and micronizing magnesium stearate. The blending may use a layering principle to ensure the even distribution of components. In some embodiments, cromolyn is dispensed in three equal parts. A method of making the formulation comprises placing a first part of cromolyn with a layer of magnesium stearate, adding a second part of cromolyn with a layer of lactose, and adding a third part of cromolyn to the layered mixture. Thereafter, the layered mixture is mixed. An alternative method of making the formulation of the present disclosure relates to first mixing lactose with magnesium stearate, dividing the blended lactose/magnesium stearate blend into three equal parts, separately mixing each part of the blend with a third part of cromolyn, layering each part of the cromolyn, lactose/magnesium stearate blend, and repeating the layering step two more times, mixing the layered mixture for 5 to 10 minutes but not more than 15 min with a high sheer blender at 500±2 rpm to yield a blend uniformity of 90-110% label claim.
Each component can be micronized using standard equipment commonly used in the pharmaceutical arts.
The present disclosure relates to a composition comprising cromolyn sodium, α-lactose, and salt of a fatty acid, wherein the cromolyn sodium, α-lactose, and salt of a fatty acid are micronized, and wherein the α-lactose has a particle size distribution of D90 of 45-70 μm, D50 of 10-35 μm, and D10 of 2-13 μm.
In some embodiments, the salt of a fatty acid is selected from magnesium stearate, calcium stearate, and zinc stearate, for example, magnesium stearate.
In certain embodiments, the α-lactose is in a form of particles.
In some embodiments α-lactose particles are spheres or spheroids.
In certain embodiments, α-lactose has a particle size distribution of D90 of 50-65 μm, D50 of 15-30 μm, and D10 of 5-10 μm, for example, particle size distribution of D90 of 50-60 μm, D50 of 20-25 μm, and D10 of 3-6 μm.
In some embodiments, cromolyn sodium has a particle size distribution of D90≤5 μm, for example, particle size distribution range of D90≤5 μm to ≥3.5 μm.
In certain embodiments, the composition comprises about 45-65% by weight of cromolyn sodium, about 30-50% by weight of α-lactose, and about 1-5% by weight of magnesium stearate, for example, the composition comprises about 50-60% by weight of cromolyn sodium, about 35-45% by weight of α-lactose, and about 1-3% by weight of magnesium stearate, such as about 58% by weight of cromolyn sodium, about 40% by weight of α-lactose, and about 2% by weight of magnesium stearate.
In some embodiments, the composition comprises about 17.1 mg of cromolyn sodium.
The present disclosure relates to a method of treating a disorder selected from Alzheimer's disease, amyloidosis-associated condition (A A C), traumatic brain injury, Huntington's disease, atherosclerosis, cytokine release syndrome (CRS), dementia, head injury, infection, neuroinflammation, prion disease, stroke, amyotrophic lateral sclerosis (ALS), Parkinson's disease, and asthma in a subject in need thereof. For example, the disorder is Alzheimer's disease. Alternatively, the disorder is amyloidosis-associated condition (AAC). Alternatively yet, the disorder is traumatic brain injury.
In certain embodiments, the disorder is Huntington's disease. Alternatively, the disorder is atherosclerosis. Alternatively yet, the disorder is CRS.
In some embodiments, the disorder is dementia. Alternatively, the disorder is head injury. Alternatively yet, the disorder is infection.
In certain embodiments, the disorder is neuroinflammation. Alternatively, the disorder is prion disease. Alternatively yet, the disorder is stroke.
In some embodiments, the disorder is ALS. Alternatively, the disorder is Parkinson's disease. Alternatively yet, the disorder is asthma.
In some embodiments, the composition is administered by oral inhalation.
All publications and patents mentioned herein are hereby incorporated by reference in their entirety as if each individual publication or patent was specifically and individually indicated to be incorporated by reference. In case of conflict, the present application, including any definitions herein, will control.
While specific embodiments of the subject invention have been discussed, the above specification is illustrative and not restrictive. Many variations of the invention will become apparent to those skilled in the art upon review of this specification and the claims below. The full scope of the invention should be determined by reference to the claims, along with their full scope of equivalents, and the specification, along with such variations.
Cromolyn sodium (1,160 g) was divided into three parts. Part 1 (381.5 g); Part 2 399.8 g) and Part 3 (379.5 g). Part 1 was placed into a shear batch mixer 10 L TRV mixing bowl. Magnesium stearate (40 g) was sprinkled onto Part 1 cromolyn sodium in the bowl. Part 2 cromolyn sodium was added to the bowl, followed by layering of lactose monohydrate (800 g). Part 3 cromolyn sodium was added to the top of the lactose monohydrate layer and the bowl was closed. The mixture was mixed for 15 minutes at 500 rpm to obtain a 2 kg batch formulation.
Formulation Preparation
The blend of cromolyn sodium (58% by weight), α-lactose (58% by weight), and magnesium stearate (2% by weight) was encapsulated in size 3 HPMC capsules, each containing 32 mg of a blend containing a 17.1 mg cromolyn sodium.
Emitted Dose Measurements
For the emitted dose analysis, a single capsule containing the cromolyn sodium, α-lactose, and magnesium stearate formulation was placed in the inhaler device and pierced. The Plasti ape RS01 dry powder inhaler (DPI) was loaded into the mouthpiece adapter and then into the induction port of the Copley TPK Flow Controller. The flow controller was set for a flow rate of 80±0.5 L/s for a 3 second pulse. Once the device was loaded into the flow controller, the flow controller was activated delivering the dose. The emitted powder was collected into a sample tube for HPLC analysis, determining the amount of product released from the capsule and device. The results of the measurements are shown in Table 2.
Particle Size Distribution Measurements
Aerodynamic particle size distribution analysis was performed using a Next Generation Impactor (NGI). A capsule containing the cromolyn sodium, α-lactose, and magnesium stearate formulation was loaded into the Plastiape RS01 DPI and pierced prior to loading onto the Copley flow controller. The controller was set for a flow rate of 80±0.5 L/s for a 3 second pulse. The NGI was setup for the test where a coating solution of 3% v/v glycerol, 0.1% w/v Lutrol F-68 in acetone was placed in each NGI stage cup (1 through 7 plus a Micro-orifice collector (MOC)). The loaded inhaler device was inserted into the mouthpiece adapter, and the assembly was inserted into the induction port of the flow controller. The flow controller was activated for 3 seconds and upon completion samples were collected from the device, throat and mouth piece adapter, pre-separator on the NGI, and each stage cup on the NGI. A diluent was used to rinse the surface of each device into a sample tube for HPLC analysis. Following analysis of each sample, the amount of product capture was determined. The FPM (Fine Particle Mass) is the sum in (mg) of the NGI cups representing stage 3 through MOC. The results of the measurements are shown in Table 8.
This application claims priority to U.S. Provisional Patent Application No. 62/692,962, filed Jul. 2, 2018, the contents of which are incorporated herein by reference in their entirety.
| Number | Date | Country | |
|---|---|---|---|
| 62692962 | Jul 2018 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | PCT/US19/40247 | Jul 2019 | US |
| Child | 16585871 | US |
