Luke I Chambers1, Osama M Musa2, Jonathan W Steed1. 1. Department of Chemistry, Durham University, Lower Mountjoy, Stockton Road, Durham DH1 3LE, U.K. 2. Ashland LLC, 1005 Route 202/206, Bridgewater, New Jersey 08807, United States.
Abstract
The effectiveness of a partial least squares-discriminant analysis coamorphous prediction model was tested using coamorphous screening data for a promising coamorphous former, the dimer of N-vinyl(caprolactam) (bisVCap) with a range of active pharmaceutical ingredients. The prediction model predicted 71% of the systems correctly. An experimental coamorphous screen was performed with this coformer with 13 different active pharmaceutical ingredients, and the results were compared to the predictions from the model. A total of 85% of the systems were correctly predicted. Stability assessments of three coamorphous systems showed that the prediction model score did not strongly correlate with the stability of the coamorphous material. The model performed well with small-molecule coformers, such as bisVCap, despite the difference in structure and properties compared to the amino-acid-based model training set.
The effectiveness of a partial least squares-discriminant analysis coamorphous prediction model was tested using coamorphous screening data for a promising coamorphous former, the dimer of N-vinyl(caprolactam) (bisVCap) with a range of active pharmaceutical ingredients. The prediction model predicted 71% of the systems correctly. An experimental coamorphous screen was performed with this coformer with 13 different active pharmaceutical ingredients, and the results were compared to the predictions from the model. A total of 85% of the systems were correctly predicted. Stability assessments of three coamorphous systems showed that the prediction model score did not strongly correlate with the stability of the coamorphous material. The model performed well with small-molecule coformers, such as bisVCap, despite the difference in structure and properties compared to the amino-acid-based model training set.
Entities:
Keywords:
active pharmaceutical ingredients; bislactams; coamorphous; partial least squares-discriminant analysis; physical stability; predictive modeling
The term coamorphous
(COAM) system was first introduced by Rades
and co-workers in 2009 based on an amorphous material comprising a
mixture of ranitidine hydrochloride and indomethacin, which was initially
described as a “comilled amorphous sample”.[1] A COAM material is defined as a mixture of multiple
low-molecular-weight components in a single-phase homogeneous amorphous
system.[2−6] The main research interest for COAM systems is for pharmaceutical
products; therefore, at least one of the components is usually an
active pharmaceutical ingredient (API) and the other is either an
inactive coformer or another API.[3,7,8] COAM materials are of interest to the pharmaceutical
industry due to the increased stability of COAM systems compared to
the amorphous solids while retaining the dissolution advantage of
an amorphous form.[9−11] The COAM systems also help overcome some of the key
issues of polymeric amorphous solid dispersions (PASDs), including
the hygroscopicity and large ratio of polymers required to stabilize
the API.[12−14]The stabilization mechanisms of COAM systems
include elevated Tg compared to the pure
drug, molecular-level
mixing, and intermolecular interactions.[15−18] COAM systems have been shown
to be stable for long periods of time after preparation even at increased
temperatures and humidities.[19,20] COAM systems are known
to increase the solubility of a crystalline API in a similar way to
cocrystals by the “spring and parachute” effect.[5,21] However, in some cases, the dissolution rate of the COAM system
can be too fast, causing the solution to become supersaturated, which
results in the API crystallizing.[22,23]Previously,
we have designed a partial least squares-discriminant
analysis (PLS-DA) model using a data set of amino acids with six APIs
to predict COAM formation.[24] The model
identifies key parameters, including average molecular weight, the
sum of the difference between hydrogen bond donors and acceptors for
both components, the excess enthalpy of mixing and of hydrogen bonding,
and the difference in the Hansen parameter for hydrogen bonding. In
the present work, this model has been applied to a new data set based
on a non-amino acid coformer, bisvinylcaprolactam (bisVCap), and applied
predictively[24,25] in the formation of new COAM
materials based on this promising coformer, which we have previously
shown stabilizes a range of APIs in the COAM state.[26]BisVCap is the unsaturated dimer of vinylcaprolactam
and contains
two highly polar lactam carbonyl groups which act as hydrogen bond
acceptor sites.[26−29] BisVCap is structurally similar to the polymer polyvinylpyrrolidone
(PVP), which contains five-membered rings as opposed to bisVCap’s
seven-membered rings. One use of PVP is in the formation of PASDs
where it stabilizes a range of APIs in an amorphous state.[30−35] BisVCap is significantly less hygroscopic compared to PVP, with
a dynamic vapor sorption (DVS) study showing that amorphous bisVCap
displays a mass increase of 1.2% when at 90% relative humidity compared
to a 40% mass increase for PVP at 80% relative humidity.[26]In this work, the reliability of the prediction
model based on
amino acid coformers was tested with bisVCap by applying the model
to our previous COAM screening results and then using the model to
predict COAM formation in further experimental systems.[24,26] Fourier transform infrared spectroscopy (FTIR) was used to analyze
the potential interactions between bisVCap and each API to understand
the nature of the stabilization. A stability study of three of the
resulting COAM systems was performed at two different temperatures
to determine if the location of the combination in the PLS-DA prediction
space correlates with the stability of the system. The representative
COAM system formed from bisVCap furosemide was studied further to
test its tolerance to increased drug loading and humidity.
Experimental
Section
Materials
Piroxicam was purchased from Alfa Aesar (Massachusetts,
USA). Aspirin, chloramphenicol, chlorpropamide, indomethacin, ketoprofen, n-vinyl caprolactam, paracetamol, phenobarbital, and trifluoroacetic
acid were purchased from Merck (Massachusetts, USA). Hexane and acetone
were purchased from Thermo Fisher Scientific (Massachusetts, USA).
Famotidine was purchased from Tokyo Chemical Industry (Tokyo, Japan).
Flurbiprofen, furosemide, mebendazole, and simvastatin were purchased
from Fluorochem (Derbyshire, UK). All chemicals were used without
further purification.
Analytical Methods
IR spectra were
measured with a
PerkinElmer 100 FT-IR spectrometer with an μATR attachment.
Data was recorded at a resolution of 4 cm–1 for
8 scans over a range of 4000–550 cm–1. X-ray
powder diffraction (XRPD) measurements were performed using an X’Pert
PANalytical PRO X-ray diffractometer (PANalytical, Almelo, The Netherlands)
or a Bruker D8 with Cu Kα radiation (1.54187 Å), acceleration
voltage and current of 45 kV and 40 mA, respectively. The samples
were scanned in the reflectance mode between 2 and 35° 2θ
with a scan rate of 0.067335° 2θ/s and a step size of 0.0262606°.
The data was collected and analyzed using the software X’Pert
Data Collector (PANalytical, Almelo, The Netherlands). 1H and {1H}13C solution NMR spectra were recorded
using a Varian Mercury-400 spectrometer, operating at 400 MHz for 1H and 100 MHz for 13C, chemical shifts are reported
in ppm (δ) and referenced to residual protic solvent. Elemental
analysis was performed by the University of Durham service using an
Exeter CE-440 elemental analyzer. Electrospray mass spectrometry was
recorded using a TQD mass spectrometer and an Acquity ultra-performance
liquid chromatography. The Acquity photodiode array detector provides
absorbance data from 210 to 400 nm. The sample is dissolved in methanol
at 1 mg/mL. Hot stage microscopy (HSM) was performed using an Olympus
XC50 microscope with a Linkam LTS420 heating stage. Samples were placed
onto a glass microscope slide and covered with a thin glass cover
slide. Differential scanning calorimetry thermograms were recorded
using a PerkinElmer 8500 calorimeter or a PerkinElmer DSC 4000 analyzer,
calibrated using an indium standard, with samples accurately weighed
(±0.5 mg) into standard aluminum pans. The heating rate was 10
°C min–1.
COSMOquick Calculations
COSMOquick version 1.7 (COSMOlogic
GmbH & Co. KG, Leverkusen, Germany) was used to calculate the
excess enthalpy of mixing (ΔHmix) and excess enthalpy of hydrogen bonding (ΔHhb), of the two-component system. For each component,
the following variables were calculated μ, the pseudo-chemical
potential of the pure solute and δh, the Hansen
parameter for hydrogen bonding. The difference between the API and
coformer values were calculated and used as the variables in the PLS-DA.
Synthesis of BisVCap
N-Vinyl caprolactam
(30.0 g, 216 mmol) was added to hexane (150 cm3) in a two-necked
flask with a reflux condenser under nitrogen. The sample was heated
to 50 °C to dissolve the N-vinyl caprolactam.
Trifluoroacetic acid (0.75 cm3) was added, and the reaction
mixture was heated to 60 °C for 2 h. A white precipitate appeared
during the reaction. The solid was removed via vacuum filtration and
washed with hexane (3 × 20 mL). The white precipitate was recrystallized
twice from acetone to give a white powder. Yield 10.05 g, 36.1 mmol,
33%. Elemental analysis expected for C16H26N2O2: C, 69.03; H, 9.41; and N, 10.06. Found: C,
69.10; H, 9.39; and N, 9.99. The analysis is in agreement with published
works.[29]1H NMR (400 MHz, CDCl3): δ 7.26 (dd, J = 14.9, 1.7 Hz, 1H,
vinyl NCH), 5.43 (qdd, J = 6.9, 5.0, 1.7 Hz, 1H,
NCH), 5.01 (dd, J = 14.9, 5.0 Hz, 1H, vinyl CH),
3.60–3.54 (m, 2H, CH2), 3.32–3.12 (m, 2H,
CH2), 2.68–2.62 (m, 2H, CH2), 2.59–2.48
(m, 2H, CH2), 1.84–1.47 (m, 12H, CH2),
1.27 (d, J = 6.9 Hz, 3H, CH3). 13C NMR (101 MHz, CDCl3): δ 175.60, 174.33, 128.13,
110.28, 48.65, 45.32, 43.21, 37.51, 37.17, 30.52, 30.02, 29.54, 29.40,
27.25, 23.41, 16.78. 13C{1H} SS NMR (101 MHz):
δ 174.4, 129.2, 110.1, 50.6, 42.5, 36.4, 31.8, 30.0, 28.3, 25.6,
25.0, 22.3. IR ν = 1667 (C=C), 1641 (C=O), 1622
(C=O) cm–1. MS (ESI) m/z: 278 (M+), mp 145 °C.
HSM Method
for COAM Systems
BisVCap and each API were
individually heated at 20 °C min–1. After the
sample was fully melted, it was removed from the HSM and placed on
a freezer block to flash cool the sample and prevent crystallization
on cooling. The samples were monitored after 24 h using an optical
microscope with a polarizer to determine if crystallization had occurred.
The same process was repeated using a 1:1 molar ratio of bisVCap and
API.
Comelting for COAM Systems
A 1:1 molar ratio of bisVCap
and API was heated in a vial to a few degrees above the highest melting
point out of the API or bisVCap (mp 145 °C). The mixture was
held at this temperature for 10 min and then, it was rapidly cooled
by submerging the vial into dry ice and acetone. The mixtures were
then analyzed via XRPD and FTIR to check if the sample was amorphous.
Rapid Solvent Evaporation for COAM Systems
The chosen
ratio of bisVCap and API was dissolved in the minimum amount of acetone.
The solvent was rapidly removed under reduced pressure on a water
bath at 60 °C. The mixtures were then analyzed via XRPD and FTIR
to check if the sample was amorphous.
Stability Test at Different
Temperatures
COAM samples
of bisVCap with indomethacin, paracetamol, and simvastatin in a 1:1
molar ratio were produced by rapid solvent evaporation (RSE). The
samples were either stored at ∼20 or 3 °C. The samples
were characterized by XRPD and FTIR after 1 and 2 weeks.
Varying Humidity
Stability Test
A COAM sample of bisVCap
and furosemide in a 1:1 molar ratio was produced via RSE. Five 50
mg samples were placed in a vial and stored in five different humidity
environments including 0, 11, 33, 75, and 100% RH using relevant saturated
salt solutions. The samples were analyzed by XRPD and FTIR after 7
and 28 days.
Results and Discussion
Testing the Model against
Previous COAM Screening Data
The results of the COAM screen
of bisVCap with a range of APIs previously
published by Goodwin et al.[26] were analyzed
using the amino acid-based PLS-DA COAM formation prediction model
to investigate the effectiveness of the model with bisVCap coformers.[24] The COAM data involved 12 bisVCap API systems
produced by comelting (CM) the two components and then cooling to
room temperature. Three of the APIs used (ibuprofen, tolfenamic acid,
and ethionamide) decompose on melting; therefore, these systems were
removed from this study. Mexiletine and metformin were also removed
from the study because they are hydrochloride salts, and the prediction
model has not been designed to consider ionic compounds. From the
remaining seven systems, the experimental results showed that three
form COAM systems while the other four do not (Table ).
Table 1
Results of an Experimental
COAM Screen
from Goodwin et al.[26] Compared to the Predicted
Result Using the Prediction Model from Chambers et al.[24]
API
label
experimental COAM
predicted
COAM
correctly predicted
benzocaine
BENZ
N
N
Y
caffeine
CAFF
N
N
Y
carbamazepine
CARB
Y
N
N
carisoprodol
CARI
Y
N
N
dopamine
DOPA
N
N
Y
isoniazid
ISON
N
N
Y
valsartan
VALS
Y
Y
Y
The score plot visually represents how close each
system is to
the predicted crossover line between COAM and non-COAM systems (Figure ). The model correctly
predicts 71% of this sample set with a Fisher’s probability
of 0.43.[36] The two systems incorrectly
predicted are carbamazepine and carisoprodol, which were experimentally
COAM but are predicted not to be COAM. The FTIR spectrum of the COAM
systems of bisVCap with carbamazepine and carisoprodol suggests reduced
hydrogen bonding strength to the API carbonyl group indicating the
formation of an amorphous state because the carbonyl peaks shift to
a higher wavenumber compared to the crystalline API. However, the
bisVCap carbonyl peaks broaden but do not shift to a lower wavenumber,
indicating the bisVCap carbonyl groups are not forming new hydrogen
bonds with the API.[26] The incorrect prediction
of carbamazepine and carisoprodol could therefore indicate the model
is based around the potential formation of stabilizing intermolecular
bonds between the two components, which are not present in this case.
Figure 1
PLS-DA
score scatter plot of latent variables (LV) 1 and 2. The
color of the markers displays the results of the previous experimental
screen[26] with red markers indicating not
COAM systems and green markers indicating COAM systems. Samples incorrectly
predicted by the prediction model are shown as hollow circles.[24] The blue dashed line shows the predicted separation
line between COAM and not COAM systems based on the PLS-DA calculation
for visualization purposes.
PLS-DA
score scatter plot of latent variables (LV) 1 and 2. The
color of the markers displays the results of the previous experimental
screen[26] with red markers indicating not
COAM systems and green markers indicating COAM systems. Samples incorrectly
predicted by the prediction model are shown as hollow circles.[24] The blue dashed line shows the predicted separation
line between COAM and not COAM systems based on the PLS-DA calculation
for visualization purposes.
COAM Systems Based on Unknown BisVCap API Combinations
To
determine the broader applicability of the PLS-DA model a range
of 13 additional APIs were selected based on a range of chemical functionality
and paired with bisVCap. The PLS-DA prediction model predicts that
10 out of these 13 combinations should form a coamorphous phase (Table ). To test these predictions,
bisVCap was mixed in a 1:1 molar ratio with each API and melt quenched
using HSM. The mixtures were monitored for signs of recrystallization
after 24 h using an optical microscope after storage at ambient conditions
(Table S1). The HSM screen showed that
bisVCap by itself recrystallizes on cooling; however, when mixed with
any of the APIs no recrystallization occurs, showing these 13 APIs
prevent bisVCap crystallization. Pure famotidine, furosemide, mebendazole,
and piroxicam all undergo decomposition when heated to near their
melting point. Similar decomposition occurs for the 1:1 mixtures of
bisVCap with famotidine, mebendazole, and piroxicam; however, the
furosemide mixture with bisVCap appears to remain amorphous and minimal
decomposition occurs on melting. Pure aspirin, chlorpropamide, flurbiprofen,
paracetamol, and phenobarbital begin to recrystallize after 24 h;
however, the mixtures with bisVCap remain amorphous, suggesting bisVCap
can stabilize the systems in an amorphous state. Pure chloramphenicol,
indomethacin, ketoprofen, and simvastatin remain amorphous after 24
h, and mixtures of these APIs with bisVCap are also amorphous suggesting
the interactions between API and bisVCap are preventing the bisVCap
from recrystallizing.
Table 2
Predictions and Experimental
Results
of the COAM Screen of 13 APIs with bisVCapa
API
label
prediction (COAM
value)
HSM
DSC (Tg/°C)
CM XRPD
RSE XRPD
correctly predicted
aspirin
ASPR
Y (0.864)
Y
Y (−19)
Y
Y
Y
chloramphenicol
CHPL
Y (0.682)
Y
Y (31)
Y
Y
Y
chlorpropamide
CHPD
Y (0.500)
Y
Y (−4)
Y
Y
Y
famotidine
FAMO
N (0.463)
D
D
D
N
Y
flurbiprofen
FLURB
Y (1.096)
Y
Y (−5)
Y
Y
Y
furosemide
FUR
Y (1.091)
Y
Y (35)
Y
Y
Y
indomethacin
INDO
Y (1.142)
Y
Y (16)
Y
Y
Y
ketoprofen
KETO
Y (0.833)
Y
Y (−5)
Y
Y
Y
mebendazole
MEB
Y (0.556)
D
D
D
N
N
paracetamol
PARA
N (0.450)
Y
Y (19)
Y
Y
N
phenobarbital
PHB
Y (0.588)
Y
Y (28)
Y
Y
Y
piroxicam
PIRO
N (0.443)
D
D
D
N
Y
simvastatin
SIM
Y (0.751)
Y
Y (12.5)
Y
Y
Y
The prediction
includes the predicted
COAM value. The experimental COAM screen includes the results from
initial HSM screening, the Tg from DSC,
and the XRPD analysis of both CM and rapid sovlent evaporation (RSE)
samples. Y indicates the samples were COAM, N indicates the samples
were not COAM, and D indicates the samples decomposed. The predicted
result was also compared with the experimental results to determine
if the prediction was correct.
The prediction
includes the predicted
COAM value. The experimental COAM screen includes the results from
initial HSM screening, the Tg from DSC,
and the XRPD analysis of both CM and rapid sovlent evaporation (RSE)
samples. Y indicates the samples were COAM, N indicates the samples
were not COAM, and D indicates the samples decomposed. The predicted
result was also compared with the experimental results to determine
if the prediction was correct.The combination of bisVCap and the 13 APIs was investigated using
both CM and rapid solvent evaporation (RSE) to allow further analysis
by XRPD and FTIR (Figure S3, Table ). The two methods CM and RSE
were selected to help cover a larger experimental space and to remove
any issues caused by the decomposition of samples during CM or difficulty
dissolving the samples in some solvents for RSE. Ball milling was
not used because bisVCap has a low glass transition temperature (Tg) and milling above the Tg usually leads to polymorphic transformation instead of amorphization.[37,38] The XRPD patterns (Figure S2, Table ) for the RSE samples
show the same results as observed in the HSM screen with the 10 systems
that did not decompose producing COAM systems using both CM and RSE.
The three systems that decomposed via HSM (famotidine, mebendazole,
and piroxicam) did not produce a COAM system by RSE.The 10
systems found to be amorphous by HSM and XRPD were analyzed
as physical mixtures, produced by gently grinding the two components
together with a spatula, by DSC to determine the Tg and check for decomposition (Figure S1, Table ).
All of the DSC traces display the API and bisVCap melting in the first
heating cycle, no recrystallization during a cooling cycle and a clear
glass transition in the second heating cycle. Each of the 10 systems
only display a single Tg confirming the
samples as COAM and not a mix of two amorphous materials. Comparing
the experimental results with the predictions of the model shows that
11 of the 13 samples were correctly predicted (Table ). The overall prediction success is therefore
85% suggesting the model is good at predicting bisVCap COAM systems,
which is surprising given the chemically different natures of the
amino acid coformers used in the training data set compared to bisVCap.
While amino acids have good hydrogen bond donor and acceptor groups,
bisVCap has only very weak hydrogen bond donor capability.[29] The PLS-DA score scatter plot shows that the
two incorrectly predicted systems paracetamol and mebendazole are
close to the prediction separation line (Figure ). Mebendazole in particular decomposes during
CM and is poorly soluble in acetone during RSE and hence, alternative
COAM preparation methods may prove successful.
Figure 2
PLS-DA score scatter
plot of LV 1 and 2. The color of the markers
displays the results of the experimental screen with red markers indicating
not COAM systems and green markers indicating COAM systems. Samples
incorrectly predicted by the prediction model are shown as hollow
circles.[24] The blue dashed line shows the
predicted separation line systems based on the PLS-DA calculation
for visualization purposes.
PLS-DA score scatter
plot of LV 1 and 2. The color of the markers
displays the results of the experimental screen with red markers indicating
not COAM systems and green markers indicating COAM systems. Samples
incorrectly predicted by the prediction model are shown as hollow
circles.[24] The blue dashed line shows the
predicted separation line systems based on the PLS-DA calculation
for visualization purposes.
Stabilizing Interactions in COAM Systems
FTIR spectroscopy
was used to understand the interactions in the COAM systems (Figure S3). The carbonyl stretching bands for
solid bisVCap occur at 1622 and 1640 cm–1 and its
X-ray crystal structure demonstrates that they do not form any strong
hydrogen bonding interactions.[29] In all
the non-COAM systems (Table ), the position of the bisVCap carbonyl bands are unchanged
suggesting no new interactions are occurring; however, in all the
COAM systems, the bisVCap carbonyl peaks shift to a lower wavenumber
and broaden implying that the bisVCap carbonyl groups are forming
stronger hydrogen bonds causing the weakening of the C=O bond.[15,39,40] The FTIR spectra of the COAM
systems show clear changes in the APIs bands as well indicating the
disruption of the hydrogen bonding structure of the parent single
component phase. The FTIR data suggest bisVCap stabilizes the COAM
system by acting as a hydrogen bond acceptor with the APIs containing
hydrogen bond donor groups.
Stability Study at Different Temperatures
The stability
of three of the experimentally generated COAM systems (Table ) was tested to determine if
the predicted COAM PLS-DA score correlates with the stability of the
COAM product. The three systems selected were bisVCap with paracetamol,
simvastatin, and indomethacin, with corresponding COAM values of 0.450,
0.751, and 1.142. Therefore, if the COAM score is an indication of
stability, it would be expected that the COAM material formed from
bisVCap and indomethacin would be the most stable and the one with
paracetamol the least stable. These three COAM materials were produced
by RSE and stored in sealed vials at both 20 and 3 °C and analyzed
after 2 weeks by XRPD and FTIR spectroscopy. The XRPD (Figure ) and FTIR (Figure S4) data shows that the indomethacin material remains
COAM after 2 weeks; however, both simvastatin and paracetamol have
recrystallized. The XRPD pattern of the recrystallized COAM simvastatin
bisVCap system after 2 weeks at both temperatures (Figure b) showed the crystallization
of bisVCap and the formation of the form I polymorph of simvastatin,
which is the thermodynamically stable polymorph above 0 °C.[41,42] A similar process was observed for the paracetamol bisVCap system
(Figure c) with the
system separately recrystallizing into bisVCap and the form I polymorph
of paracetamol, which is the thermodynamically stable form at the
tested conditions.[43,44] The XRPD patterns for the samples
stored at 20 °C showed complete conversion, while some amorphous
content remained in each of the samples stored at 3 °C. The formation
of the thermodynamically stable polymorph of the simvastatin and paracetamol
suggests bisVCap only slows the crystallization rate but does not
affect the crystallization process. The apparent greater stability
of the indomethacin COAM phase correlates with the higher COAM score
from the PLS-DA model.
Figure 3
XRPD traces of COAM samples of bisVCap with (a) indomethacin,
(b)
simvastatin, and (c) paracetamol. The initial COAM samples made by
RSE are shown in black. The XRPD traces are shown after 2 weeks when
stored at both 20 °C (red) and 3 °C (blue).
XRPD traces of COAM samples of bisVCap with (a) indomethacin,
(b)
simvastatin, and (c) paracetamol. The initial COAM samples made by
RSE are shown in black. The XRPD traces are shown after 2 weeks when
stored at both 20 °C (red) and 3 °C (blue).A second stability experiment with a shorter timescale was
carried
out with bisVCap simvastatin and paracetamol COAM phases. The two
systems were produced by RSE and samples were stored for 1 week at
both 20 and 3 °C. The resulting samples were analyzed by XRPD
(Figure ) and FTIR
(Figure S5). The XRPD pattern shows the
simvastatin COAM material stored at 20 °C crystallizes into bisVCap
and the form I polymorph of simvastatin; however, the sample stored
at 3 °C proved to be a mixture of crystalline bisVCap and amorphous
material indicating that it is the coformer that crystallizes first
rather than both components simultaneously. In the system with paracetamol,
no recrystallization had occurred after 1 week at 3 °C and only
slight recrystallization had occurred for the sample stored at 20
°C. The paracetamol COAM system is, therefore, assumed to be
more kinetically stable than the simvastatin COAM system, which is
the opposite of the prediction based on the COAM values, suggesting
that the PLS-DA score has limited use in predicting stability order.
Figure 4
XRPD traces
of COAM samples of bisVCap with (a) simvastatin and
(b) paracetamol. The XRPD traces are shown after 1 week when stored
at ∼20 °C (black) and 3 °C (red).
XRPD traces
of COAM samples of bisVCap with (a) simvastatin and
(b) paracetamol. The XRPD traces are shown after 1 week when stored
at ∼20 °C (black) and 3 °C (red).
Increasing the Ratio of Furosemide to BisVCap
The COAM
system formed from furosemide and bisVCap has the highest Tg (Table ) and occurs as a free-flowing light-yellow powder, whereas
the other systems are in the form of viscous pastes. The COAM system
produced in the screening experiments has a 1:1 molar ratio of bisVCap
to furosemide. However, COAM systems have been shown to form with
increased ratios of API to a coformer and it is of interest to know
how much API loading the COAM phase can tolerate.[45] Therefore, the preparation of the COAM phase using RSE
was repeated using 1:2, 1:3, and 1:4 ratios of bisVCap to furosemide.
The RSE process was also repeated with a sample of furosemide in the
absence of coformer to determine if the bisVCap is necessary to make
the system amorphous. The systems were analyzed by XRPD and FTIR to
determine the crystallinity and solid form of the resulting products
due to the speed of the results obtained allowing the results to capture
any unstable coamorphous states. The XRPD data (Figure ) shows the bisVCap furosemide systems prepared
by RSE remain amorphous up to a 1:2 ratio. The higher ratio samples
undergo recrystallization into the form II polymorph of furosemide,
which is the polymorph usually formed from evaporation under reduced
pressure of a furosemide acetone solution.[46] The FTIR spectra (Figure ) of all of the samples show that the bisVCap does not recrystallize
as the carbonyl peaks do not return to the original position. The
peaks in the XRPD diffractogram of the 1:4 ratio sample can all be
assigned to form II furosemide. Therefore, the 1:2 ratio seems to
be the API loading limit before crystallization begins. The 1:3 material
displayed a significant amorphous halo suggesting a mixture of COAM
material and excess crystalline furosemide.
Figure 5
XRPD diffractograms of
bisVCap with furosemide after RSE in a 1:1
(black), 1:2 (red), 1:3 (blue), and 1:4 ratio (green). Pure form II
furosemide after RSE is shown in purple.
Figure 6
FTIR spectra
for the increased ratio study of bisVCap and furosemide
showing the carbonyl and alcohol region. The spectra display pure
bisVCap (black) and pure furosemide (red). The bisVCap furosemide
systems were made by RSE at different ratios with 1:1 in blue, 1:2
in green, 1:3 in purple, and 1:4 in light brown. The furosemide systems
which underwent RSE is also shown in cyan.
XRPD diffractograms of
bisVCap with furosemide after RSE in a 1:1
(black), 1:2 (red), 1:3 (blue), and 1:4 ratio (green). Pure form II
furosemide after RSE is shown in purple.FTIR spectra
for the increased ratio study of bisVCap and furosemide
showing the carbonyl and alcohol region. The spectra display pure
bisVCap (black) and pure furosemide (red). The bisVCap furosemide
systems were made by RSE at different ratios with 1:1 in blue, 1:2
in green, 1:3 in purple, and 1:4 in light brown. The furosemide systems
which underwent RSE is also shown in cyan.
Stability Study on BisVCap and Furosemide at Different Humidities
To understand the effect of humidity on the bisVCap COAM systems
a 1:1 mixture of bisVCap and furosemide was prepared by RSE and stored
in five different humidity environments (0, 11, 33, 75, and 100%).
The systems were analyzed by XRPD and FTIR after seven days and 28
days to see the effect of the different humidity environments.[47] The initial XRPD data (Figure ) shows the system is amorphous. After 7
days the material stored at 0, 11, and 33% RH remained unchanged by
XRPD (Figure ) and
FTIR (Figure S6), and the material retained
the appearance of a free flowing powder. The material stored at 75%
RH appears to remain amorphous by both FTIR (Figure S6) and XRPD (Figure ); however, the material changed from a powder to a glass-like
film. No recrystallization was observed by polarized optical microscopy
indicating the system remain amorphous even after absorption of water.
The material stored at 100% RH turned into a thick paste and started
to recrystallize as shown by XRPD with small Bragg peaks observed
corresponding to the form I polymorph of furosemide which is the thermodynamically
stable form under ambient conditions however, the FTIR spectrum remained
unchanged suggesting only a small amount of the sample has recrystallized.[48]
Figure 7
XRPD traces of a COAM bisVCap furosemide material made
by RSE.
The initial system is shown in black. The system was stored for 7
day at 0% RH (red), 11% RH (green), 33% RH (blue), 75% RH (cyan),
and 100% RH (pink).
XRPD traces of a COAM bisVCap furosemide material made
by RSE.
The initial system is shown in black. The system was stored for 7
day at 0% RH (red), 11% RH (green), 33% RH (blue), 75% RH (cyan),
and 100% RH (pink).After storage for 28
days in the five different humidity environments,
the materials stored at 0 to 75% RH remained unchanged with no indications
of recrystallization by FTIR (Figure S7) or XRPD (Figure ). The material stored at 100% RH underwent significant crystallization
as observed by FTIR with the appearance of sharper peaks in the 3200–3500
cm–1 region corresponding to the N–H stretching
bands and XRPD displaying Bragg peaks matching the form I polymorph
as well as some remaining amorphous halo.[48] Overall, it appears the 1:1 bisVCap furosemide system remains stable
up to 75% RH.
Figure 8
XRPD traces of a COAM bisVCap furosemide system made via
RSE. The
initial system is shown in black. The system was stored for 28 days
at 0% RH (red), 11% RH (green), 33% RH (blue), 75% RH (cyan), and
100% RH (pink).
XRPD traces of a COAM bisVCap furosemide system made via
RSE. The
initial system is shown in black. The system was stored for 28 days
at 0% RH (red), 11% RH (green), 33% RH (blue), 75% RH (cyan), and
100% RH (pink).
Conclusions
In
conclusion, the PLS-DA prediction model was tested against the
results of a previously published COAM screening of bisVCap with a
range of APIs, successfully predicting five out of seven systems.
The model was then used to predict the outcomes of COAM screening
of bisVCap with 13 further APIs expected to form both COAM and non-COAM
systems. Each of the mixtures was experimentally prepared by both
CM and rapid solvent evaporation. The PLS-DA model successfully predicted
the outcome in 11 of the 13 systems. The FTIR data indicates that
bisVCap stabilizes the COAM systems by the formation of hydrogen bonds
with the two carbonyl groups disrupting the intermolecular hydrogen
bonding in the pure API.The stability of three COAM systems
of bisVCap with indomethacin,
paracetamol, and simvastatin was analyzed at two different storage
temperatures to determine if the prediction model COAM score correlates
with the stability of the COAM phases. The stability assessment showed
that indomethacin was the most stable agreeing with the model; however,
the paracetamol system proved more stable than simvastatin suggesting
the prediction model score is not strongly correlated with stability.The stability of the COAM system as a function of API loading showed
that up to a 2:1 ratio of API to bisVCap remains amorphous, with crystallization
of the API thereafter. This may be because of two hydrogen bond acceptor
carbonyl groups on the coformer. A variable humidity study showed
that the 1:1 bisVCap furosemide system remains stable for at least
28 days when stored at 75% RH. The bisVCap coformer is a remarkably
effective way of stabilizing coamorphous phases with a range of APIs
and in 85% of cases the formation of a COAM phase is successfully
predicted by the PLS-DA model despite the very different systems used
to train it.
Authors: Luke I Chambers; Holger Grohganz; Henrik Palmelund; Korbinian Löbmann; Thomas Rades; Osama M Musa; Jonathan W Steed Journal: Eur J Pharm Sci Date: 2020-11-04 Impact factor: 4.384
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