manuscript


doi: 10.5599/admet.2.1.33 18 

ADMET & DMPK 2(1) (2014) 18-32; doi: 10.5599/admet.2.1.33 

 
Open Access: ISSN: 1848-7718  

http://www.pub.iapchem.org/ojs/index.php/admet/index   

Original scientific paper 

The intrinsic aqueous solubility of indomethacin 

John Comer
1
*, Sam Judge

1
, Darren Matthews

1
, Louise Towes

1
,
 
Bruno Falcone

2
, 

Jonathan Goodman
2
 and John Dearden

3
  

1
Sirius Analytical Ltd., Forest Row, West Sussex RH18 5DW, UK 

2
Unilever Centre for Molecular Informatics, Department of Chemistry, University of Cambridge, Lensfield Road, 

Cambridge CB2 1EW, UK 
3
School of Pharmacy & Biomolecular Sciences, Liverpool John Moores University, Byrom Street, Liverpool L3 3AF, UK 

*Corresponding Author: E-mail: John.Comer@sirius-analytical.com; Tel.: +44 1342 820720 

Received: February 19, 2014; Revised: April 01, 2014; Published: April 01, 2014  

 

Abstract 
A value of 8.8 μg/mL was measured for the intrinsic solubility of indomethacin. Evidence of a form with a 

solubility of about 77 μg/mL was also obtained. Solubility measurements were conducted using the 

CheqSol and Curve Fitting methods using a maximum pH of 9. It is also demonstrated that a published 

intrinsic solubility of 410 μg/mL was in error due to decomposition of indomethacin at pH 12. The 

decomposition of indomethacin at pH 12 was investigated. Decomposition products comprising p-

chlorobenzoic acid and 5-Methoxy-2-methyl-3-indoleacetic acid were isolated and characterised. 

Keywords: Indomethacin, solubility, CheqSol, p-chlorobenzoic acid, decomposition 

 

Introduction 

Indomethacin is a widely-used non-steroidal anti-inflammatory drug (NSAID), despite its propensity to 

cause gastric irritation and ulceration. Its structure is shown in Figure 1. Indomethacin can exist in several 

polymorphic solid forms and as an amorphous solid. Yamamoto [1] reported in 1968 that he had isolated 

three polymorphs, and with slightly different melting points. Borka [2] and Lin [3] claimed to have 

found at least four polymorphic modifications. Other authors recognise only the  and  polymorphs [4-6]. 

The polymorphism is believed to arise from different orientations between the aromatic indole and phenyl 

rings [7]. Solvates are also known to exist [2,8]. 

 

Figure 1. Decomposition of indomethacin into 5-methoxy-2-methyl-3-indoleacetic acid  (1) and p-chlorobenzoic acid at 
pH 12. 

N

O Cl

O

OH

MeO

pH 12

H
N

O

OH

MeO
+

O Cl

HO

indomethacin 1 p-chlorobenzoic acid

http://www.pub.iapchem.org/ojs/index.php/admet/index
mailto:John.Comer@sirius-analytical.com


ADMET & DMPK 2(1) (2014) 18-32 Indomethacin solubility 

doi: 10.5599/admet.2.1.33 19 

 

One difficulty associated with the measurement of the solubility of indomethacin is that the measured 

solubility can change with over time [2,10,11], suggesting that there is conversion from one form to 

another. For example, Murdande et al. [10] found that amorphous indomethacin in aqueous solution 

changed almost completely to a mixture of the and  polymorphs over a 40-minute period, with solubility 

decreasing from about 26 μg/mL to about 9 μg/mL. 

Numerous measurements of the aqueous solubility of indomethacin have been reported and results are 

presented in Table 1.  Predicted indomethacin solubilities from a number of commercial and free-to-use 

software programs are also summarised in Table 1.  

It can be seen from Table 1 that the published solubilities for the  and  polymorphs are quite 

consistent. It is, however, difficult to say with assurance whether the so-called polymorph I is the or  

polymorph, and polymorphs II and IV are not obviously either or . 

 

Table 1. Reported measured values for the solubility of indomethacin, and a selection of values calculated by 

commercial software. RT = room temperature; n/a = not available. 

 

Because amorphous solids do not have crystal lattices in which molecules can be held strongly, they are 

more soluble and are lower-melting than are their crystalline forms. Murdande et al. [10] reported that the 

aqueous solubility ratio (amorphous/-polymorph) for indomethacin was 4.9. Borka [2] found the 

amorphous form of indomethacin to have a melting point of 55-57 °C, in contrast to values ranging from 

134 to 160 °C for various polymorphic forms.   

There is considerable variation among the unspecified form solubilities reported, which could indicate 

that different proportions of polymorphs and amorphous form have contributed to the reported 

solubilities.  

One reported solubility value, (410 μg/mL), is significantly higher than all the others and has been the 

source of some controversy [23]. This result was one of 132 measured by the Sirius CheqSol method and 

cited in the Cambridge Solubility Challenge.  The Cambridge Solubility Challenge invited readers to use 100 

measured solubility values to train software for predicting solubility from the structure alone [24], and then 

Form μg/mL Temp. °C REF. Form μg/mL Temp. °C REF. Form μg/mL REF.

pol ymorph I 4.2 25 2 uns peci fi ed 9.5 RT 15 uns peci fi ed 17.3 39

pol ymorph II 15.6 25 2 uns peci fi ed 0.94 25 16 "Nati ve" 39.1 39

pol ymorph IV 20 25 2 uns peci fi ed 18.5 25 17 uns peci fi ed 0.94 40

α pol ymorph 8.7 35 4 uns peci fi ed 25.3 35 17 uns peci fi ed 4.3 41

γ pol ymorph 6.9 35 4 uns peci fi ed 3.9 25 18 uns peci fi ed 2.4 42

γ pol ymorph 5 25 9 uns peci fi ed 2.3 25 19 uns peci fi ed 3.1 43

amorphous 22.5 25 9 uns peci fi ed 40 25 20 uns peci fi ed 0.81 44

γ pol ymorph 5 25 10 uns peci fi ed 15 25 21

amorphous  24.5 25 10 uns peci fi ed 27.1 RT 22

α pol ymorph 9.4 35 12 uns peci fi ed 410 25 25

γ pol ymorph 6.9 35 12 uns peci fi ed 0.94 25 31

pol ymorph I 9.1 25 13 uns peci fi ed 1.16 25 35

pol ymorph II 14.4 25 13 uns peci fi ed 3.09 25 36

α pol ymorph 4 n/a 14 uns peci fi ed 0.4 25 37

γ pol ymorph 6 n/a 14 uns peci fi ed <1 RT 38

amorphous  10 n/a 14

Meas ured val ues Cal cul ated val ues



Comer et al.   ADMET & DMPK 1(2) (2014) 18-32 

20  

to use the trained software to predict the solubility of a further 32 molecules whose solubilities had been 

withheld from the publication. One of these 32 molecules was indomethacin. A total of 99 entries were 

received from software providers, and the results were reviewed in a subsequent publication [25]. 

Although most of the 32 values were predicted well, software was not able to predict the solubility of 

indomethacin.   

In the current paper we used the CheqSol approach to reinvestigate the aqueous solubility of 

indomethacin and determined a value of 8.8 μg/mL. We also found evidence suggesting an amorphous 

form, as well as evidence to suggest that indomethacin might have decomposed during the measurement 

reported in [25]. We used NMR and HPLC to characterise the decomposition, which occurs at high pH. The 

results reported in this paper together with the graphical representations of dissolution and precipitation 

events during the experiments enable us to gain improved understanding of the solubility of indomethacin. 

 

Experimental 

Indomethacin (I7378, ≥99 %) was purchased from Sigma Life Science and used without further 

purification. The polymorphic form of this material was not specified. Solubility and pKa values were 

measured using the SiriusT3 automatic titration system (Sirius Analytical Ltd., Forest Row, UK), using the 

software supplied with the instrument to calculate results from the experimental data. Solubility 

experiments to prepare solid material for HPLC and NMR studies were undertaken on the Sirius GLpKa 

automatic titration system. Solution and solid composition were investigated using NMR spectroscopy, 

LCMS and HPLC with UV detection. NMR spectral data (500 MHz 
1
H NMR and 125 MHz 

13
C) were recorded 

in a BRUKER Avance 500 MHz BroadBand. 
1
H and 

13
C NMR chemical shifts are reported in parts per million 

(ppm) and referenced relative to their residual solvent peaks. Assignments were determined by 

unambiguous chemical shift, analogue comparison, coupling patterns, or HMQC experiments. LCMS data 

were collected with a Waters ZQ Mass Spectrometer using Electrospray Ionisation, connected to a Waters 

2795 HPLC and 996 DAD. The column used was an Agilent Poroshell 120 C-18 4.6 x 30 mm, 2.7 µm particle 

size, and the solvent mixtures were A: 10 mM ammonium acetate with 0.1 % formic acid, and B: 95 % 

aqueous acetonitrile with 0.05 % formic acid. HPLC/UV data were collected with a Shimadzu SPD M-20A 

PDA connected to a Shimadzu LC-10 HPLC. The column used was a Phenomenex KinetexC-18 4.6 x 50 mm, 

2.6 µm particle size, and the solvent mixtures were A: 0.1 % formic acid, and B: acetonitrile. 

Solubility measurements were carried out using the CheqSol and Curve Fitting methods. These methods 

and the associated Bjerrum Curves are described in detail elsewhere [26-28].  Indomethacin samples of 

around 2 mg were weighed accurately into glass vials. Measurements were performed in 1.5 mL of 

deionised water. The pH of the prepared sample was raised by adding standardised 0.5 M KOH solution, 

under which conditions all the indomethacin dissolved in ionised form. The transmission of light through 

the sample was monitored at 500 nm by use of a spectroscopic dip probe connected to a diode array 

spectrophotometer. The spectroscopic data were used to detect the onset of precipitation as the pH was 

lowered by adding standardised 0.5 M HCl solution. In CheqSol assays, small aliquots of KOH or HCl solution 

were added after precipitation to maintain the system close to equilibrium, and solubility results were 

calculated from rates of pH change vs. concentration. In Curve Fitting assays, only HCl was added, and 

solubility was calculated by fitting a Precipitation Bjerrum Curve to the data. Some Curve Fitting 

experiments commenced at low pH; these are discussed later. 

In order to calculate solubility results from the CheqSol and Curve Fitting data the pKa of indomethacin is 

required, and a value of 4.13 ± 0.018, I = 0.058M, 25.2 °C was measured in triplicate by a UV-metric method 



ADMET & DMPK 2(1) (2014) 18-32 Indomethacin solubility 

doi: 10.5599/admet.2.1.33 21 

on the same instrument. Some comment is required on this pKa measurement. A pH-metric titration 

method is often chosen to measure the pKa of compounds in which the ionisable group shows weak UV 

activity. However it proved to be surprisingly difficult to measure the pKa reliably by the pH-metric method. 

Because of its low aqueous solubility, indomethacin pKa must be measured in cosolvent-water mixtures and 

an aqueous result obtained by extrapolation. This was first attempted in methanol-water solutions adjusted 

to an ionic strength of 0.15M with KCl. A result of 4.20 was obtained from the Yasuda-Shedlovsky 

extrapolation of four psKa values measured at methanol percentages between 37.4 % and 52.7 %. However 

a further 14 methanol-water psKa values were considered to be too unreliable to include in the 

extrapolation, and confidence in the methanol-water result was low. Measurement was then attempted in 

solutions containing dioxane-water adjusted to an ionic strength of 0.15 M with KCl. A result of 4.22 was 

obtained from the Yasuda-Shedlovsky extrapolation of seven psKa values measured at dioxane percentages 

between 37.4 % and 52.7 %. This value was used in the Curve Fitting solubility measurement made from 

low to high pH (Figure 2). However the linear extrapolation of the same data yielded a result of 3.60 and 

the discrepancies between these two dioxane-water extrapolations led to some caution. It has been 

reported that indomethacin can self-aggregate in pure water and in the absence of ionic strength [29], and 

it seems likely that this tendency will be stronger at high ionic strength. This tendency for aggregation was 

not allowed for in the software used in the SiriusT3 to calculate pKa values from titration data, and this 

could lead to errors in pKa measurement. The behaviour of indomethacin during pH-metric pKa 

measurement at 1 mM concentration when forming aggregates in the presence of 0.15 M KCl and varying 

percentages of solvent is likely to be hard to predict.  The difficulty of accounting for aggregation might also 

explain why other reported measurements of indomethacin pKa differ considerably (4.01 +/-0.09, I=0.05 M, 

25 °C, CE procedure [30]), (4.17, I=0.5 M, 25 °C [31], (4.5, conditions not described [29]). The effects of 

aggregation should be less apparent in UV-metric pKa measurement, where the sample concentration is 

around 30 μM.  

In parallel with these attempts to measure indomethacin pKa by pH-metric titration it was observed 

during the solubility measurements that indomethacin did not fully dissolve at pH 9 in the presence of 0.15 

M KCl, which would be the case if the potassium salt of indomethacin was poorly soluble. It is important in 

CheqSol experiments that the sample is fully dissolved in ionised form at the start of the experiment and 

that no precipitated salt is present [26]. It was found that indomethacin did dissolve when solutions were 

prepared in deionised water adjusted to pH 9, and the subsequent solubility measurements were therefore 

done in a low ionic strength background.  

In order that the pKa value used in the solubility data sets were collected under similar conditions, it was 

measured in pH-adjusted deionised water (average ionic strength = 0.058M) by a UV-metric method. The 

carboxylic acid in indomethacin is not part of a chromophore but a small change in absorbance vs. pH was 

observed, and this was sufficient for reliable measurements to be made.  

It is understood that pH-metric experiments done at low ionic strength are susceptible to pH electrode 

calibration errors but these errors are most apparent at pH below 3 and above 11, and will have little effect 

on the solubility measurements reported here in which all relevant data were between pH 4 and 9. 

Results and Discussion 

Evaluating the outlying published result 

The starting point for this research was to discover why a value of 410 μg/mL for solubility measured by 

CheqSol was so different from other reported values. 



Comer et al.   ADMET & DMPK 1(2) (2014) 18-32 

22  

 The first step was to re-examine the data from which this result was derived. This experiment used a 

standard template for measurement of solubility of a monoprotic weak acid, which includes a dissolution 

phase wherein the sample solution is held at pH 12 for several minutes. The sample will be fully ionised at 

this pH and is expected to dissolve in aqueous solution. Although an experiment starting at lower pH (e.g. 

between 7 and 10) would similarly ensure the compound is fully ionised, a value of 12 is normally chosen 

because water has a high buffer capacity at this pH and therefore resists the sample’s tendency to drag the 

pH down as it dissolves, helping to ensure complete dissolution of the sample.  The existence of titration 

data between the pH of sample dissolution and the pH of precipitation generally improves the quality of 

CheqSol experiments because it aids the calculation of acidity error and concentration factor, and may in 

some circumstances provide experimental verification of the sample’s pKa.  

A Curve Fitting experiment was then run at 25 °C in 0.15 M KCl solution on the SiriusT3, starting at low 

pH where the indomethacin was present as a suspension of crystalline solid as obtained from the 

manufacturer. The suspension was titrated slowly with KOH solution and a Precipitation Bjerrum Curve was 

calculated from the pH measured as the sample dissolved (Figure 2). Although the data below pH 3 deviates 

above a mean molecular charge of 0 and may indicate an electrode calibration error, this deviation occurs 

in a region where the sample is not undergoing ionization, and has no effect on the data above pH 3. It is, 

however significant that unionised indomethacin is poorly wettable and tends to float, which led to variable 

data quality. A result of 3.3 μg/mL was determined from the data points between the vertical red lines by 

the Curve Fitting procedure described below in the section “Investigating the intrinsic solubility of 

indomethacin”; this value is close to the values listed in Table 1.  

 

Figure 2. Curve Fitting experiment to determine the solubility of indomethacin; 3.8 mg of indomethacin in 1.5 mL 
of 0.15 M KCl, titrated with 0.5 M KOH at 25 °C. The solid blue triangles denote data points that are included in the 

Curve Fitting calculation. Unfilled triangles are excluded. 

 

The comparison of solubilities measured in two experiments done in opposite pH directions provides a 

quick way to check for metastable behaviour of the solid state after precipitation. However a solubility of 

410 μg/mL seemed too high to represent the solubility of a polymorphic form of indomethacin. Subsequent 

analysis of the data from the “410  μg/mL” experiment indicated that the sample chased equilibrium during 

the assay, indicating that this result is not likely to correspond to an amorphous form. 

1 3 5 7 9 11

pH (Concentration scale)

-1.0

-0.5

0.0

M
e

a
n

 m
o

le
c

u
la

r 
c

h
a

rg
e



ADMET & DMPK 2(1) (2014) 18-32 Indomethacin solubility 

doi: 10.5599/admet.2.1.33 23 

A careful literature search revealed that indomethacin can undergo base-catalysed hydrolysis [32] and it 

is shown here that it rapidly decomposes at pH 12 to p­chlorobenzoic acid and 5-methoxy-2-methyl-3-

indoleacetic acid (1). It is therefore likely that the result of 410 μg/mL is erroneous, and that the species 

that was observed to chase equilibrium during the CheqSol assay was the least soluble of these two 

decomposition products. This decomposition is illustrated in Figure 1. 

The experimental work now proceeded in two stages: a study to investigate the decomposition of 

indomethacin and a series of new CheqSol experiments to re-investigate the intrinsic solubility of 

indomethacin. 

 

Investigating the decomposition of indomethacin at high pH 

The “410 μg/mL” solubility experiment was repeated using the Sirius GLpKa, which provides 15 mL of 

solution containing 20 mg of solid for examination. NMR shows the presence of peaks representing p-

chlorobenzoic acid and the substituted indole (1). Separation of these two compounds was attempted using 

column chromatography but did not succeed due to the high polarity of the compounds. Instead, methyl 

esters of the acids were formed and separation via column chromatography was successful. The ester of 

the indole product was subsequently hydrolysed back to the corresponding acid. These compounds were 

fully characterized, and it was found that indomethacin had decomposed into p-chlorobenzoic acid and the 

substituted indole (1) during the dissolution phase of the experiment (15 – 20 min). 

The pKa values of p-chlorobenzoic acid (3.75) and the substituted indole 1 (4.42) were measured. For an 

experiment at 10 mM concentration, no precipitate was found for the indole (1), and its kinetic solubility 

was therefore expected to be higher than 10 mM. Using the measured value for the pKa of p-chlorobenzoic 

acid, the initial indomethacin decomposition CheqSol experiment was reanalysed and an accurate value for 

the solubility of p-chlorobenzoic acid was determined (302 μM; 42.4 μg/mL). This was possible because the 

indole (1) has a much higher solubility than the concentration present in the experiment. The nature of the 

precipitate was established as p-chlorobenzoic acid. Details of the decomposition study and NMR results 

are given in the Appendix. 

A re-analysis of the Bjerrum titration curve of the “410 µg/mL” experiment leads to a conclusion that is 

consistent with the hypothesis that decomposition had occurred. Figure 3 shows that twice as many 

protons were lost from the added acid as was expected. This arises from the fact that twice as much base 

has been added as would be necessary for the concentration of monoprotic indomethacin introduced in 

the experiment, thus suggesting that two acidic protons are present for each sample molecule.  If the 

calculation is modified to account for the presence of two weak acids, namely the poorly soluble p-

chlorobenzoic acid that precipitated and the substituted indole (1) that remained in solution, then the 

calculated curve representing p-chlorobenzoic acid fits the experimental one (Figure 4). 



Comer et al.   ADMET & DMPK 1(2) (2014) 18-32 

24  

 

 

Figure 3. CheqSol solubility Bjerrum curve for indomethacin starting from pH 12. The blue star indicates the starting 
point of the titration. The pink circle indicates the onset of precipitation. The Mean molecular charge value of -2 is 

consistent with the presence of two titratable acids. 

 

 

Figure 4. CheqSol solubility Bjerrum curve for indomethacin starting from pH 12. The settings were modified into an 
assay for p-chlorobenzoic acid in the presence of one equivalent of the substituted indole 1. Using these settings, a 

solubility result showing good agreement with the reported intrinsic solubility of p­chlorobenzoic acid was obtained. 

 

Investigating the intrinsic solubility of indomethacin  

A new series of CheqSol and Curve Fitting experiments was conducted to investigate the intrinsic 

solubility of indomethacin. To check for stability, solutions of indomethacin were prepared at pH 7.4, 9, 12 

and >12 and stored for 3 hours, and then compared by HPLC/UV. Sharp peaks after 4.2 minutes were 

observed for the solutions at pH 7.4 and 9. However the peaks occurred after 2.8 minutes for the solutions 

prepared at higher pH, suggesting that the composition of the solution was significantly different to the 

 

 
 

 

 

 

 

 

1 3 5 7 9 11 

pH (Concentration scale) 

-2.0 

-1.5 

-1.0 

-0.5 

0.0 
M

e
a

n
 m

o
le

c
u

la
r 

c
h

a
rg

e
 

 

 
 

 
 

 

 
 

 

 

 

 
 

 

 
 

 

 

 

1 3 5 7 9 11 13 

pH (Concentration scale) 

-1.0 

-0.5 

0.0 

M
e

a
n

 m
o

le
c
u

la
r 

c
h

a
rg

e
 



ADMET & DMPK 2(1) (2014) 18-32 Indomethacin solubility 

doi: 10.5599/admet.2.1.33 25 

composition of the solutions prepared at lower pH. With this evidence it was decided that decomposition 

could be avoided if experiments started at a pH of about 9. 

All experiments were conducted at 25 ± 0.5 °C. Samples of indomethacin between 2±0.3 mg were 

weighed into glass vials. 50 μL of DMSO was added manually to aid dissolution and the vials were then 

placed on the Sirius T3 instrument, which added 1.5 mL of deionised water and then raised the pH to 

between 9.03 and 9.39 by adding about 10 μL of 0.5 M KOH solution. In our experience the inclusion of 50 

µL DMSO in the sample solution (corresponding to a DMSO concentration of about 2 % v/v) does not alter 

significantly the measured solubility values of most compounds. The vial plus contents was then sonicated 

for 5 minutes to ensure complete dissolution of the indomethacin in ionised form. The solution was then 

titrated with 0.5 M HCl until the onset of precipitation, which was detected by an in-situ UV probe. The 

concentration of neutral indomethacin in solution at the onset of precipitation is referred to as the kinetic 

solubility. After precipitation the experiments followed CheqSol or Curve Fitting protocols, which are 

described elsewhere [28]. Results of these solubility measurements are listed in Table 2. 

 

Table 2. Results of experiments to measure solubility of indomethacin. Log S refers to the logarithm to base 10 of the 

solubility in units of molarity. 

 

 

The system chased equilibrium during the latter stages of all CheqSol experiments, suggesting that the 

precipitated material had crystallized. In one Cheqsol experiment, a few crystals of the original solid were 

added after the system had begun chasing equilibrium but there was no obvious shift in solubility, 

suggesting that the system was measuring the same polymorphic form.  

In all of the CheqSol experiments the indomethacin precipitated initially in a form with mean kinetic 

solubility of 77 μg/mL that endured for between 5 and 15 minutes before converting to a form with mean 

intrinsic solubility of 8.8 μg/mL (n = 4). By analogy with published studies [33] it is likely that the initial 

precipitation is a Liquid-Liquid Phase Separation (LLPS) in which a disordered amorphous solid state is 

created that later crystallizes. This process is summarised in Figures 5 and 6. Although the value of 8.8 

μg/mL was reproducibly measured in four experiments, it is not possible to claim that it represents the 

solubility of the least soluble polymorph. The effects of possible aggregation were not modelled in the 

software. There was 50 µL of DMSO present in each experiment, which may affect the result and the crystal 

form. The Curve Fitting experiment starting at low pH with the original solid (Figure 1) determined a 

solubility of 3.3 μg/mL, and other workers have reported lower values (Table 1). It could be useful in the 

future to re-measure the solubility in experiments with longer duration (e.g. 24 hours) to check for further 

Figure Description Ionic strength pKa

log S μg/mL log S μg/mL log S μg/mL

1

Curve-Fitting, pH2 up. 

Original solid (3.8 mg) 

dissolved during 

experiment.

0.157 M 4.22 (n = 1) -5.0 3.3

5
CheqSol pH9  down. 2 mg 

+ 50µL DMSO
0.0065 M 4.13

Average 

(n = 4)
-3.6 76.9 -4.6 8.8

Std. Dev. 0.1 8.3 0.1 1.7

7
Curve Fitting, pH9  down. 

2 mg  + 50µL DMSO
0.004 M 4.13

Average 

(n = 3)
-3.7 68.7 -3.7 79.8

Std. Dev. 0.0 5.4 0.0 5.8

8
Curve Fitting, pH9  down. 

2 mg + 50µL DMSO
0.004 M 4.13 (n = 1) -3.7 72.1 -4.4 13.2

IntrinsicKinetic Amorphous



Comer et al.   ADMET & DMPK 1(2) (2014) 18-32 

26  

conversion to a less soluble form; such changes have occasionally been observed in the Sirius laboratory 

and are described in Figure 6. 

 

Figure 5. CheqSol solubility Bjerrum curve for indomethacin starting from pH 9. The blue star denotes the start of the 
experiment. The red triangles denote the addition of HCl titrant. The pink circle indicates the onset of precipitation, 

and lies on the green line representing the solubility of the initial precipitated form. 

 

 

Figure 6. Data from Figure 5 re-plotted to show the concentrations of the initial precipitated form (plateau on left 
hand side) and the crystalline form (points from 35 minutes onwards), to which a solid blue line representing the 

intrinsic solubility has been fitted. The changes in magnitude of the concentration changes associated with the lower 
plateau may indicate that crystals are consolidating by Ostwald ripening. Although not evident here, CheqSol 

experiments with other samples sometimes show concentrations dropping to a lower plateau after longer times, 
suggesting that a metastable crystalline form has converted to a more stable crystalline form. 

 

By contrast the precipitated sample persisted in the higher solubility form throughout three Curve 

Fitting experiments, as shown in Figure 7. It may be useful to speculate why the sample remained 

amorphous in the Curve Fitting experiments but crystallized in the CheqSol. In Curve Fitting experiments pH 

is adjusted in one direction only and this often allows the sample to persist in the amorphous state. In 



ADMET & DMPK 2(1) (2014) 18-32 Indomethacin solubility 

doi: 10.5599/admet.2.1.33 27 

CheqSol experiments, successive aliquots of acid and base are added and it is believed this may stimulate 

the onset of crystallization after a short amorphous period. Although the sample remained amorphous 

during three Curve Fitting experiments, it converted soon after precipitation in a fourth experiment to a 

less soluble form, as shown in Figure 8. It is not understood why this conversion took place. 

 

Figure 7. Curve Fitting experiment in which indomethacin persisted in a form that is probably amorphous.   

 

 

Figure 8. Curve Fitting experiment in which indomethacin converted soon after precipitation a form that is probably 
amorphous to a form with lower solubility. 

 

It is important to point out that the Sirius Curve Fitting protocol differs from the Pion pSOL method [34]. 

In the pSOL method the solubility is calculated using an approach based on mass balance expressions 

constructed from the equilibrium equations and constants which iteratively derives the concentrations of 

all species present in solution and those which have precipitated. In the Sirius Curve Fitting method, 

samples are dissolved in ionised form and the solutions are titrated with acid or base towards the pH where 

the samples are in neutral form. The solution is a user-supervised automated on-screen graphics exercise in 

which the user selects the data points to include, and a theoretical Bjerrum curve representing the 



Comer et al.   ADMET & DMPK 1(2) (2014) 18-32 

28  

precipitation and calculated from the pKa and proposed solubility result is manually fitted to the selected 

data points. Data collection for Curve Fitting experiments is fast for compounds that precipitate in the 

amorphous (i.e. LLPS) form. This is because the so-called precipitation is actually a phase separation 

between an aqueous solution and a liquid or supercooled liquid phase. The pH quickly reaches a stable 

value after each addition of titrant, and the data generally fits the theoretical model well. Curve Fitting 

experiments are not suitable for compounds that quickly crystallise after precipitation because it may take 

many minutes for the pH to reach a stable value after each addition of titrant. These compounds are 

measured by the CheqSol method. Indomethacin is an unusual compound because it tends to remain in 

amorphous form during Curve Fitting experiments yet quickly converts to a crystalline form during CheqSol 

experiments. 

Conclusions 

Indomethacin decomposes rapidly at pH 12. This invalidates measurements of its solubility that involved 

any exposure to high pH conditions, and illustrates the importance of selecting appropriate assay 

conditions when analysing acid- or base-labile molecules using titration methods.  Any unexpectedly large 

mean molecular charge values should be investigated, as they may suggest the occurrence of 

decomposition.  It is shown that in some cases CheqSol assays can be carried out successfully even for pH-

unstable compounds if mild starting conditions are utilised. Indomethacin is stable at pH 9. A value of 8.8 

μg/mL for the intrinsic solubility of indomethacin was measured in experiments in which all data was 

collected at pH 9 or below; however, this result may not represent the least soluble form. These 

experiments also provided strong evidence for the existence of a form of indomethacin with a solubility of 

about 77 μg/mL, which persisted before crystallization for between 5 and 15 minutes.  

The authors would like to suggest the following topics for future research. Any one of the following 

would be interesting: to create additional software for calculating solubility results from the pH-metric 

CheqSol data that includes equilibrium expressions to describe aggregation; to run the CheqSol 

experiments for longer times in case the form with solubility of 8.8 μg/mL converts to a less soluble form; 

to examine the precipitates with a polarising light microscope or other tools to provide evidence of their 

amorphous or crystalline form; to identify a target pH at which indomethacin precipitates as the pH is 

lowered and then to run controlled supersaturation experiments at higher pH to investigate the duration of 

supersaturation and the induction time when a form change occurred. 

Who did what: Sam Judge and Louise Towes ran pKa and solubility measurements using the SiriusT3. Darren 
Matthews ran HPLC experiments to validate the sample integrity. Bruno Falcone and Jonathan Goodman 
characterised the decomposition of indomethacin and measured the pKa and solubility of p-chlorobenzoic 
acid and the substituted indole (1). John Dearden encouraged the other authors to write this paper and 
provided valuable literature searches and insights. John Comer planned the solubility investigations, created 
the Figures and wrote or edited the text. 

References 

[1] H. Yamamoto. Chem. Pharm. Bull. 16(1) (1968) 17-19. 

[2] L. Borka.  Acta Pharm. Suecica. 11(3) (1974) 295-303. 

[3] S-Y Lin. J Pharm Sci. 81(6) (1992) 572-576. 

[4] N. Kaneniwa, M. Otsuka, T. Hayashi. Chem. Pharm. Bull. 33(8) (1985) 3447-3455. 

[5] V. Andronis, G. Zografi. J. Non-Cryst. Solids. 271(3) (2000) 236-248. 

[6] J.M. Aceves-Hernandez, I. Nicolás-Vázquez, F.J. Aceves, J. Hinojosa-Torres, M. Paz, V.M. Castaño. J. 
Pharm. Sci. 98(7) (2009) 2448-2463. 



ADMET & DMPK 2(1) (2014) 18-32 Indomethacin solubility 

doi: 10.5599/admet.2.1.33 29 

[7] C. Aubrey-Medendorp, M.J. Swadley, T. Li. Pharm. Res. 25(4) (2008) 953-959. 

[8] N. Hamdi, Y. Feutelais, N. Yagoubi, D. de Girolamo, B. Legendre. J. Therm. Anal. Cal. 76 (2004) 985-
1001. 

[9] B.C. Hancock, M. Parks. Pharm. Res. 17(4) (2000) 397-403. 

[10] S.B. Murdande, M.J. Pikal, R.M. Shanker, R.H. Bogner. J. Pharm. Sci. 99(3) (2010) 1254-1264. 

[11] D. Iohara, F. Hirayama, T. Ishiguro, H. Arima, K. Uekama. Int. J. Pharm. 354(1-2) (2008) 70-76. 

[12] M. Otsuka, T. Matsumoto, N. Kaneniwa. Chem. Pharm. Bull. 34(4) (1986) 1784-1793.  

[13] A. Rezaei Mokarram, A. Kebriaee Zadeh, M. Keshavarz, A. Ahmadi, B. Mohtat. DARU J. Pharm Sci. 
18(3) (2010) 185-192. 

[14] T. Ito, T. Sugafuji, M. Maruyama, Y. Ohwa, T. Takahashi. J. Supramol. Chem. 1(4-6) (2001) 217-219. 

[15] O.A. Deshpande, V.B. Yadav. Int. J. Chem.Tech. Res. 1(4) (2009) 1312-1317. 

[16] S.H. Yalkowsky, R.M. Dannenfelser. AQUASOL Database of Aqueous Solubility, version 5, College of 
Pharmacy, University of Arizona, Tucson, AZ, USA, 1992. 

[17] F. Martínez, M.A. Peña, P. Bustamante. Fluid Phase Equilib. 308(1-2) (2011) 98-106. 

[18] A. Nokhodchi. J. Pharm. Pharmaceu.t Sci. 8(1) (2005) 18-25. 

[19] C.A.S. Bergström, M. Strafford, L. Lazorova, A. Avdeef, K. Luthman, P. Artursson. J. Med. Chem. 
46(4) (2003) 558-570. 

[20] S. Muchtar, M. Abdulrazik, J. Frucht-Pery, S. Benita. J. Control. Release 44(1) (1997) 55-64. 

[21] S. Jambhekar, R. Casella, T. Maher. Int. J. Pharm. 270(1-2) (2004) 149-166.  

[22] R. Bodmeier, H. Chen. J. Control. Release. 12(3) (1990) 223-233.  

[23] M. Hewitt, M.T. Cronin, S.J. Enoch, J.C. Madden, D.W. Roberts, J.C. Dearden. J. Chem. Inf. Model. 
49(11) (2009) 2572-87. 

[24] A. Llinas, R.C. Glen, J.M. Goodman. J. Chem. Inf. Model. 48(7) (2008) 1289-303. 

[25] A.J. Hopfinger, E.X. Esposito, A. Llinàs, R.C. Glen, J.M. Goodman. J. Chem. Inf. Model. 49(1) (2009) 
1-5. 

[26] M. Stuart, K. Box. Anal. Chem. 77(4) (2005) 983-990. 

[27] K.J. Box, G. Völgyi, E. Baka, M. Stuart, K. Takács-Novák, J.E.A. Comer. J. Pharm. Sci. 95(6) (2006) 
1298-1307. 

[28] K. Box, J.E. Comer, T. Gravestock, M. Stuart. Chem. Biodiversity 6(11) (2009) 1767-1788. 

[29] A. Fini, G. Fazio, G. Feroci. Int. J. Pharm. 126 (1995) 95-102. 

[30] M. Shalaeva, J. Kenseth, F. Lombardo, A. Bastin, A. J. Pharm. Sci. 97(7) (2008) 2581-2606. 

[31] K.G. Mooney, M.A. Mintun, K.J. Himmelstein, V.J. Stella. J. Pharm. Sci. 70(1) (1981) 13-22. 

[32] B. Tsvetkova, I. Pencheva, A. Zlatkov, P. Peikov. Int. J. Pharm. Sci. 4(Supplement 3) (2012) 549. 

[33] S.A. Raina, G.Z. Zhang, D.E. Alonzo, J. Wu,D. Zhu,N.D. Catron, Y. Gao, L.S. Taylor. J. Pharm. Sci. 
2014, DOI: 10.1002/jps.23826 

[34] A. Avdeef. Pharm. Pharmacol. Commun. 4 (1998) 165-178. 

[35] M.Z. Southard, D.W. Green, V.J. Stella, K.J. Himmelstein. Pharm. Res. 9(1) (1992) 58-69. 

[36] K. Okimoto, R.A. Rajewski, K. Uekama, J.A. Jona, V.J. Stella. Pharm. Res. 13(2) (1996) 256-64. 

[37] C.M. Wassvik, A.G. Holmen, C.A. Bergstrom, I. Zamora, P. Artursson. Eur. J. Pharm. Sci. 29(3-4) 
(2006) 294-305. 

[38] J.H. Fagerberg, O. Tsinman, N. Sun, K. Tsinman, A. Avdeef, C.A. Bergstrom. Mol. Pharm. 7(5) (2010) 
1419-30. 

[39] Simulations Plus, Inc. 42505 10th Street West Lancaster, CA 93534, USA. http://www.simulations-
plus.com/ 

[40] StarDrop: Optibrium Ltd. 7221 Cambridge Research Park Beach Drive Cambridge CB25 9TL, UK. 
http://www.optibrium.com/starvue/index.php 

http://www.simulations-plus.com/
http://www.simulations-plus.com/
http://www.optibrium.com/starvue/index.php


Comer et al.   ADMET & DMPK 1(2) (2014) 18-32 

30  

[41] CSlogWS: ChemSilico LLC, 48 Baldwin St. Tewksbury, MA 01876, USA. http://www.chemsilico.com/ 

[42] ALOGPS:  I.V. Tetko, J. Gasteiger, R. Todeschini, A. Mauri, D. Livingstone, P. Ertl, V.A. Palyulin, E.V. 
Radchenko, N.S. Zefirov, A.S. Makarenko, V.Y. Tanchuk, V.V. Prokopenko.  J. Comput. Aid. Mol. Des 
19 (2005) 453-463. 

[43] WSKOWWIN: http://www.epa.gov/oppt/exposure/pubs/episuite.htm 

[44] WATERNT: http://www.epa.gov/oppt/exposure/pubs/episuite.htm 

 
  

http://www.chemsilico.com/
http://www.epa.gov/oppt/exposure/pubs/episuite.htm
http://www.epa.gov/oppt/exposure/pubs/episuite.htm


ADMET & DMPK 2(1) (2014) 18-32 Indomethacin solubility 

doi: 10.5599/admet.2.1.33 31 

Appendix 

Indomethacin decomposition experiment 

Ionic strength adjusted water (10 mL, 0.15 M KCl) was added to indomethacin (130 mg, 0.36 mmol). The 

pH was brought to 12 by addition of KOH solution (1.73 mL, 0.5 M) and the solution was stirred for 40 min 

under nitrogen. The mixture was titrated towards low pH until precipitation was detected. 

Extraction of product of decomposition experiment 

The solution was brought to pH 1 by addition of aqueous HCl (3N). The aqueous layer was extracted with 

EtOAc (3 x 25 mL). The organic layers were combined, dried over Na2SO4 and the solvent was removed in 

vacuo to afford a white solid (100 mg).  

Identification of products of decomposition experiment 

1
H NMR (500 MHz, CDCl3, T = 298 K)  7.99 (2H, d, J = 8.5 Hz), 7.43 (2H, d, J = 8.5 Hz) corresponding to p-

chlorobenzoic acid. 

1
H NMR (500 MHz, CDCl3, T = 298 K)  7.76 (1H, br), 7.14 (1H, d, J = 8.7 Hz), 6.98 (1H, d, J = 2.2 Hz), 6.78 

(1H, dd, J = 8.7, 2.4 Hz), 3.84 (3H, s), 3.68 (2H, s), 2.37 (3H, s) corresponding to the substituted indole (1). 

LCMS Electrospray Ionisation: calc. for [M – H]
−
 218.08, found 218.4; calc. for p-chlorobenzoic acid 

C7H5
35

ClO2 [M – H]
−
 154.99, found 155.2 (75%); calc. for p­chlorobenzoic acid C7H5

37
ClO2 [M – H]

−
 156.99, 

found 157.2 (25%). 

Esterification of decomposition products 

The mixture of decomposition products was dissolved in MeOH (5 mL). HCl (1 M in MeOH, 1 mL) was 

added and the mixture was heated under reflux for 3 h, stirred at room temperature overnight, and heated 

under reflux again for 3.5 h. The solvent was concentrated in vacuo. Purification by flash column 

chromatography (SiO2, 20:1 40-60 petroleum ether / EtOAc for fraction I, and 4:1 40-60 petroleum 

ether / EtOAc for fraction II) afforded methyl p-chlorobenzoate (40 mg, fraction I), and (5-methoxy-2-

methyl-indol-3-yl) acetic acid methyl ester (2) (70 mg, fraction II). 

1
H NMR (500 MHz, CDCl3, T = 298 K)  7.92 (1H, s, NH), 7.07 (1H, d, J = 8.7 Hz, H7), 7.01 (1H, d, J = 2.2 Hz, 

H4), 6.78 (1H, dd, J = 8.7, 2.2 Hz, H6), 3.87 (3H, s, OMe), 3.68 (3H, s, COOMe), 3.68 (2H, s, CH2), 2.31 (3H, s, 

C2-Me). 

13
C NMR (125 MHz, CDCl3, T = 298 K)  172.8 (COO), 154.1 (C-5), 133.8 (C-2/3a/7a), 130.3 (C-2/3a/7a), 

128.9 (C-2/3a/7a), 111.1 (C-7), 110.9 (C-6), 104.2 (C-3), 100.5 (C-4), 56.0 (OMe), 52.0 (COOMe), 30.3 (CH2), 

11.7 (Me). 

Hydrolysis of 2 

A mixture of 2 (640 mg, 2.75 mmol) and LiOH•H2O (1.15 g, 27.5 mmol) in 1:1 THF:water (10 mL) was 

stirred for 23 h. Aqueous HCl (3 M, 5 mL) was added and the pH was brought to 4. The solution was 

saturated with NaCl and extracted with EtOAc (3 x 25 mL). The organic fractions were combined, dried over 

Na2SO4 and concentrated in vacuo. The product was recrystallised twice from hot ethanol to afford (5-

methoxy-2-methyl-indol-3-yl) acetic acid (5-Methoxy-2-methyl-3-indoleacetic acid, 1) (98 mg). 

1
H NMR (500 MHz, CDCl3, T = 298 K)  7.72 (1H, br, NH), 7.14 (1H, d, J = 8.7 Hz, H7), 6.96 (1H, d, 

J = 2.3 Hz, H4), 6.78 (1H, dd, J = 8.7, 2.4 Hz, H6), 3.84 (3H, s, OMe), 3.65 (2H, s, CH2), 2.35 (3H, s, Me).  



Comer et al.   ADMET & DMPK 1(2) (2014) 18-32 

32  

1
H NMR (500 MHz, CD3OD, T = 298 K)  7.11 (1H, d, J = 8.7 Hz, H7), 6.95 (1H, d, J = 2.4 Hz, H4), 6.67 (1H, 

dd, J = 8.7, 2.4 Hz, H6), 3.79 (3H, s, OMe), 3.61 (2H, s, CH2), 2.34 (3H, s, Me). 

13
C NMR (125 MHz, CD3OD, T = 298 K)  176.2 (COO), 155.0 (C5), 135.0 (C2/3a/7a), 132.1 (C2/3a/7a), 

130.2 (C2/3a/7a), 111.9 (C7), 111.2 (C6), 104.8 (C3), 101.2 (C4), 56.3 (OMe), 30.9 (CH2), 11.4 (Me). 

 

 

 

 

 

 

©2014 by the authors; licensee IAPC, Zagreb, Croatia. This article is an open-access article distributed under the terms and 

conditions of the Creative Commons Attribution license (http://creativecommons.org/licenses/by/3.0/)  

http://creativecommons.org/licenses/by/3.0/