Characterization of 3-Aminopropyl Oligosilsesquioxane - Analytical

Mar 28, 2016 - ... distribution (MWD) of an oligosilsesquioxane synthesized in-house from ... The novelty of the method lies on the unique determinati...
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Characterization of 3-Aminopropyl Oligosilsesquioxane Ian Ken de Pedro Dimzon, Tobias Frömel, and Thomas P. Knepper Anal. Chem., Just Accepted Manuscript • DOI: 10.1021/acs.analchem.6b00732 • Publication Date (Web): 28 Mar 2016 Downloaded from http://pubs.acs.org on April 11, 2016

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Characterization of 3-Aminopropyl Oligosilsesquioxane Ian Ken D. Dimzon, Tobias Frömel and Thomas P. Knepper Hochschule Fresenius Institute for Analytical Research Limburger St. 2, 65510 Idstein, Germany

ABSTRACT

The synthesis routes in the production of polysilsesquioxanes have largely relied upon in situ formations. This perspective often leads to polymers in which their basic structures including molecular weight and functionality are unknown1. For a better understanding of the polysilsesquioxane properties and applications, there is a need to develop more techniques to enable their chemical characterization. An innovative method was developed to determine the molecular weight distribution (MWD) of an oligosilsesquioxane synthesized in-house from (3aminopropyl)triethoxysilane. This method, which can be applied to other silsesquioxanes, siloxanes and similar oligomers and polymers, involved separation using high performance liquid chromatography (HPLC) and detection using mass spectrometry (MS) with electrospray ionization (ESI). The novelty of the method lies on the unique determination of the absolute concentrations of the individual homologues present in the sample formulation. The use of absolute concentrations is necessary in estimating the MWD of the formulation when relative percentage, which is based solely on mass spectral ion intensities, becomes irrelevant due to the disproportionate response factors of the homologues. Determination of absolute concentration requires the use of single homologue calibration standards. Because of commercial unavailability, these standards were prepared by efficient fractionation of the original formulation.

1

Lichtenhan, J.D. et al., Silsesquioxane-siloxane copolymers from polyhedral silsesquioxanes.

Macromolecules, 1993. 26(8): p. 2141-2142

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1. Introduction Polysilsesquioxanes refer in general to the polymers whose backbone structure is alternating oxygen and silicon atoms with [RSiO3/2] as repeat units.1,2 These Si-containing polymers can be differentiated from polysiloxanes that have repeat units of [R2SiO].2 Polymeric silsesquioxanes are more thermally stable and have higher chemical resistance compared to polysiloxanes because of the three-fold coordination of Si with O. The additional Si-O-Si bridges create an added stability within a molecule.2,3 The applications of silsesquioxanes can be wide-ranging and are largely dependent on the attached R groups.4 Silsesquioxanes are also used as building blocks of ceramics, nanoparticles, hybrid materials and dendrimers.5-9 Aside from molecular weight and the degree of polymerization (n), another important parameter in silsesquioxane characterization is the degree of intramolecular condensation. Intramolecular condensation creates more Si-O-Si bridges within the molecule from the silanol groups (Si-OH)2. High degree of intramolecular condensation leads to the formation of polyhedral oligosilsesquioxanes.6 The silsesquioxanes can be partially or completely condensed. The overall general structure of silsesquioxanes could be random, ladder, cage and partial-cage.5 Highly controlled and selective silsesquioxane synthesis can be complex and is dependent on different empirical conditions.6 Synthesis routes have largely relied upon in situ formation of silsesquioxanes.10 This perspective often leads to polymers in which the correspondence between a specific synthetic route and the physical properties of the products is well established but the basic structures including molecular weight and functionality are unknown.10 There are already some methods available in the literature that deals with partial physico-chemical characterization of silsesquioxanes based on size-exclusion chromatography (SEC)11,12; infrared (IR)11,13,14 and nuclear magnetic resonance (NMR)11,12,15 spectroscopy; and mass spectrometry (MS)12,16,17. The information derived from the current methods is limited to average molecular weights for SEC and to functional group characterization for IR, NMR and MS. These methods can further be developed via a multi-technique approach so as to extract more information on the nature of silsesquioxanes including the molecular weight and chemical structures of the individual species present in a formulation. Mass spectrometry, particularly with electrospray ionization (ESI) and matrix-assisted laser desorption ionization (MALDI) techniques, has been used to characterize silsesquioxanes.2,3,18-20 For example, the product from hydrolytic condensation of (3-glycidoxypropyl)trimethoxysilane was characterized using ESI and MALDI with a time-of-flight mass analyzer (TOF).20 ESI-TOF

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resulted in doubly protonated molecules [M+2H]2+ of the polymer. MALDI-TOF, on the other hand, gave singly protonated or sodiated molecules. Mass discrimination was observed in both ESI and MALDI. In ESI-TOF analysis, only the lower molecular weight compounds (720 to 1500 Da) were observed whereas in the MALDI-TOF analysis, the low and medium molecular weight peak clusters were detected (up to 4000 Da).20 For some homologues, a noticeable pattern of equidistant peaks differing by 18 Da were observed and were attributed to loss of water during intramolecular condensation.2 The loss of water can occur either in-solution or in-MS. ESI and MALDI were used to characterize the polyhedral silsesquioxane product of the hydrolytic condensation of N-(β-aminoethyl)-γ-aminopropyltrimethoxysilane and phenyl glycidyl ester.21 The differences in the molecular weight distributions obtained using MALDI and ESI highlights the problem of MS as a tool in polymer characterization. One way to overcome this problem is to be able to quantify each homologue separately using chromatographic separation and standard solutions. There is recent interest in the determination of the molecular weight distribution (MWD) of polymers as well as the molecular weight of every molecule present in a polymer formulation. Aside from being essential in studying the properties of these polymers in relation to their structures, accurate MWD and molecular weight data can be used in studying the impact of these compounds when released into the environment including their degradation.22 Si-based polymers are not always studied in terms of their biodegradation,23 fate and the risk they pose to the environment. This can be due to the lack of appropriate techniques that can be used to study them. In this study, we report on our attempt to determine the MWD of oligosilsesquioxane synthesized by acid-catalyzed hydrolytic condensation of (3-aminopropyl)triethoxy silane. The method involved the use multi-technique approach that includes high performance liquid chromatography (HPLC), MS and induced-coupled plasma optical emission spectrophotometry (ICP-OES). When taken individually, the analytical methods employed are simple and are widely-used. What is more innovative is the use of the different methods together in such a way that the actual molecular weight distribution and at the same time, the chemical structures of the silsesquioxane under study can be derived. This is a task that is difficult if not impossible to achieve using single technique approaches.

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2. Methodology 2.1. Oligosilsesquioxane formulation The silsesquioxane formulation was prepared by dissolving the (3-aminopropyl)triethoxy silane in enough Milli-Q water (Millipore) to produce 10% (w/v). The mixture was then acidified to pH 4 using nitric acid and was left to react for a period of 24 h. This mixture was used as the silsesquioxane formulation. 2.2. ESI-Q-MS of the oligosilsesquioxane formulation A working solution was prepared by diluting the oligosilsesquioxane formulation to 1/200 in 5+95 (V+V) MilliQ water in methanol. The working solution was introduced directly into the AB Sciex API 2000 (AB Sciex, Darmstadt, Germany) in the ESI mode interfaced to a triple quadrupole mass analyzer, through a syringe pump at the rate of 10 µL/min. The ESI was operated in the positive ion mode with the following parameters: ion spray voltage, 5500 V; curtain gas, 25 psi; ion source gas 1, 10 psi; declustering potential, 160 - 200 V (max); focusing potential, 400 V; and entrance potential, 10 V. The mass spectrum was acquired in ‘Q1MS’ mode (Q1 scans, no collision, Q3 in RF-only mode), within the m/z 100-1800 mass range and 2 s cycle time. 2.3. MALDI-ToF-MS of the oligosilsesquioxane formulation A stock solution was prepared by diluting the oligosilsesquioxane formulation 1/10 using methanol. Equal volumes of the oligosilsesquioxane stock and 20 mg/mL 2,5-dihydroxybenzoic acid (2,5-DHB) in water (matrix solution) were mixed in a separate vial. A 1 µL drop of the mixture was placed on a stainless steel target and was allowed to dry under the normal room condition. The analysis was performed on a Biflex™ III Bruker Daltonics MALDI-TOF MS with a nitrogen laser emitting at a wavelength of 337 nm in the reflector mode and pulsed for 3 ns. The signals monitored were from positive ions in the 0 ≤ m/z ≤ 7000 range. Unless stated differently, the spectra shown were the sum of 150 shots (5 points x 30 shots/point) at 20-40 % laser attenuation. The instrument was externally calibrated using the generated mass spectrum of poly(ethylene glycol) standard (Mp = 1000) with 2,5-DHB as matrix at 30% laser attenuation. 2.4. Fractionation of the oligosilsesquioxane Ten microliters of oligosilsesquioxane formulation was injected into an HP1090 LC (HP Agilent; Santa Clara, California, USA) equipped with Kromasil 100-5 C18 column (5 µm particle size, 100 Ǻ pore size, 8 mm internal diameter, 250 mm length) and UV diode array detector. The 4 ACS Paragon Plus Environment

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separation of oligosilsesquioxane homologues was made possible in a gradient of 5 mM perfluoroheptanoic acid in water (Eluent A) and 5 mM perfluoroheptanoic acid in methanol (Eluent B) at a flow rate maintained at 0.5 mL/min: Initially, 55% Eluent B for 5 min; increased to 95% Eluent B at a rate of 1%/min; maintained at 95% Eluent B for 15 min; decreased back to 55% Eluent B at rate of 4%/min, maintained at 55% Eluent B for 10 min. The elution of homologues was observed by monitoring the absorbances at 235 and 220 nm. Fractions were collected at retention times that correspond to specific homologues. The composition of each collected fraction was confirmed using ESI-MS. 2.5. ICP-OES analysis of the fractions The homologue concentration in each fraction was quantified indirectly by determining Si using Spectro Ciros CCD ICP-OES equipped with a cross flow nebulizer and quartz torch (Spectro; Kleve, Germany). Calibration solutions containing 0.1 to 4.0 µg/mL of Si were prepared from (3aminopropyl)triethoxysilane. The calibration curve was set to linear and had a coefficient of determination (R2) of 0.9991. All solutions were diluted using Milli-Q water. Quantification was performed by monitoring the 212.41 nm Si emission line after method development with three other emission lines including: 152.67, 251.61 and 288.16 nm. The method limit of quantification was 0.1 µg /mL. Another silane, the dichlorodimethylsilane was used as quality control standard. A dilute solution of this was prepared in Milli-Q water at concentration of 0.25 and 0.50 µg Si/mL. Analysis of these two solutions against the (3-aminopropyl) triethoxysilane calibration curve gave a result of 120% and 104% recoveries respectively. Fractions containing single homologues of n=3, 4, 5 and 6 were analyzed in ICP-OES. The obtained Si concentration value in each fraction was re-expressed so that the final unit was in nmol Si/mL. To calculate the final concentration in terms of nmol polymer molecule/mL, the concentrations in nmol Si/mL were divided by the degree of polymerization.

2.6. Determination of the MWD of the oligosilsesquioxane formulation A working solution was prepared by diluting the oligosilsesquioxane formulation to 1/100 in 5+95 (V/V) MilliQ water in methanol. Agilent HPLC with 50 mm Kromasil 100-5 C18 column with 10 mm guard column (5 µm particle size, 100 Ǻ pore size, 2.1 mm diameter). Separation of the oligosilsesquioxane homologues was made possible in the gradient of 5 mM perfluoroheptanoic acid in water (Eluent A) and 5 mM perfluoroheptanoic acid in methanol (Eluent B) at a flow rate

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maintained at 0.20 mL/min: Initially, 55% Eluent B for 1 min; increased to 95% Eluent B at a rate of 4%/min; maintained at 95% Eluent B for 15 min; decreased back to 55% Eluent B at rate of 8%/min, maintained at 55% Eluent B for 4 min.The analytes were detected in the AB Sciex API 2000 MS with ESI, in the Q1 selected ion monitoring mode. Fractions containing a single homologue were analyzed in the ICP-OES and used as calibration standards.

3. Results and Discussion 3.1. MS analysis of the 3-aminopropyl oligosilsesquioxane prior to fractionation The synthesis of silsesquioxanes can be done via acid-catalyzed or base-catalyzed reactions. Base-catalysis results in gels and colloidal particles. On the other hand, acid-catalysis produces weakly-branched polymers of various shapes.4,24 The acid-catalyzed reaction of (3aminopropyl)triethoxysilane to produce the oligosilsesquioxanes involves two steps as shown in Figure 1: first is the hydrolysis of the monomers producing highly reactive silanols and ethanol; and second is the condensation reaction producing the oligomers and water. The n of the silsesquioxane formed in the example in Figure 1 is four. The reaction mixture after 24 h, was used as the in situ oligosilsesquioxane formulation to be characterized. The formulation was found to be stable at normal room conditions. No further polymerization was observed when the formulation was analyzed over several months. The oligosilsesquioxane formulation was surveyed by direct injection into the ESI-Q-MS. Figure 2A shows the generated mass spectrum in the positive ion mode. The oligosilsesquioxane homologues present have n in the range from 2 to 12. There are also hydrolyzed but nonpolymerized monomers present in the formulation. The expected molecular weights of ions resulting from condensation of the monomers assuming that only polymerization occurred are not present. For example, for n=6 (Figure 2A insert), the expected m/z of a singly-charged ion (protonated molecule) is 733, accounting for six 3-aminopropyl silsesquioxane repeating units. Instead of m/z 733 one finds lower masses with equidistant peaks differing by m/z 18.The singly charged ions with m/z 661, 643, 625 and 608 are product masses after losses of 4, 5, 6 and 7 more H2O molecules, respectively. This further loss of H2O is due to intramolecular condensation in the solution to form the Si-O-Si bridges (in-solution). It is also possible that the intramolecular condensation is triggered further by the ESI process (in-MS). The extent of further H2O loss after polymerization is described by the degree of intramolecular condensation. The degree of intramolecular condensation described in this paper does not differentiate between the reactions that happened in-solution and in-MS. Figure 1 shows two different

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products of intramolecular condensation. The formation of a fully condensed polyhedral silsesquioxane is favored in-solution as it is catalyzed by the acidic environment.24 On the other hand, formation of Si=C bonds in silenes in-solution is highly unlikely. The process usually involves high energy conditions or irreversible elimination of stable salts.25 Also, silenes are very unstable although they can be partially stabilized by steric protection and by reversed Si=C bond polarization when there are π-donor substituents in the C atom.25

Figure 1. General reaction scheme in the formation of oligosilsesquioxane (n=4) from (3aminopropyl)triethoxy silane and the formation of a fully condensed polyhedral silsesquioxane (in-solution or in MS) or a silene by intramolecular condensation (in-MS). 7 ACS Paragon Plus Environment

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Figure 2. Positive-mode mass spectra of 3-aminopropyl oligosilsesquioxane in methanol: A. ESI-Q at declustering potential of 160 V; and B. MALDI-TOF mass spectrum with 2,5-DHB as matrix. Inserts: Zoomed in region showing the ions with n=6. 8 ACS Paragon Plus Environment

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MALDI-TOF MS was also carried out in addition to the ESI-Q-MS analysis. The silsesquioxane formulation was mixed with the solution of 2,5-DHB in water. The mixture was then spotted into a stainless steel target for analysis. The positive ion mode MALDI-TOF mass spectrum of the sample is shown in Figure 2B. The ions formed were protonated molecules. This is different from the generated ions of other silsesquioxanes by MALDI which were cation and proton adducts.3,20,21 Moreover, it was noted in a previous study that the degree of intramolecular condensation is proportional to n.3 The ions generated from both ESI and MALDI are plotted in a graph of n versus degree of intramolecular condensation in Figure 3. Two differences are readily observed. First, the ESI graph showed a wider range of intramolecular condensation than MALDI. And second, the mode-average molecular weights (Mm) obtained by ESI-Q-MS (n=3) is lower than in MALDITOF-MS (n=9). It is difficult to assess the extent to which the ESI and MALDI can trigger further intramolecular condensation. It is known that different ionization techniques can result in major differences in the MWD of polymers. Mechanisms of ion formation in ESI and MALDI are entirely different from each other and each will have its own unique limitation.26 In MALDI, the type of matrix used and the manner of spot preparation are optimized so that the polymer molecules are easily desorbed then ionized in the gas phase. In contrast, in ESI, the solvent buffer and several instrumental parameters are tested to maximize ion intensities. The nonappearance of highly-condensed ions in the MALDI spectrum can be due to either the inability of the MALDI process to desorb and ionize the highly-condensed silsesquioxanes in the formulation; or that MALDI process is unable to trigger as in ESI the further condensation of less-condensed silsesquioxanes in the solution. Furthermore, the ESI-MS uses a stream of nitrogen in between the ESI and the first quadrupole, which can further cause fragmentation and thus increase the observed degree of condensation. Because of the limitations of each ionization technique, the methods are unable to give accurate information on the relative abundance of the species present in the formulation.

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Figure 3. Comparison of the degree of polymerization and degree of intramolecular condensation of the ions generated in: A. ESI and B. MALDI.

The degree of intramolecular condensation needed to produce a fully-condensed polyhedral silsesquioxane, t, is given by Equations 1 and 23. t = 0.5n + 1

(if n is even)

Equation 1

t = 0.5 (n - 1) + 1

(if n is odd)

Equation 2

The maximum condensation that can occur to produce the Si-O-Si bridges given a certain n is given by t. Equation 1 is drawn in Figure 3. This line represents the maximum in-solution intramolecular condensation. It can be observed that most of the points are above the line t = 0.5n + 1. Therefore, one can infer that Si-O-Si bridges are not the only products of intramolecular condensation. One possible reaction that leads to more losses of H2O could be the formation of Si=C bond or silenes in the gas phase. If this reaction occurs, the maximum degree of intramolecular condensation leading to the formation of Si=C bonds and a single ring, s, is given by Equation 3. s=n+1

Equation 3

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Equation 3 is also drawn in Figure 3. It can be observed that most of the points either in ESI or in MALDI are between the lines t = 0.5n + 1 and s = n + 1. These points represent molecules that have undergone further condensation beyond the limits if they are to form the fully condensed polyhedral geometry. If these further condensations led to the formation of silenes, then these further condensations must have occurred in the gas phase in the MS. There is no way of differentiating the separate extent of these two different condensation reactions by solely relying on the mass spectral data. Thus, no conclusion can be made as to the extent of the formation of the Si-O-Si bridges in the formulation. The degree of intramolecular condensation as observed in the mass spectra is dependent on the type of MS being used. To gain insight on the oligomer distribution, it was necessary to perform a chromatographic separation and to determine the absolute concentration of the individual homologues in the formulation. The next sections describe the development of an HPLC method to achieve these goals.

3.2. Fractionation of the 3-aminopropyl oligosilsesquioxane formulation In weakly acidic solution, 3-aminopropyl oligosilsesquioxane compound is ionic and highly polar due to the amino and the hydroxyl groups present in the molecules. Size exclusion chromatography is not suitable to separate the different homologues of the oligosilsesquioxane. Because of their highly polar nature, chromatographic separation of the homologues using the traditional reversed-phase techniques (for example, using C18 column) and hydrophilic chromatography (HILIC) are also not possible. To enable the separation of the homologues, an ion-pair reagent is added into the eluent to enhance the interaction between the compounds to be separated and the stationary phase. Perfluoroheptanoic acid (PFHpA) was used as an ion-pair reagent to strengthen the interaction of the oligosilsesquioxane homologues and the C18 stationary phase. The number of possible ion-pairing for an oligosilsesquioxane homologue is proportional to its degree of polymerization. The higher the n, the more amine groups are available where the perfluoroheptanoic acid can attach to. Consequently, this results to more interaction with the C18 stationary phase and to a slower migration rate. Fractionation was achieved in the gradient of water and methanol with 5 mM PFHpA in a semi-preparative C18 column with DAD detector. The fraction corresponding to a homologue was collected at a retention time set after a thorough optimization. The composition of each fraction was confirmed using ESI-Q MS. The fractionation process allowed the separation of homologues (see Supporting Information, SI1 for the chromatogram) making the resulting fractions less polydispersed and less complex 11 ACS Paragon Plus Environment

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to be analyzed in the ESI-Q-MS. Table 1 shows the different homologues contained in different collected fractions. Some fractions can contain more than one homologue. The mass spectra of the collected fractions are shown in the Supporting Information, SI2. The mass spectra of fractions containing homologues with n= 5, 7 and 11 are shown in Figure 4- A, B and C respectively. Table 1. Detected oligosiloxane in each of the collected fraction in the region between 37.0 min. and 42.6 min. Fraction*

Retention Time (min)

Detected Oligosiloxane Homologue (n)

17

37.0 – 37.4

3

18

37.4 – 37.8

3, 4

19

37.8 – 38.2

4

20

38.2 – 38.6

5

21

38.6 – 39.0

6

22

39.0 – 39.4

6

23

39.4 – 39.8

7

24

39.8 – 40.2

8

25

40.2 – 40.6

8, 9

26

40.6 – 41.0

10

27

41.0 – 41.4

10

28

41.4 – 41.8

11

29

41.8 – 42.2

11, 12

30

42.2 – 42.6

12

*The number labels of the fractions are arbitrary and could differ from one run to another. Nonetheless, the fraction number is included in the table for easy references to the ESI-q mass spectra in Appendix. The more important nd parameter is the retention time interval (2 column) in which a certain fraction is collected.

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Figure 4. Positive-mode ESI-Q mass spectra of fractions containing oligosilsesquioxanes of n = 5, 7 and 11 (A-C) respectively. The x represents the charge of the ions.

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It can be observed that at higher n, multiply-charged ions are favored by the ESI process. For example, at n=7, two patterns of the same compounds appear in the mass spectrum. One form results from the singly charged species while the other form originates from doubly-charged species. The mass differences of 18 and 9 for these forms reflect the intramolecular condensation of the singly- and doubly-charged ions, respectively. For n=11, the singly-charged form occurred minimally while the doubly- and triply-charged forms were more pronounced. Multiple charging is highly probable at higher n since the number of amino groups that can accept extra protons is proportional to n. Doubly-charged ions with even-numbered n can have m/z that are almost equal to the m/z of singly charged ions with n/2 degree of polymerization. Multiple charging was not observed in the ESI mass spectrum of unfractionated formulation. This highlights the need to study thoroughly and optimize the ESI process before a conclusion can be made regarding the relative amount of the homologues present in the formulation. Single-homologue containing fractions can be used as calibration standards in the LC-ESI-QMS determination of the absolute and relative molar concentration of the individual homologues as well as the MWD of the 3-aminopropyl oligosilsesquioxane formulation. Fraction collection was repeated several times to gather a significant amount for use as HPLC calibration standard. The purity of the fractions was checked by ESI-Q MS. For some homologues, it was difficult to obtain a fraction that is free of other homologues. These cannot be used as standards. The molar concentration of the silsesquioxane in single-homologue containing fractions was estimated using the Si emission lines in the ICP-OES. The emission at 212.4 nm gave a low baseline and was free from matrix interferences and was used in the quantification Si in the fractions.

3.4. Determination of the MWD of the oligosilsesquioxane by HPLC-ESI-Q-MS The oligosilsesquioxane formulation was introduced into an HPLC with analytical C18 column and interfaced to ESI-QqQ-MS. The mobile phases used were water and methanol with 5mM perfluoroheptanoic acid as ion pair reagent. Selected ions were monitored in the Q1. The list of the m/z monitored for each homologue from n=3 to n=12 is included in the Supporting Information (SI3). The different m/z per homologue results from varying degree of intramolecular condensation and charging. The main criterion in the selection of ions to be included in the list is their appearance or detection in the scan mass spectra of the fractions. The elution of the different homologues of the oligosilsesquioxane is shown in Figure 5. Some m/z represents two different homologues. For example, m/z 405 and 423 can either be the doubly-charged ions of

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homologues with n=8 or the singly-charged ions of homologues with n=4. Nonetheless, they are well separated in the C18 column and will not be a problem in the analysis.

Figure 5. Elution of the oligosilsesquioxane homologues in the C18 column and in the gradient of water and methanol with 5 mM PFHpA.

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For quantification, the sum of the chromatographic areas of all the selected m/z per homologue was calculated. Three to four levels of calibration standards were prepared from the singlehomologue containing fractions (n= 3, 4, 5 and 6) to generate the calibration curves. The reciprocal of the slopes of the calibration curves can be used as response factors to quantify the homologues in the formulation. The slopes of the calibration curves were plotted versus n as shown in SI4 (Supporting Information). This empirical correspondence can be used to extrapolate the slopes and the response factors for the homologues with n= 7 to 12. The response factors (experimental response factors for n= 3 to 6 and empirical response factors for n=7 to 14) were used to determine the concentration of the homologues in the fraction. The final MWD was obtained after normalization relative to the homologue with highest molar concentration (Figure 6). It is a bimodal distribution with n=3 and n=9 having the highest relative abundance. This distribution can be optimal degree of polymerization and can attributed to the conditions during synthesis. The absolute molecular weights of the individual homologue in the solution cannot be determined from MS because of the problem of further condensation in the gas phase. Thus, an accurate calculation of the dispersity index will not be possible. The MWD shown in Figure 7 is better expressed as a degree of polymerization distribution instead.

Figure 6. MWD of oligosilsesquioxane obtained by HPLC-ESI-Q MS 16 ACS Paragon Plus Environment

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4. Conclusion The use and applications of oligomers and polymers are dependent on the base structure of the monomer, the average MW and the dispersity index. For oligosilsesquioxanes, the amount of Si-O-Si is additionally studied to determine the stability of the structure. The more Si-O-Si bridges present in the silsesquioxane structure the higher is the stability of the molecule. The individual absolute molecular weight information from ESI or MALDI MS can be used to correlate in a more quantitative way this relationship when the formulation is additionally characterized for its physical properties. The same physico-chemical properties also dictate the behavior of these substances when released into the environment, for example, toxicity, fate and degradation. The determination of the MWD of highly complex oligomers and polymers like the silsesquioxanes will not be possible using MS alone. In this paper, direct MS analysis using soft ionization techniques like ESI and MALDI gave contrasting MWD for the 3-aminopropyl oligosilsesquioxane formulation. ESI and MALDI are two different ionization processes; and the relative intensities of ions in the ESI and MALDI mass spectra are not directly translatable to MWD. The extent of ionization is affected by the functionality and the degree of polymerization of the polymers. This necessitated the development of a method with LC separation prior to MS detection and with absolute determination of concentration using single-homologue standards. The method used in this research can also be applied to other complex polymer formulation provided: 1. There is an efficient fractionation method to separate the different unique molecules in the formulation; and 2. There is a way of quantifying the molecule. Efficient fractionation can be done by using specialized columns, addition of ion-pairs, and optimization of mobile phase and the eluent gradient. Quantification of the unique fractions to be used as calibration standards can include spectroscopic techniques like UV-Vis and nuclear magnetic resonance as well as another chromatographic technique. With this method, the absolute and relative concentrations and the absolute molecular weights of each homologue were easily determined. These are vital information to be able to correlate the structure of the silsesquioxane with its properties and activity. The applicability of the method can be extended to other polysilsesquioxanes and polysiloxanes.

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Supporting Information Chromatograms of the fractionation of the silsesquioxane formulation using HPLC-UV (SI1); ESI-q MS of the collected fractions from the ion-pair separation of oligosiloxanes (SI2); Selected ions monitored in the HPLC ESI-Q MS; and Degree of polymerization (n) versus the slope of the calibration curve (SI4)

Corresponding Author: Thomas P. Knepper; [email protected], (+49) 61269352 64 Acknowledgement This research work was funded in part by the European Commission under the project Environmental Chemoinformatics – Initial Training Network (ITN No. 238701).

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(21) Fasce, D. P.; Williams, R. J. J.; Erra-Balsells, R.; Ishikawa, Y.; Nonami, H. Macromolecules 2001, 34, 3534-3539. (22) Bernhard, M.; Eubeler, J. P.; Zok, S.; Knepper, T. P. Water Res. 2008, 42, 4791-4801. (23) Eubeler, J. P.; Bernhard, M.; Knepper, T. P. TrAC, Trends Anal. Chem. 2010, 29, 84-100. (24) Brinker, C. J. J. Non-Cryst. Solids 1988, 100, 31-50. (25) Ottosson, H.; Steel, P. G. Chemistry – A European Journal 2006, 12, 1576-1585. (26) Dimzon, I. K. D.; Knepper, T. P. MALDI-TOF MS for characterization of synthetic polymers in aqueous environment; Elsevier: Amsterdam, 2012; Vol. 58.

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Table of Content graphic 389x145mm (96 x 96 DPI)

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