Peter Kroll scite author profile

Nonionic poly(ethylene oxide) alkyl ether (C i E j ) surfactants self-assemble into aggregates of various sizes and shapes above their critical micelle concentration (CMC). Knowledge on solution attributes such as CMC as well as aggregate characteristics is crucial to choose the appropriate surfactant for a given application, e.g., as a micellar solvent system. In this work, we used static and dynamic light scattering to measure the CMC, aggregation number ( N agg ), and hydrodynamic radius ( R h ) of four different C i E j surfactants (C 8 E 5 , C 8 E 6 , C 10 E 6 , and C 10 E 8 ). We examined the influence of temperature, concentration, and molecular structure on the self-assembly in the vicinity of the CMC. A minimum in the CMC vs temperature curve was identified for all surfactants investigated. Further, extending the hydrophilic and hydrophobic chain lengths leads to an increase and decrease of the CMC, respectively. The size of the aggregates strongly depends on temperature. N agg and R h increase with increasing temperature for all surfactants investigated. Additionally, N agg and R h both increase with increasing surfactant concentration. The data obtained in this work further improve the understanding of the influence of temperature and molecular structure on the self-assembly of C i E j surfactants and will further foster their use in micellar solvent systems.

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Solubilization of Aldehydes and Amines in Aqueous C_iE_j Surfactant Aggregates: Solubilization Capacity and Aggregate Properties

Kroll

Sadowski

Brandenbusch

2022

Langmuir

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Hydroformylation of olefins to aldehydes and subsequent reductive amination of aldehydes to amines takes place in an aqueous system using a water-soluble catalyst. It is limited to short-chain molecules due to an insufficient solubility of long-chain molecules in water. A promising approach to increase the solubility of long-chain aldehydes and amines is the addition of surfactants to the aqueous phase. In this work, we thus determined the solubilization capacity (SC) of different nonionic C i E j surfactants (C 8 E 6 , C 10 E 6 , and C 10 E 8 ) toward long-chain aldehydes and amines. We used static and dynamic light scattering techniques to investigate the influence of both the surfactant and solute molecular structures on the SC as well as on the aggregation number (N agg ) and hydrodynamic radius (R h ) of mixed aggregates. Our data reveals that an optimum ratio of hydrophobic to hydrophilic chain length of C i E j surfactants exists where the SC toward long-chain aldehydes and amines possesses a maximum. Further, the size of the aggregates (N agg , R h ) passes through a minimum upon amine solubilization, while upon aldehyde solubilization, the aggregate size increases gradually. The results shown in this work give valuable insights to the solubilization of aldehydes and n-amines into nonionic C i E j surfactants and facilitate the search of suitable surfactants for hydroformylation and reductive amination as "green" solvents based on the detailed knowledge about the aggregate structure.

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Predicting the API partitioning between lipid-based drug delivery systems and water

Brinkmann

Becker

Kroll

et al. 2021

International Journal of Pharmaceutics

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Influence of Hydrophobic and Hydrophilic Chain Length of C_iE_j Surfactants on the Solubilization of Active Pharmaceutical Ingredients

et al. 2022

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Up to 90% of all newly developed active pharmaceutical ingredients (APIs) are poorly water soluble, most likely also showing a low oral bioavailability. In order to increase the aqueous solubility of these APIs, surfactants are promising excipients to increase both solubility and consequently bioavailability (e.g., in lipidand surfactant-based drug delivery systems). In this work, we investigated the influence of hydrophobic and hydrophilic chain lengths of C i E j surfactants (C 8 E 6 , C 10 E 6 , and C 10 E 8 ) toward the solubilization of fenofibrate, naproxen, and lidocaine. Furthermore, we investigated the partitioning of these APIs between the surfactant aggregates and the surrounding aqueous bulk phase. For all APIs considered, we determined the locus of API solubilization as well as the individual aggregation numbers (N agg ) of surfactants and API molecules in an API/surfactant aggregate. We further determined the hydrodynamic radius (R h ) of the API/surfactant aggregates in the absence and presence of the APIs. The size of the API/surfactant aggregates (N agg , R h ) passes through a minimum upon lidocaine solubilization; it gradually increases upon naproxen solubilization and is almost constant upon fenofibrate solubilization. The results give valuable insights into the solubilization mechanisms of APIs in the C i E j surfactant aggregates. Our results reveal that fenofibrate is solely solubilized in the hydrophobic core of the C i E j surfactant aggregates, as only the hydrophobic chain length of the surfactant influences its solubilization. Naproxen is solubilized in the palisade layer of the surfactant aggregates, as both the hydrophobic and hydrophilic chain lengths are decisive for its solubilization. Lidocaine is mainly solubilized in the rather hydrophilic corona region of the surfactant aggregates, as the hydrophilic chain length of the surfactant governs its solubilization. The results further reveal that the hydrophilic/lipophilic balance is not an appropriate measure to estimate the solubilization capacity of surfactant aggregates.

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Peter Kroll

Influence of Temperature and Concentration on the Self-Assembly of Nonionic C_iE_j Surfactants: A Light Scattering Study

Solubilization of Aldehydes and Amines in Aqueous C_iE_j Surfactant Aggregates: Solubilization Capacity and Aggregate Properties

Predicting the API partitioning between lipid-based drug delivery systems and water

Influence of Hydrophobic and Hydrophilic Chain Length of C_iE_j Surfactants on the Solubilization of Active Pharmaceutical Ingredients

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Peter Kroll

Influence of Temperature and Concentration on the Self-Assembly of Nonionic CiEj Surfactants: A Light Scattering Study

Solubilization of Aldehydes and Amines in Aqueous CiEj Surfactant Aggregates: Solubilization Capacity and Aggregate Properties

Predicting the API partitioning between lipid-based drug delivery systems and water

Influence of Hydrophobic and Hydrophilic Chain Length of CiEj Surfactants on the Solubilization of Active Pharmaceutical Ingredients

Contact Info

Product

Resources

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Influence of Temperature and Concentration on the Self-Assembly of Nonionic C_iE_j Surfactants: A Light Scattering Study

Solubilization of Aldehydes and Amines in Aqueous C_iE_j Surfactant Aggregates: Solubilization Capacity and Aggregate Properties

Influence of Hydrophobic and Hydrophilic Chain Length of C_iE_j Surfactants on the Solubilization of Active Pharmaceutical Ingredients