Structure, morphology and surface properties of α-lactose monohydrate in relation to its powder properties

Structure, morphology and surface properties of α-lactose monohydrate in relation to its powder properties

The particulate properties of α-lactose monohydrate (αLMH), an excipient and carrier for pharmaceuticals, is important for the design, formulation and performance of a wide range of drug products. Here an integrated multi-scale workflow provides a detailed molecular and inter-molecular (synthonic) a...

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Veröffentlicht in:Journal of pharmaceutical sciences 2025-01, Vol.114 (1), p.507-519
Hauptverfasser: Nguyen, Thai T.H., Ma, Cai Y., Styliari, Ioanna D., Gajjar, Parmesh, Hammond, Robert B., Withers, Philip J., Murnane, Darragh, Roberts, Kevin J.
Format: Artikel
Sprache:eng
Schlagworte:
Crystallization - methods
Excipients - chemistry
Inhalation powdered drug formulations
Lactose - chemistry
Mechanical properties
Morphological characterisation
Particle Size
Powders - chemistry
Surface energy
Surface physical chemical properties
Surface Properties
Synthons and intermolecular interactions
X-ray computed tomography
X-Ray Diffraction - methods
Α-lactose monohydrate
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container_end_page 519
container_issue 1
container_start_page 507
container_title Journal of pharmaceutical sciences
container_volume 114
creator Nguyen, Thai T.H.
Ma, Cai Y.
Styliari, Ioanna D.
Gajjar, Parmesh
Hammond, Robert B.
Withers, Philip J.
Murnane, Darragh
Roberts, Kevin J.
description The particulate properties of α-lactose monohydrate (αLMH), an excipient and carrier for pharmaceuticals, is important for the design, formulation and performance of a wide range of drug products. Here an integrated multi-scale workflow provides a detailed molecular and inter-molecular (synthonic) analysis of its crystal morphology, surface chemistry and surface energy. Predicted morphologies are validated in 3D through X-ray diffraction (XCT) contrast tomography. Interestingly, from aqueous solution the fastest growth is found to lie along the b-axis, i.e. the longest unit cell dimension of the αLMH crystal structure reflecting the greater opportunities for solvation on the prism compared to the capping faces leading to the former's slower relative growth rates. The tomahawk morphology reflects the presence of β-lactose which asymmetrically binds to the capping surfaces creating a polar morphology. The crystal lattice energy is dominated by van der Waals interactions (between lactose molecules) with electrostatic interactions contributing the remainder. Predicted total surface energies are in good agreement with those measured at high surface coverage by inverse gas chromatography, albeit their dispersive contributions are found to be higher than those measured. The calculated surface energies of crystal habit surfaces are not found to be significantly different between different crystal surfaces, consistent with αLMH's known homogeneous binding to drug molecules when formulated. Surface energies for different morphologies reveals that crystals with the elongated crystal morphologies have lower surface energies compared to those with a triangular or tomahawk morphologies, correlating well with literature data that the surface energies of the lactose carriers are inversely proportional to their aerosol dispersion performance. A predictive workflow for inhalation drug formulation highlighting the 4-stage pathway from the molecular state through solid-state and surface properties to the blended powder. [Display omitted] •Lattice energy dominated by van der Waals interactions with electrostatic interactions contributing about 13%.•Predicted 3D crystal morphology agrees with aqueous solution grown data as measured using X-ray Computed Tomography.•Polar “tomahawk” morphology reflects differential adsorption of β-lactose molecules between {010} and {0-10} surfaces.•Predicted surface energies agree with IGC data albeit with higher predicted dispersive energies co
doi_str_mv 10.1016/j.xphs.2024.10.031
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Here an integrated multi-scale workflow provides a detailed molecular and inter-molecular (synthonic) analysis of its crystal morphology, surface chemistry and surface energy. Predicted morphologies are validated in 3D through X-ray diffraction (XCT) contrast tomography. Interestingly, from aqueous solution the fastest growth is found to lie along the b-axis, i.e. the longest unit cell dimension of the αLMH crystal structure reflecting the greater opportunities for solvation on the prism compared to the capping faces leading to the former's slower relative growth rates. The tomahawk morphology reflects the presence of β-lactose which asymmetrically binds to the capping surfaces creating a polar morphology. The crystal lattice energy is dominated by van der Waals interactions (between lactose molecules) with electrostatic interactions contributing the remainder. Predicted total surface energies are in good agreement with those measured at high surface coverage by inverse gas chromatography, albeit their dispersive contributions are found to be higher than those measured. The calculated surface energies of crystal habit surfaces are not found to be significantly different between different crystal surfaces, consistent with αLMH's known homogeneous binding to drug molecules when formulated. Surface energies for different morphologies reveals that crystals with the elongated crystal morphologies have lower surface energies compared to those with a triangular or tomahawk morphologies, correlating well with literature data that the surface energies of the lactose carriers are inversely proportional to their aerosol dispersion performance. A predictive workflow for inhalation drug formulation highlighting the 4-stage pathway from the molecular state through solid-state and surface properties to the blended powder. [Display omitted] •Lattice energy dominated by van der Waals interactions with electrostatic interactions contributing about 13%.•Predicted 3D crystal morphology agrees with aqueous solution grown data as measured using X-ray Computed Tomography.•Polar “tomahawk” morphology reflects differential adsorption of β-lactose molecules between {010} and {0-10} surfaces.•Predicted surface energies agree with IGC data albeit with higher predicted dispersive energies compared to measurements.•Low variation between face-specific surface energies consistent with observed homogenous binding of crystals when blended.</description><identifier>ISSN: 0022-3549</identifier><identifier>ISSN: 1520-6017</identifier><identifier>EISSN: 1520-6017</identifier><identifier>DOI: 10.1016/j.xphs.2024.10.031</identifier><identifier>PMID: 39481472</identifier><language>eng</language><publisher>United States: Elsevier Inc</publisher><subject>Crystallization - methods ; Excipients - chemistry ; Inhalation powdered drug formulations ; Lactose - chemistry ; Mechanical properties ; Morphological characterisation ; Particle Size ; Powders - chemistry ; Surface energy ; Surface physical chemical properties ; Surface Properties ; Synthons and intermolecular interactions ; X-ray computed tomography ; X-Ray Diffraction - methods ; Α-lactose monohydrate</subject><ispartof>Journal of pharmaceutical sciences, 2025-01, Vol.114 (1), p.507-519</ispartof><rights>2024 The Authors</rights><rights>Copyright © 2024 The Authors. 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Predicted total surface energies are in good agreement with those measured at high surface coverage by inverse gas chromatography, albeit their dispersive contributions are found to be higher than those measured. The calculated surface energies of crystal habit surfaces are not found to be significantly different between different crystal surfaces, consistent with αLMH's known homogeneous binding to drug molecules when formulated. Surface energies for different morphologies reveals that crystals with the elongated crystal morphologies have lower surface energies compared to those with a triangular or tomahawk morphologies, correlating well with literature data that the surface energies of the lactose carriers are inversely proportional to their aerosol dispersion performance. A predictive workflow for inhalation drug formulation highlighting the 4-stage pathway from the molecular state through solid-state and surface properties to the blended powder. 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Here an integrated multi-scale workflow provides a detailed molecular and inter-molecular (synthonic) analysis of its crystal morphology, surface chemistry and surface energy. Predicted morphologies are validated in 3D through X-ray diffraction (XCT) contrast tomography. Interestingly, from aqueous solution the fastest growth is found to lie along the b-axis, i.e. the longest unit cell dimension of the αLMH crystal structure reflecting the greater opportunities for solvation on the prism compared to the capping faces leading to the former's slower relative growth rates. The tomahawk morphology reflects the presence of β-lactose which asymmetrically binds to the capping surfaces creating a polar morphology. The crystal lattice energy is dominated by van der Waals interactions (between lactose molecules) with electrostatic interactions contributing the remainder. Predicted total surface energies are in good agreement with those measured at high surface coverage by inverse gas chromatography, albeit their dispersive contributions are found to be higher than those measured. The calculated surface energies of crystal habit surfaces are not found to be significantly different between different crystal surfaces, consistent with αLMH's known homogeneous binding to drug molecules when formulated. Surface energies for different morphologies reveals that crystals with the elongated crystal morphologies have lower surface energies compared to those with a triangular or tomahawk morphologies, correlating well with literature data that the surface energies of the lactose carriers are inversely proportional to their aerosol dispersion performance. A predictive workflow for inhalation drug formulation highlighting the 4-stage pathway from the molecular state through solid-state and surface properties to the blended powder. 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subjects Crystallization - methods
Excipients - chemistry
Inhalation powdered drug formulations
Lactose - chemistry
Mechanical properties
Morphological characterisation
Particle Size
Powders - chemistry
Surface energy
Surface physical chemical properties
Surface Properties
Synthons and intermolecular interactions
X-ray computed tomography
X-Ray Diffraction - methods
Α-lactose monohydrate
title Structure, morphology and surface properties of α-lactose monohydrate in relation to its powder properties
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