Insights into the dehydration behavior of thiamine hydrochloride (vitamin B1) hydrates: Part I

Paroma Chakravarty; Robert T. Berendt; Eric J. Munson; Victor G. Young; Ramprakash Govindarajan; Raj Suryanarayanan

doi:10.1002/jps.21876

Insights into the dehydration behavior of thiamine hydrochloride (vitamin B₁) hydrates: Part I

Paroma Chakravarty, Robert T. Berendt, Eric J. Munson, Victor G. Young, Ramprakash Govindarajan, Raj Suryanarayanan

Research output: Contribution to journal › Article › peer-review

30 Scopus citations

Abstract

Thiamine hydrochloride (Vitamin B₁, THCl) can exist as a nonstoichio-metric hydrate (NSH) and as a hemihydrate (HH). NSH can contain up to ∼1 molar equivalent of water and be dehydrated to an isomorphic desolvate (ID) with minimal change in lattice structure. Crystallographic and spectroscopic techniques were used to characterize the influence of structure and mobility on NSH dehydration. Dehydration was accompanied by lattice contraction, as noted by a decrease in the d-spacings. Dehydration also led to the development of surface cracks parallel to the (101̄) and (102̄) planes in the NSH single crystal, as observed by hot stage microscopy. Step-wise dehydration of NSH produced gradual shifts in XRPD and SSNMR peaks, indicating that NSH (with ∼1 mole water) and ID represent the two extremes of a continuum in the hydration state. Variable temperature ¹³C SSNMR studies showed that water molecules move rapidly at room temperature within the NSH crystal lattice, and the thiamine molecules transiently exist in distinct hydrated and dehydrated states. It is hypothesized that, despite the lack of continuous hydration channels in the NSH crystal lattice, cooperative deformation of the thiamine molecules allows a nondisruptive departure of water molecules from the lattice during dehydration.

Original language	English (US)
Pages (from-to)	816-827
Number of pages	12
Journal	Journal of Pharmaceutical Sciences
Volume	99
Issue number	2
DOIs	https://doi.org/10.1002/jps.21876
State	Published - Feb 2010

Bibliographical note

Funding Information:
We thank Dr. Sergey Vyazovkin, University of Alabama, for the model-free analysis of NSH dehydration data. Partial financial support was received from Dane O. Kildsig Center for Pharmaceutical Processing Research. Paroma Chakravarty is the recipient of the Doctoral Dissertation Fellowship from the Graduate School, University of Minnesota. Part of this work was carried out in the I.T. Characterization Facility of the University of Minnesota, which receives partial support from NSF through the NNIN program.

Copyright:
Copyright 2017 Elsevier B.V., All rights reserved.

Keywords

Crystal structure
Hydrates
Mobility
Solid-state NMR
Spectroscopy
X-ray powder diffractometry

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title = "Insights into the dehydration behavior of thiamine hydrochloride (vitamin B1) hydrates: Part I",

abstract = "Thiamine hydrochloride (Vitamin B1, THCl) can exist as a nonstoichio-metric hydrate (NSH) and as a hemihydrate (HH). NSH can contain up to ∼1 molar equivalent of water and be dehydrated to an isomorphic desolvate (ID) with minimal change in lattice structure. Crystallographic and spectroscopic techniques were used to characterize the influence of structure and mobility on NSH dehydration. Dehydration was accompanied by lattice contraction, as noted by a decrease in the d-spacings. Dehydration also led to the development of surface cracks parallel to the (10{\=1}) and (10{\=2}) planes in the NSH single crystal, as observed by hot stage microscopy. Step-wise dehydration of NSH produced gradual shifts in XRPD and SSNMR peaks, indicating that NSH (with ∼1 mole water) and ID represent the two extremes of a continuum in the hydration state. Variable temperature 13C SSNMR studies showed that water molecules move rapidly at room temperature within the NSH crystal lattice, and the thiamine molecules transiently exist in distinct hydrated and dehydrated states. It is hypothesized that, despite the lack of continuous hydration channels in the NSH crystal lattice, cooperative deformation of the thiamine molecules allows a nondisruptive departure of water molecules from the lattice during dehydration.",

keywords = "Crystal structure, Hydrates, Mobility, Solid-state NMR, Spectroscopy, X-ray powder diffractometry",

author = "Paroma Chakravarty and Berendt, {Robert T.} and Munson, {Eric J.} and Young, {Victor G.} and Ramprakash Govindarajan and Raj Suryanarayanan",

note = "Funding Information: We thank Dr. Sergey Vyazovkin, University of Alabama, for the model-free analysis of NSH dehydration data. Partial financial support was received from Dane O. Kildsig Center for Pharmaceutical Processing Research. Paroma Chakravarty is the recipient of the Doctoral Dissertation Fellowship from the Graduate School, University of Minnesota. Part of this work was carried out in the I.T. Characterization Facility of the University of Minnesota, which receives partial support from NSF through the NNIN program. Copyright: Copyright 2017 Elsevier B.V., All rights reserved.",

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AU - Suryanarayanan, Raj

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N2 - Thiamine hydrochloride (Vitamin B1, THCl) can exist as a nonstoichio-metric hydrate (NSH) and as a hemihydrate (HH). NSH can contain up to ∼1 molar equivalent of water and be dehydrated to an isomorphic desolvate (ID) with minimal change in lattice structure. Crystallographic and spectroscopic techniques were used to characterize the influence of structure and mobility on NSH dehydration. Dehydration was accompanied by lattice contraction, as noted by a decrease in the d-spacings. Dehydration also led to the development of surface cracks parallel to the (101̄) and (102̄) planes in the NSH single crystal, as observed by hot stage microscopy. Step-wise dehydration of NSH produced gradual shifts in XRPD and SSNMR peaks, indicating that NSH (with ∼1 mole water) and ID represent the two extremes of a continuum in the hydration state. Variable temperature 13C SSNMR studies showed that water molecules move rapidly at room temperature within the NSH crystal lattice, and the thiamine molecules transiently exist in distinct hydrated and dehydrated states. It is hypothesized that, despite the lack of continuous hydration channels in the NSH crystal lattice, cooperative deformation of the thiamine molecules allows a nondisruptive departure of water molecules from the lattice during dehydration.

AB - Thiamine hydrochloride (Vitamin B1, THCl) can exist as a nonstoichio-metric hydrate (NSH) and as a hemihydrate (HH). NSH can contain up to ∼1 molar equivalent of water and be dehydrated to an isomorphic desolvate (ID) with minimal change in lattice structure. Crystallographic and spectroscopic techniques were used to characterize the influence of structure and mobility on NSH dehydration. Dehydration was accompanied by lattice contraction, as noted by a decrease in the d-spacings. Dehydration also led to the development of surface cracks parallel to the (101̄) and (102̄) planes in the NSH single crystal, as observed by hot stage microscopy. Step-wise dehydration of NSH produced gradual shifts in XRPD and SSNMR peaks, indicating that NSH (with ∼1 mole water) and ID represent the two extremes of a continuum in the hydration state. Variable temperature 13C SSNMR studies showed that water molecules move rapidly at room temperature within the NSH crystal lattice, and the thiamine molecules transiently exist in distinct hydrated and dehydrated states. It is hypothesized that, despite the lack of continuous hydration channels in the NSH crystal lattice, cooperative deformation of the thiamine molecules allows a nondisruptive departure of water molecules from the lattice during dehydration.

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