Multicomponent Chemical Imaging of Pharmaceutical Solid Dosage Forms with Broadband CARS Microscopy

Hartshorn, Christopher M.; Lee, Young Jong; Camp, Charles H.; Liu, Zhen; Heddleston, John M.; Canfield, Nicole; Rhodes, Timothy; Walker, Angela R. Hight; Marsac, Patrick J.; Cicerone, Marcus T.

doi:10.1021/ac400671p

Cited by 60 publications

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“…Examples in biology include mechanisms of intercellular signaling [9], and adhesion strategies of mollusks [10]. We have also been able to use this imaging modality to chemically map pharmaceutical preparations, finding rare, but potentially important features in drug phase that were not visible to spontaneous Raman imaging due to their small size [11].In addition to chemical contrast, it appears that it will be possible to derive a contrast mechanism based on materials dynamics from CRI methods. Recent advances in our understanding of motion in solids allows us to predict dynamic properties of these systems over 12 orders of magnitude in time with just a few parameters derived from picosecond timescale measurements [12].…”

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Mapping Chemistry, Composition, and Dynamics with Coherent Raman Imaging

et al. 2016

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We first introduced spectroscopic coherent Raman imaging in 2004 [1], demonstrating good chemical discrimination of bulk polymer blends on a broadband coherent Raman scattering (BCARS) microscope. The good spatial resolution (lateral 300 nm and axial 1 μm) and resolution and short spectral integration times (17 ms) portended utility in materials and biological imaging. However, the CARS signal is proportional to the square of the local analyte concentration, so the early instrumentation was not able to acquire spectra from weakly scattering and relatively low concentration species represented in the fingerprint region of the spectrum.After many improvements in instrumentation and signal retrieval methods it is now possible to obtain quantitative and robust fingerprint and CH-stretch spectra from materials and biological systems. The BCARS signal is generated by combining a spectrally narrow probe field with a spectrally broad Stokes field. The resulting signal includes a component that is resonant with molecular vibrations, related to the spontaneous Raman signal, and a field that is not resonant, and nominally frequency independent. The latter can be much stronger than the former, and we found that it masked the weak fingerprint spectra. One of the most important advances was the realization that the nonresonant component of the coherent signal could be used to amplify the weak resonant component of interest [2], and once baseline was removed [3], it was possible to obtain quantitative and reliable spectra from materials [4] and cells [5]. Subsequent correction to errors in nonresonant background estimation [6] ensured reproducible spectra with internally calibrated peak ratios. With these improvements it was possible to obtain good quality spectra from biological cells in the CH stretch region, but still only marginal fingerprint spectral peaks.The early BCARS instrumentation relied on a continuum Stokes field that was intrinsically noise-prone, and that noise was transferred to the anti-Stokes signal, obscuring weak fingerprint peaks. Optimizing the continuum [7] was one key to improving the signal, but ultimately, an entirely different type of supercontinuum pulse that was temporally compressible to 15 fs, allowed us to utilize a second and more efficient signal generation mechanism. Together, these factors lead to acquisition of even weak fingerprint spectra from biological tissues in approximately 3 ms [8]. The resulting state-of-the-art spectroscopic coherent Raman imaging (CRI) instrument provides rapid, high spatial resolution imaging with excellent label-free chemical contrast as shown in Figure 1. It has allowed us to shed light on phenomena in biology and materials science. Examples in biology include mechanisms of intercellular signaling [9], and adhesion strategies of mollusks [10]. We have also been able to use this imaging modality to chemically map pharmaceutical preparations, finding rare, but potentially important features in drug phase that were not visible to spontaneous Raman imaging due to...

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Mapping Chemistry, Composition, and Dynamics with Coherent Raman Imaging

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“…These techniques are capable of determining the relative stability of polymorphs by investigating the energies involved in phase changes between various polymorphs [33]. Thermal analysis is based on the principle that a physical change in a material is associated with a release or absorption of heat.…”

Section: Pharmaceutical Analytical Techniquesmentioning

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“…Fussell et al [31] extended this dissolution concept by building an intrinsic flow-through dissolution setup which allowed correlation of surface solid-state changes occurring during dissolution with changes in drug dissolution rate. Slipchenko et al [32] and Hartshorn et al [33] focused on studying complex oral dosage forms containing APIs combined with a number of excipients.…”

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Coherent anti-Stokes Raman scattering microscopy for pharmaceutics

Fussell

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“…Second, narrowband CARS signals are typically detected on monolithic detectors such as photomultiplier tubes (PMTs) and bulk photodiodes (PDs). These detectors have bandwidths on the order of tens to hundreds of megahertz, allowing exceptionally fast imaging, while even the best broadband CARS microscope is limited to read-out speeds of about 10 kilohertz [66].…”

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Contrast in coherent Raman scattering microscopy

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Multicomponent Chemical Imaging of Pharmaceutical Solid Dosage Forms with Broadband CARS Microscopy

Cited by 60 publications

References 53 publications

Mapping Chemistry, Composition, and Dynamics with Coherent Raman Imaging

Mapping Chemistry, Composition, and Dynamics with Coherent Raman Imaging

Coherent anti-Stokes Raman scattering microscopy for pharmaceutics

Contrast in coherent Raman scattering microscopy

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