Jump to content

Transmission Raman spectroscopy

From Wikipedia, the free encyclopedia

This is an old revision of this page, as edited by Citation bot (talk | contribs) at 15:25, 6 July 2022 (Alter: pages. Add: pmid, s2cid, authors 1-1. Removed parameters. Some additions/deletions were parameter name changes. | Use this bot. Report bugs. | Suggested by Headbomb | #UCB_toolbar). The present address (URL) is a permanent link to this revision, which may differ significantly from the current revision.

Transmission Raman spectroscopy (TRS) is a variant of Raman spectroscopy which is advantageous in probing bulk content of diffusely scattering samples. Although it was demonstrated in the early days of Raman spectroscopy[1] it was not exploited in practical settings until much later, probably due to limitations of technology at the time. It was rediscovered in 2006,[2] where the authors showed that it was capable of allowing Raman spectroscopy through many millimetres of tabletted or powdered samples. In addition, this research has also identified several highly beneficial analytical properties of this approach, including the ability to probe bulk content of powders and tissue in the absence of subsampling and to reject Raman and fluorescence components originating from the surface of the sample.

Theory

Transmission Raman is possible because light scatters through turbid materials that do not significantly absorb or block the light. By a similar mechanism to spatially offset Raman spectroscopy, the light in a diffusely scattering sample spreads through the object randomly (Transmission Raman can be regarded as an extreme example of SORS). As Raman photons can be created at all points that the light passes through the total scrambled Raman signal measured on the opposite face of the object is highly representative of the bulk of the material. This desirable property removes a problem with conventional, widely used back-scattering Raman spectroscopy where the signal tends to be representative of the surface and near-surface composition. Because Raman spectroscopy does not rely on absorption and the light spreads throughout the sample, a large thickness can be measured in the absence of photon absorption. This produces an analysis representative of the entire mixture and is typically insensitive to coatings, or thin containers.

Pharmaceutical applications

Transmission Raman lends itself to rapid, non-invasive and non-destructive analysis of pharmaceutical dosage forms such as capsules and tablets. This addresses several limitations of traditional pharmaceutical assay techniques including limitations due to surface sensitivity (e.g., reflectance NIR), the presence of phase changes due to sample preparation (liquid chromatography) or sub-sampling (conventional Raman, NIR).[3][4] Transmission Raman is largely insensitive to surface, requires no sample preparation, involves no phase change and is rapid. Transmission Raman spectroscopy of pharmaceutical tablets and capsules was first demonstrated by Matousek and Parker.[5][6] Subsequent research established the technique’s accuracy and applicability to quantifying tablet and production-style capsule formulations.[7][8]

Pharmaceutical tablets and capsules are typically composed of a combination of APIs and excipients, each of which will produce a Raman spectral component with a relative intensity proportional to the ingredient concentrations. Analysing Raman spectra to produce assay results requires a method to separate the individual spectral components and correlate their intensity contributions with a relative concentration measure. This is typically facilitated using chemometric analysis methods.

Transmission Raman spectroscopy can be used as a process analytical technology (PAT) tool for the detection of physical state of the API and for obtaining qualitative and quantitative information about the composition.[9]

Medical applications

The use of Raman spectroscopy in medical applications has been limited to depths of hundreds of micrometres (confocal Raman). Transmission Raman has been demonstrated as a potential diagnostic tool for lesions in breast tissue.[10][11]

References

  1. ^ B. Schrader; G. Bergmann (1967). "Die Intensität des Ramanspektrums polykristalliner Substanzen". Fresenius' Z. Anal. Chem. 225 (2): 225–230. doi:10.1007/bf00983673. S2CID 94487523.
  2. ^ P. Matousek; A. W. Parker (2006). "Bulk Raman Analysis of Pharmaceutical Tablets". Applied Spectroscopy. 60 (12): 1353–1357. Bibcode:2006ApSpe..60.1353M. doi:10.1366/000370206779321463. PMID 17217583. S2CID 32218439.
  3. ^ H. Wang; C.K. Mann; T.J. Vickers (2002). "Effect of Powder Properties on the Intensity of Raman Scattering by Crystalline Solids". Appl. Spectrosc. 56 (12): 1538–1544. Bibcode:2002ApSpe..56.1538W. doi:10.1366/000370202321115779. S2CID 96236279.
  4. ^ J. Johansson; S. Pettersson; S. Folestad (2005). "Characterization of different laser irradiation methods for quantitative Raman tablet assessment". Journal of Pharmaceutical and Biomedical Analysis. 39 (3–4): 516. doi:10.1016/j.jpba.2005.04.029. PMID 15950422.
  5. ^ P. Matousek; A. W. Parker (2006). "Bulk Raman Analysis of Pharmaceutical Tablets". Applied Spectroscopy. 60 (12): 1353–7. Bibcode:2006ApSpe..60.1353M. doi:10.1366/000370206779321463. PMID 17217583. S2CID 32218439.
  6. ^ P. Matousek; A. W. Parker (2007). "Non-invasive probing of pharmaceutical capsules using transmission Raman spectroscopy". J. Raman Spectrosc. 38. 38 (5): 563–567. Bibcode:2007JRSp...38..563M. doi:10.1002/jrs.1688.
  7. ^ J. Johansson; A. Sparen; O. Svensson; S. Folestad; et al. (2007). "Quantitative transmission Raman spectroscopy of pharmaceutical tablets and capsules". Appl. Spectrosc. 61 (11): 1211–8. Bibcode:2007ApSpe..61.1211J. doi:10.1366/000370207782597085. PMID 18028700. S2CID 6622891.
  8. ^ Charlotte Eliasson; Neil A. Macleod; Linda C. Jayes; Fiona C. Clarke; et al. (2008). "Non-invasive quantitative assessment of the content of pharmaceutical capsules using transmission Raman spectroscopy". Journal of Pharmaceutical and Biomedical Analysis. 47 (2): 221–229. doi:10.1016/j.jpba.2008.01.013. PMID 18296001.
  9. ^ Vigh, T.; et al. (2013). "Polymer-free and polyvinylpirrolidone-based electrospun solid dosage forms for drug dissolution enhancement". European Journal of Pharmaceutical Sciences. 49 (4): 595–602. doi:10.1016/j.ejps.2013.04.034. PMID 23684933.
  10. ^ P. Matousek; N. Stone (2007). "Prospects for the diagnosis of breast cancer by noninvasive probing of calcifications using transmission Raman spectroscopy". Journal of Biomedical Optics. 12 (2): 024008. Bibcode:2007JBO....12b4008M. doi:10.1117/1.2718934. PMID 17477723.
  11. ^ Ellis, David I.; Cowcher, David P.; Ashton, Lorna; O'Hagan, Steve; Goodacre, Royston (2013). "Illuminating disease and enlightening biomedicine: Raman spectroscopy as a diagnostic tool". The Analyst. 138 (14): 3871–3884. Bibcode:2013Ana...138.3871E. doi:10.1039/c3an00698k. ISSN 0003-2654. PMID 23722248.