FT-IR versus EC-QCL spectroscopy for biopharmaceutical quality assessment with focus on insulin—total protein assay and secondary structure analysis using attenuated total reflection

Delbeck, Sven; Heise, H. M.

doi:10.1007/s00216-020-02718-1

Cited by 11 publications

(11 citation statements)

References 30 publications

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“…Traditionally limited to Fourier transform infrared (FTIR) spectroscopy but recently also expanded to include quantum cascade laser (QCL)-based wavelength-scanning spectroscopy, IR spectroscopy has seen expanding areas of applications in biology and life sciences. 1,2 These include, to name just a few, the analysis of protein samples for research or quality control, [3][4][5] the analysis of biofluid samples such as blood serum and plasma for disease screening, [6][7][8] the spectro-chemical imaging of histology samples as "digital staining", [9][10][11][12] and the spectroscopy and spectro-chemical imaging of fixed cells, live cells, or cell lysates to study cell biology. [13][14][15][16][17] IR spectroscopy-based monitoring of live cells in real time is particularly appealing because it enables quantitative measurements of dynamic cellular changes, such as growth, metabolism, differentiation, and cell-drug interaction, without missing any key biological events.…”

Section: Introductionmentioning

confidence: 99%

Metasurface-enhanced infrared spectroscopy in multiwell format for real-time assaying of live cells

et al. 2023

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Section: Introductionmentioning

confidence: 99%

Metasurface-enhanced infrared spectroscopy in multiwell format for real-time assaying of live cells

et al. 2023

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“…The ATR IR-spectroscopic method presented here offers a multi-purpose approach, combining the protein’s secondary structure analysis with concentration quantification and identification of insulin subclasses, respectively. 19 Combined with the aforementioned in vitro cell test, which offers insight into the biopotency of selected samples, this method could replace the current section for insulin quality control in international Pharmacopoeias. In comparison to quality assurance by HPLC methods, ATR IR-spectroscopy of protein-enriched insulin dry-films can detect early stages of protein misfolding, secured by reliable validation protocols based on multivariate data analysis, as described here.…”

Section: Discussionmentioning

confidence: 99%

“…4(b) , other excipient compounds such as phenol or m-cresol are found at low concentrations not contributing significantly to the dry-film spectrum; the same applies to glycerol within the protein amide I and II band interval, as demonstrated earlier by us. 19 However, still some traces of water are left over and visible from the deformation vibration band at

.…”

Section: Methodsmentioning

confidence: 99%

Systematic stability testing of insulins as representative biopharmaceuticals using ATR FTIR-spectroscopy with focus on quality assurance

Delbeck

Heise

2021

J. Biomed. Opt.

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. Significance: Bioactive proteins represent the most important component class in biopharmaceutical products for therapeutic applications. Their production is most often biotechnologically realized by genetically engineered microorganisms. For the quality assurance of insulins as representatives of life-saving pharmaceuticals, analytical methods are required that allow more than total protein quantification in vials or batches. Chemical and physical factors such as unstable temperatures or shear rate exposure under storage can lead to misfolding, nucleation, and subsequent fibril forming of the insulins. The assumption is valid that these processes go parallel with a decrease in bioactivity. Aim: Infrared (IR) spectroscopy has been successfully utilized for secondary structure analysis in cases of protein misfolding and fibril formation. Approach: A reliable method for the quantification of the secondary structure changes has been developed using insulin dry-film Fourier-transform IR spectroscopy in combination with the attenuated total reflection (ATR) technique and subsequent data analyses such as band-shift determination, spectral band deconvolution, and principal component analysis. Results: A systematic study of insulin spectra was carried out on model insulin specimens, available either as original formulations or as hormones purified by ultrafiltration. Insulin specimens were stored at different temperatures, i.e., 0°C, 20°C, and 37°C, respectively, for up to three months. Weekly ATR-measurements allowed the monitoring of hormone secondary structure changes, which are supposed to be negatively correlated with insulin bioactivity. Conclusions: It could be shown that IR-ATR spectroscopy offers a fast and reliable analytical method for the determination of secondary structural changes within insulin molecules, as available in pharmaceutical insulin formulations and therefore challenges internationally established measurement techniques for quality control regarding time, costs, and effort of analysis.

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“…Specifically, for insulin pens, ifwNMR detects abnormal R 2 ( 1 H 2 O) value of a pen, based on the R 2 ( 1 H 2 O) value alone, one cannot specify whether the aberration is caused by insulin dose deviation, insulin aggregation, insulin misfolding, or insulin chemical degradation. These specific scenarios need to be clarified by invasive analytical techniques; the compendial HPLC method or biopotency method for insulin dose; 33,34 size exclusion chromatography, dynamic light scattering and microflow imaging for insulin aggregates, 19,35 small-angle X-ray scattering, X-ray absorption and transmission electron microscopy for insulin fibrillation, 36 Raman and FT-IR spectroscopy for insulin misfolding and total quantification, 37,38 and LC-MS for insulin chemical degradation. 39 From the quality control standpoint, noninvasive analytical techniques, like wNMR, are best implemented at the drug product (DP) level while invasive analyses are best implemented at the drug substance (DS) level.…”

Section: Limitations Of Noninvasive Inspectionmentioning

confidence: 99%

“…The data show that even the simple procedure of sample transfer can be detected by w NMR, presumably because w NMR is sensitive to O 2 , which is paramagnetic. Techniques that are insensitive to O 2 , such as FT-IR that is equally efficient for liquid and dry-film preparations, 38,40 might not have detected that the insulin pen solution has experienced being transferred out of and then back into the pen. This sensitivity to O 2 is useful in detecting drug product tampering.…”

Section: Introductionmentioning

confidence: 99%

Inspecting Insulin Products Using Water Proton NMR. I. Noninvasive vs Invasive Inspection

Taraban

Wang

Briggs

et al. 2021

J Diabetes Sci Technol

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Background: There is a clear need to transition from batch-level to vial/syringe/pen-level quality control of biologic drugs, such as insulin. This could be achieved only by noninvasive and quantitative inspection technologies that maintain the integrity of the drug product. Methods: Four insulin products for patient self-injection presented as prefilled pens have been noninvasively and quantitatively inspected using the water proton NMR technology. The inspection output is the water proton relaxation rate R2(1H2O), a continuous numerical variable rather than binary pass/fail. Results: Ten pens of each product were inspected. R2(1H2O) displays insignificant variation among the 10 pens of each product, suggesting good insulin content uniformity in the inspected pens. It is also shown that transferring the insulin solution out of and then back into the insulin pen caused significant change in R2(1H2O), presumably due to exposure to O2 in air. Conclusions: Water proton NMR can noninvasively and quantitatively inspect insulin pens. wNMR can confirm product content uniformity, but not absolute content. Its sensitivity to sample transferring provides a way to detect drug product tampering. This opens the possibility of inspecting every pen/vial/syringe by manufacturers and end-users.

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FT-IR versus EC-QCL spectroscopy for biopharmaceutical quality assessment with focus on insulin—total protein assay and secondary structure analysis using attenuated total reflection

Cited by 11 publications

References 30 publications

Metasurface-enhanced infrared spectroscopy in multiwell format for real-time assaying of live cells

Metasurface-enhanced infrared spectroscopy in multiwell format for real-time assaying of live cells

Systematic stability testing of insulins as representative biopharmaceuticals using ATR FTIR-spectroscopy with focus on quality assurance

Inspecting Insulin Products Using Water Proton NMR. I. Noninvasive vs Invasive Inspection

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