Optimizing tissue preparation and storage for analysis of polyunsaturated fatty acids using Agilent’s FTIR imaging systems
Applications | 2014 | Agilent TechnologiesInstrumentation
The distribution and oxidation state of polyunsaturated fatty acids (PUFAs) in biological tissues are key indicators of cellular health and disease progression, particularly in neurological disorders such as Alzheimer’s disease. High-resolution Fourier transform infrared (FTIR) imaging offers a label-free approach to map PUFA content at the subcellular level, providing insights into lipid metabolism and oxidative damage in tissue sections.
This work aimed to evaluate how common preparation and storage conditions affect PUFA integrity in mouse retinal sections and to establish guidelines that minimize oxidative degradation. By comparing accelerated exposure to light and standard dark, dry room-temperature storage, the study quantified temporal changes in characteristic FTIR absorption bands linked to PUFA content.
Retinal tissue from 13-month-old C57BL/6 mice was flash-frozen in isopentane cooled by liquid nitrogen, cryosectioned to 7 µm at –20 °C, and mounted on MirrIR or BaF2 substrates. Samples were stored at –70 °C until analysis. After thawing and air-drying in the dark, sections were imaged at predefined intervals to monitor PUFA loss under typical storage and under accelerated light exposure.
Imaging was performed on an Agilent Cary 620 FTIR microscope equipped with a 64×64 pixel focal plane array detector (5.5 µm pixel). It was coupled to an Agilent Cary 670 FTIR spectrometer. Spectra were recorded from 4000 to 900 cm⁻¹ at 4 cm⁻¹ resolution with 256 co-added scans. Both MirrIR reflection and BaF2 transmission modes were used, and data processing employed Agilent Resolutions Pro and custom software routines.
Under accelerated light exposure, the olefinic C=C–H band at 3012 cm⁻¹ disappeared within 48 hours, indicating rapid PUFA oxidation. In standard dark, dry room-temperature storage, the PUFA band area declined by ~8% over two weeks, ~15% after one month, and more than two-thirds of the initial signal was lost after eight months. The lipid carbonyl band at 1735 cm⁻¹ showed smaller decreases, suggesting formation of new oxidation products evidenced by changes in the O–H stretch region. Spatial maps confirmed highest PUFA concentration in rod outer segments of the retina.
Advances may include cryogenic imaging stages to preserve native lipid states during measurement, integration with chemometric and machine-learning tools for automated spectral interpretation, and extension to in vivo or live-cell FTIR modalities. Development of standardized workflows will enhance reproducibility across laboratories studying lipidomics and oxidative pathology.
FTIR imaging on freshly thawed, dark-stored tissue sections yields the most reliable measurement of PUFA biomarkers. Delays in imaging under routine lab conditions lead to progressive underestimation of PUFA levels, underscoring the need for rapid analysis post-sectioning.
FTIR Spectroscopy, Microscopy
IndustriesClinical Research
ManufacturerAgilent Technologies
Summary
Importance of the Topic
The distribution and oxidation state of polyunsaturated fatty acids (PUFAs) in biological tissues are key indicators of cellular health and disease progression, particularly in neurological disorders such as Alzheimer’s disease. High-resolution Fourier transform infrared (FTIR) imaging offers a label-free approach to map PUFA content at the subcellular level, providing insights into lipid metabolism and oxidative damage in tissue sections.
Objectives and Study Overview
This work aimed to evaluate how common preparation and storage conditions affect PUFA integrity in mouse retinal sections and to establish guidelines that minimize oxidative degradation. By comparing accelerated exposure to light and standard dark, dry room-temperature storage, the study quantified temporal changes in characteristic FTIR absorption bands linked to PUFA content.
Methodology
Retinal tissue from 13-month-old C57BL/6 mice was flash-frozen in isopentane cooled by liquid nitrogen, cryosectioned to 7 µm at –20 °C, and mounted on MirrIR or BaF2 substrates. Samples were stored at –70 °C until analysis. After thawing and air-drying in the dark, sections were imaged at predefined intervals to monitor PUFA loss under typical storage and under accelerated light exposure.
Instrumentation
Imaging was performed on an Agilent Cary 620 FTIR microscope equipped with a 64×64 pixel focal plane array detector (5.5 µm pixel). It was coupled to an Agilent Cary 670 FTIR spectrometer. Spectra were recorded from 4000 to 900 cm⁻¹ at 4 cm⁻¹ resolution with 256 co-added scans. Both MirrIR reflection and BaF2 transmission modes were used, and data processing employed Agilent Resolutions Pro and custom software routines.
Main Results and Discussion
Under accelerated light exposure, the olefinic C=C–H band at 3012 cm⁻¹ disappeared within 48 hours, indicating rapid PUFA oxidation. In standard dark, dry room-temperature storage, the PUFA band area declined by ~8% over two weeks, ~15% after one month, and more than two-thirds of the initial signal was lost after eight months. The lipid carbonyl band at 1735 cm⁻¹ showed smaller decreases, suggesting formation of new oxidation products evidenced by changes in the O–H stretch region. Spatial maps confirmed highest PUFA concentration in rod outer segments of the retina.
Benefits and Practical Applications
- Establishes optimized handling protocols for accurate FTIR-based lipid analysis in tissues.
- Provides a timeline for acceptable storage durations before significant PUFA loss.
- Supports research on oxidative stress in neurodegenerative diseases using label-free imaging.
Future Trends and Potential Applications
Advances may include cryogenic imaging stages to preserve native lipid states during measurement, integration with chemometric and machine-learning tools for automated spectral interpretation, and extension to in vivo or live-cell FTIR modalities. Development of standardized workflows will enhance reproducibility across laboratories studying lipidomics and oxidative pathology.
Conclusion
FTIR imaging on freshly thawed, dark-stored tissue sections yields the most reliable measurement of PUFA biomarkers. Delays in imaging under routine lab conditions lead to progressive underestimation of PUFA levels, underscoring the need for rapid analysis post-sectioning.
References
- Fraser T., Taylor H., Love S. Neurochem. Res. 35, 503–513 (2010).
- Hartmann T., Kuchenbecker J., Grimm M. O. W. J. Neurochem. 103, 159–170 (2007).
- Stitt D. M., Kastyak-Ibrahim M. Z., Liao C. R., Morrison J., Albensi B. C., Gough K. M. Vib. Spectrosc. 60, 16–22 (2012).
Content was automatically generated from an orignal PDF document using AI and may contain inaccuracies.
Similar PDF
High Spatial resolution FTIR imaging of biomedical tissue samples using a novel method of magnification enhancement
2014|Agilent Technologies|Applications
High Spatial resolution FTIR imaging of biomedical tissue samples using a novel method of magnification enhancement Application note Biomedical Research Authors Mustafa Kansiz1, Carol Hirschmugl2, Benedict Albensi3, Catherine Liao4, Kathleen Gough4 1 Agilent Technologies Australia Pty Ltd, Mulgrave, Australia 2…
Key words
magnification, magnificationsynchrotron, synchrotronabsorbance, absorbancespatial, spatialireni, irenipixel, pixelglobar, globarftir, ftiragilent, agilentimaging, imagingsource, sourcehigh, highmicroscope, microscopebiomedical, biomedicalstandard
Rapid screening of brain tissue with a high spatial resolution over large analysis areas using Agilent’s 670 and 620 FTIR imaging analysis
2012|Agilent Technologies|Applications
Rapid screening of brain tissue with a high spatial resolution over large analysis areas using Agilent’s 670 and 620 FTIR imaging analysis Application note Biomedical Authors Kathleen M. Gough*, Alexandra Kuzyk*, Jonah Kirkwood† * Department of Chemistry University of Manitoba…
Key words
imaging, imagingmosaic, mosaicbrain, brainplaques, plaquesspatial, spatialtissue, tissueresolutions, resolutionsagilent, agilentchemical, chemicalresolution, resolutiontangles, tanglesinfrared, infraredinvestigate, investigatemanitoba, manitobahippocampus
Polymers and Rubbers Application Compendium
2010|Agilent Technologies|Guides
MATERIALS TESTING AND RESEARCH SOLUTIONS FROM AGILENT Polymers and Rubbers Application Compendium
AGILENT TECHNOLOGIES MATERIALS TESTING AND RESEARCH SOLUTIONS From the extraction of raw materials through the development, manufacturing and utilization of advanced materials, to material reuse and recycling, Agilent…
Key words
kfm, kfmsurface, surfaceforce, forceafm, afmmodulus, modulustopography, topographyimages, imagesimaging, imagingpolymer, polymerscratch, scratchsample, sampleprobe, probepotential, potentialfrom, frommeasurements
FTIR Microscopic Imaging of Large Samples with 4x and 15x Infrared Objectives: A Case Study of a Carcinoma Tissue Section
2014|Agilent Technologies|Applications
FTIR Microscopic Imaging of Large Samples with 4x and 15x Infrared Objectives: A Case Study of a Carcinoma Tissue Section Application note Biomedical Research Author Claudia Beleites*, Jürgen Popp*, Christoph Krafft*, Mustafa Kansiz† * Institute of Photonic Technology, Albert-Einstein-Str. 9,…
Key words
tissue, tissuecarcinoma, carcinomamosaic, mosaicsize, sizeftir, ftirfile, filemosaics, mosaicspixel, pixeldata, datafov, fovfpa, fpasection, sectionimages, imagesfive, fivemicroscopic
