Draft:Backscatter Interferometry (BSI)

  • Comment: Concur with prior reviewer, (I did do a few edits however it needs alot more) Ozzie10aaaa (talk) 16:54, 28 May 2024 (UTC)
  • Comment: The tone is very promotional, making it sound like an advertisement for using the technique. Also there are no references for the "Key Findings and Applications" section and onwards. This is an encyclopedia, not an essay, so we don't need a conclusion section. But it look like a notable topic, so please improve this page. Graeme Bartlett (talk) 11:31, 28 May 2024 (UTC)

Backscatter Interferometry (BSI) is an analytical technique used for the detection and analysis of fluid bulk properties at micro and nanoliter volumes. This method leverages the principles of interferometry to measure changes in the refractive index of fluids, making it highly sensitive to minute volume changes. BSI is particularly useful in various scientific fields, including microfluidics, capillary electrophoresis, and clinical diagnostics.

Core Principles

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BSI operates by directing an unfocused laser beam at a cylindrical tube of capillary dimensions, which produces a backscattered interference pattern. This pattern contains information about the refractive index (RI) of the fluid within the tube. Positional changes in the interference fringes correspond to changes in the fluid's RI, enabling highly sensitive measurements. BSI can detect changes in the refractive index at the level of 10-7, making it suitable for probing extremely small volumes, down to 350 picoliters.[citation needed]

Innovations and developments

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Micro-Interferometric Backscatter Detection (MIBD)

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Developed by Bornhop in 1995, MIBD measures relative refractive index changes in small volumes without needing special optical alignment or beam-conditioning optics. It is applicable to capillary tubes ranging from 75 µm to 1.0 mm in diameter.[1]

Noninvasive Thermometry

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Demonstrated by Swinney and Bornhop in 2001, this application uses an on-chip interferometric backscatter detector (OCIBD) to facilitate sensitive, small volume temperature measurements, achieving a resolution of 9.9 × 10-4 °C.[2]

Flow Measurements in Microfluidic Channels

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Explored by Markov et al. in 2004, BSI was used for noninvasive fluid flow measurements in microfluidic channels, capable of accurately measuring fluid velocities with detection limits as low as 0.127 nL/s.[3]

Clinical Diagnostics

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Kussrow et al. in 2010 highlighted BSI's potential as an in vitro clinical diagnostic tool for detecting antibody-antigen interactions in human serum, significant for serological diagnosis of infectious diseases.[4]

Heat Index Flow Monitoring

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StClaire and Hayes (2000) demonstrated the application of BSI for real-time flow monitoring in capillaries using heat indexing, enabling accurate flow measurements in the range of 500 nL/s to 7 mL/s.[5]

Molecular Interaction Studies

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Weinberger et al. (2012) applied BSI to measure the dissociation constants (Kd) of protein complexes, demonstrating its high sensitivity and quantitative capabilities.[6]

Aptamer-Protein Interactions

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Olmsted et al. (2011) used BSI to measure aptamer-protein interactions, revealing allosteric effects that influence binding affinities.[7]

Hydrogen Bonding in Organic Solvents

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Pesciotta et al. (2011) extended BSI's application to study hydrogen bonding interactions in organic solvents, demonstrating its high sensitivity in non-aqueous environments.[8]

Membrane Protein Interactions

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Gerhart et al. (2015) explored the application of BSI in studying the interactions of membrane proteins within lipid membranes. This study highlighted BSI's ability to quantify association constants and stability free energy of membrane proteins under various conditions, illustrating its non-perturbing and physiologically relevant measurement capabilities.[9]

Verification of BSI's Accuracy

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Baksh and Finn (2017) validated BSI's accuracy by determining association constants for well-known biomolecular interactions, reinforcing BSI's reliability and precision.[10]

Label-Free Quantification of Protein-Protein Interactions

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Abbas and Koch (2021) demonstrated the label-free quantification of protein-protein interactions using BSI, providing accurate equilibrium dissociation constants without labeling or immobilization.[11]

High-Speed Capillary Electrophoresis

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Dunn (2020) implemented high-speed capillary electrophoresis (HSCE) combined with BSI, reducing analysis time and improving temperature stabilization.[12]

Electric Field-Enhanced Detection

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De Silva and Dunn (2024) introduced an electric field-enhanced BSI for capillary electrophoresis, enhancing the BSI signal with high field strengths.[13]

Dual Detection in HSCE

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Opallage, De Silva, and Dunn (2022) developed a high-speed capillary electrophoresis platform capable of simultaneous serum protein electrophoresis (SPE) and immunoassay measurements. Using a single laser excitation source, the platform measures both RI and fluorescence signals. This dual detection method enables the analysis of serum proteins and immunocomplexes in the same run, enhancing diagnostic capabilities. Optimized buffer systems like 20 mM CHES at pH 10 provided suitable conditions for both SPE and immunoassays, yielding a limit of detection (LOD) of 23 nM and a limit of quantification (LOQ) of 70 nM for fluorescein detection.[14]

References

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  1. ^ Dj, Bornhop (June 20, 1995). "Microvolume index of refraction determinations by interferometric backscatter". Applied Optics. 34 (18): 3234–3239. Bibcode:1995ApOpt..34.3234B. doi:10.1364/AO.34.003234. PMID 21052128 – via pubmed.ncbi.nlm.nih.gov.
  2. ^ Swinney, K.; Bornhop, D. J. (June 26, 2001). "Noninvasive picoliter volume thermometry based on backscatter interferometry". Electrophoresis. 22 (10): 2032–2036. doi:10.1002/1522-2683(200106)22:10<2032::AID-ELPS2032>3.0.CO;2-1. PMID 11465503 – via PubMed.
  3. ^ Markov, Dmitry A.; Dotson, Stephen; Wood, Scott; Bornhop, Darryl J. (November 26, 2004). "Noninvasive fluid flow measurements in microfluidic channels with backscatter interferometry". Electrophoresis. 25 (21–22): 3805–3809. doi:10.1002/elps.200406139. PMID 15565690 – via PubMed.
  4. ^ A, Kussrow; Cs, Enders; Ar, Castro; Dl, Cox; Rc, Ballard; Dj, Bornhop (July 26, 2010). "The potential of backscattering interferometry as an in vitro clinical diagnostic tool for the serological diagnosis of infectious disease". The Analyst. 135 (7): 1535–1537. Bibcode:2010Ana...135.1535K. doi:10.1039/c0an00098a. PMC 4317348. PMID 20414494.
  5. ^ StClaire, J. C.; Hayes, M. A. (October 1, 2000). "Heat index flow monitoring in capillaries with interferometric backscatter detection". Analytical Chemistry. 72 (19): 4726–4730. doi:10.1021/ac0004759. PMID 11028638 – via PubMed.
  6. ^ P, Sétif; N, Harris; B, Lagoutte; S, Dotson; Sr, Weinberger (August 11, 2010). "Detection of the photosystem I:ferredoxin complex by backscattering interferometry". Journal of the American Chemical Society. 132 (31): 10620–10622. doi:10.1021/ja102208u. PMID 20681677 – via pubmed.ncbi.nlm.nih.gov.
  7. ^ Olmsted, Ian R.; Xiao, Yi; Cho, Minseon; Csordas, Andrew T.; Sheehan, Jonathan H.; Meiler, Jens; Soh, H. Tom; Bornhop, Darryl J. (December 1, 2011). "Measurement of Aptamer–Protein Interactions with Back-Scattering Interferometry". Analytical Chemistry. 83 (23): 8867–8870. doi:10.1021/ac202823m. PMID 22032342 – via CrossRef.
  8. ^ Pesciotta, Esther N.; Bornhop, Darryl J.; Flowers, Robert A. (May 20, 2011). "Backscattering Interferometry: An Alternative Approach for the Study of Hydrogen Bonding Interactions in Organic Solvents". Organic Letters. 13 (10): 2654–2657. doi:10.1021/ol200757a. PMID 21510617 – via CrossRef.
  9. ^ P, Saetear; Aj, Perrin; Sj, Bartholdson; M, Wanaguru; A, Kussrow; Dj, Bornhop; Gj, Wright (February 21, 2015). "Quantification of Plasmodium-host protein interactions on intact, unmodified erythrocytes by back-scattering interferometry". Malaria Journal. 14: 88. doi:10.1186/s12936-015-0553-2. PMC 4349660. PMID 25889240.
  10. ^ Baksh, Michael M.; Finn, M. G. (May 2017). "An experimental check of backscattering interferometry - ScienceDirect". Sensors and Actuators B: Chemical. 243: 977–981. doi:10.1016/j.snb.2016.12.055. PMC 5433263. PMID 28529409.
  11. ^ Abbas, Seher; Koch, Karl-Wilhelm (December 20, 2021). "Label-free Quantification of Direct Protein-protein Interactions with Backscattering Interferometry". Bio-Protocol. 11 (24): e4256. doi:10.21769/BioProtoc.4256. PMC 8720515. PMID 35087916.
  12. ^ Dunn, Robert C. (June 2, 2020). "High-Speed Capillary Electrophoresis Using a Thin-Wall Fused-Silica Capillary Combined with Backscatter Interferometry". Analytical Chemistry. 92 (11): 7540–7546. doi:10.1021/acs.analchem.9b05881. PMID 32352792 – via CrossRef.
  13. ^ De Silva, Miyuru; Dunn, Robert C. (January 24, 2024). "Electric field-enhanced backscatter interferometry detection for capillary electrophoresis". Scientific Reports. 14 (1): 2110. Bibcode:2024NatSR..14.2110D. doi:10.1038/s41598-024-52621-3. PMC 10808210. PMID 38267528.
  14. ^ Opallage, Prabhavie M.; De Silva, Miyuru; Dunn, Robert C. (February 4, 2022). "Dual detection high-speed capillary electrophoresis for simultaneous serum protein analysis and immunoassays". Scientific Reports. 12 (1): 1951. Bibcode:2022NatSR..12.1951O. doi:10.1038/s41598-022-05956-8. PMC 8817013. PMID 35121780.