What question did this study set out to answer?

This research aims to explore how temperature changes affect the Raman spectra of doxorubicin.

March 31, 2026Open Access

Temperature-induced spectral anomalies in doxorubicin—A Raman study

Q: What is the clinical evidence from this study?

Study design: Other. Population: Doxorubicin spectral analysis. Intervention: Temperature variation (100 to 300 K) vs. DFT-based simulations. Primary outcome: Raman spectra agreement between theory and experiment.

Key Result

Temperature-dependent Raman scattering experiments of doxorubicin between 100 and 300 K yielded 91%-94% agreement with DFT-based simulations, revealing temperature-dependent resonance effects.

Key Points

This research aims to explore how temperature changes affect the Raman spectra of doxorubicin.
Conducted temperature-dependent Raman scattering experiments from 100 to 300 K under controlled conditions.
Utilized density functional theory (DFT) simulations to analyze resonance Raman spectra.
Employed the SARA algorithm for quantitative comparison between theoretical and experimental results.
Achieved 91%-94% agreement between theory and experiment across temperatures.
Observed intensity variations, with reduced hydrogen-bonded contributions and enhanced ring modes at higher temperatures.
Identified key temperature-induced changes related to resonance conditions.

Structured PICO

Population

Doxorubicin (DOX), DOX-HCl, and DOX-H+ molecules

Intervention

Temperature variations between 100 and 300 K

Outcome

Temperature-induced changes in Raman spectrasurrogate

Temperature-dependent resonance effects primarily drive the pronounced spectral intensity variations in the Raman spectra of doxorubicin between 100 and 300 K.

Abstract

Doxorubicin (DOX) is a widely used chemotherapeutic agent whose spectroscopic behavior can provide insight into its structural dynamics and interactions. Here, we investigate temperature-induced changes in the Raman spectra of DOX between 100 and 300 K, combining experimental measurements with density functional theory (DFT)-based simulations. Temperature-dependent Raman scattering experiments, performed under controlled cryogenic and ambient conditions, revealed pronounced spectral intensity variations accompanied by changes in the luminescence background. Detailed analysis and comparison with simulated resonance Raman spectra showed that these changes originate primarily from temperature-dependent resonance effects. Using the R2SCAN/def2-TZVP level of theory with D3 dispersion corrections, the most stable conformers of DOX, DOX-HCl, and DOX-H+ were identified, and their resonance Raman spectra were computed. Quantitative comparison using the SARA algorithm yielded 91%-94% agreement between theory and experiment across all temperatures. Increasing temperature is accompanied by a redistribution of relative Raman intensities, with reduced contributions from bands assigned to motions involving hydrogen-bonds and enhanced contributions from ring-dominated modes. This trend is discussed in the context of temperature-dependent resonance conditions.

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Cite This Study

Todorović et al. (Tue,) conducted a other in Doxorubicin spectral analysis. Temperature variation (100 to 300 K) vs. DFT-based simulations was evaluated on Raman spectra agreement between theory and experiment. Temperature-dependent Raman scattering experiments of doxorubicin between 100 and 300 K yielded 91%-94% agreement with DFT-based simulations, revealing temperature-dependent resonance effects.

synapsesocial.com/papers/6a025ca2edf6f4813859481c https://doi.org/https://doi.org/10.1016/j.saa.2026.127678

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