Table 2.
Summary of some of the Raman techniques used for monitoring the effects of anticancer drugs on cancer tissues.
| Monitoring Approach |
Nanoparticles | Anticancer Drug |
Raman Instrumentation |
Target | Reference |
|---|---|---|---|---|---|
| Cancer response to anticancer drugs |
Targeted Cet-PLGA- b-PEG and Non-targeted PLGA- b-PEG |
Microtubule targeted vascular disrupting agents (MTVDA) |
Confocal Spontaneous Raman Microscopy (λ = 532 nm; laser power on sample = 10 mW; integration time = 5 s; number of spectra acquired for each sample = 10) |
Ex-vivo hepatocellular carcinomas |
[50] |
| Monitoring of concentration of anticancer drug in cancer cell nucleus/ cytoplasm |
Squalene | Doxorubicin | Confocal Spontaneous Raman Microscopy (λ = 785 nm; laser power on sample = 60 mW; integration time = 20 s; number of spectra acquired for each sample = 30) |
Murine lung carcinomas and Human breast cancer |
[51] |
| Assessing profiles of the release of anticancer drugs |
Diatomic NP decorated with Au NPs and enclosed in gelatin shell |
Galunisertib | SERS (λ = 638 nm; He-Ne laser power = 50 mW; laser power on sample = 1 mW; acquisition time = 1 s; SERS spectra collected from 30 cells) Raman imaging (λ = 638 nm; He-Ne laser power = 50 mW; laser power on sample = 20 mW; Raman images acquired by raster scanning with step size of 0.5 μm; number of spectra acquired per cell = 1500/2000) |
Colorectal cancer |
[52] |