Abstract:
Cardiovascular diseases are still among the leading causes of mortality and morbidity worldwide. The build up of fatty plaques in the arteries, leading to atherosclerosis, is the most common cause of cardiovascular
diseases. The central player in atherosclerotic plaque formation is the foam cell. Foam cells are formed
when monocytes infiltrate from the blood stream into the sub-endothelial space, differentiating into macro phages. With the subsequent uptake and storage of lipoprotein, especially low-density lipoprotein (LDL),
they change their phenotype to lipid laden cells. Lowering circulating LDL levels, or initiating cholesterol
efflux/reverse cholesterol transport in foam cells, is one of the current clinical therapies. Prescription of the
pleiotropic drugs, statins, is the most successful therapy for the treatment and prevention of atherosclerosis.
In this study, we used a foam cell model from the macrophage cell line, RAW 246.7, and applied the label free Fourier Transform Infrared Spectroscopy (FTIR) method, i.e. synchrotron-based microFTIR spec troscopy, to study the lipid efflux process initiated by statins in a dose and time dependent manner. We used
glass coverslips as substrates for IR analysis. The optical images (visible and fluorescent light) clearly identify
the localization and lipid distribution within the foam cells, and the associated changes before and after cul turing them with atorvastatin at concentrations of 0.6, 6 and 60 µg mL−1
, for a culture duration between 24
to 72 hours. MicroFTIR spectroscopic spectra uniquely displayed the reduction of lipid content, with higher
lipid efflux observed at higher doses of, and longer incubation time with, atorvastatin. Principal Component
Analysis (PCA) and t-distributed Stochastic Neighbor Embedding (t-SNE) analysis demonstrated defined
cluster separation at both lipid (3000–2800 cm−1
) and fingerprint (1800–1350 cm−1
) regions, with more
profound discrimination for the atorvastatin dose treatment than time treatment. The data indicate that
combining synchrotron-based microFTIR spectroscopy and using glass substrates for foam cells can offer
an alternative tool in atherosclerosis investigation at a molecular level, and through cell morphology