Quantitative evaluation of atherosclerotic plaques using cross-polarization optical coherence tomography, nonlinear, and atomic force microscopy.

A combination of approaches to the image analysis in cross-polarization optical coherence tomography (CP OCT) and high-resolution imaging by nonlinear microscopy and atomic force microscopy (AFM) at the different stages of atherosclerotic plaque development is studied. This combination allowed us to qualitatively and quantitatively assess the disorganization of collagen in the atherosclerotic arterial tissue (reduction and increase of CP backscatter), at the fiber (change of the geometric distribution of fibers in the second-harmonic generation microscopy images) and fibrillar (violation of packing and different nature of a basket-weave network of fibrils in the AFM images) organization levels. The calculated CP channel-related parameters are shown to have a statistically significant difference between stable and unstable (also called vulnerable) plaques, and hence, CP OCT could be a potentially powerful, minimally invasive method for vulnerable plaques detection.

Three-dimensional in vivo imaging of tumors expressing red fluorescent proteins.

3D imaging of genetically-engineered fluorescent tumors enables quantitative monitoring of tumor growth/regression, metastatic processes, including during anticancer therapy in real-time.Fluorescent tumor models for 3D imaging require stable expression of genetically encoded fluorescent proteins and maintenance of the properties of tumor cell line including growth rate, morphology, and immunophenotype.In this chapter, the protocol for 3D imaging of tumors expressing red fluorescent protein are described in detail.

Lifetime imaging of FRET between red fluorescent proteins.

Numerous processes in cells can be traced by using fluorescence resonance energy transfer (FRET) between two fluorescent proteins. The novel FRET pair including the red fluorescent protein TagRFP and kindling fluorescent protein KFP for sensing caspase-3 activity is developed. The lifetime mode of FRET measurements with a nonfluorescent protein KFP as an acceptor is used to minimize crosstalk due to its direct excitation. The red fluorescence is characterized by a better penetrability through the tissues and minimizes the cell autofluorescence signal. The effective transfection and expression of the FRET sensor in eukaryotic cells is shown by FLIM. The induction of apoptosis by camptothecine increases the fluorescence lifetime, which means effective cleavage of the FRET sensor by caspase-3. The instruments for detecting whole-body fluorescent lifetime imaging are described. Experiments on animals show distinct fluorescence lifetimes for the red fluorescent proteins possessing similar spectral properties.

Fluorescence diffuse tomography for detection of red fluorescent protein expressed tumors in small animals.

A fluorescence diffuse tomography (FDT) setup for monitoring tumor growth in small animals has been created. In this setup an animal is scanned in the transilluminative configuration by a single source and detector pair. To remove stray light in the detection system, we used a combination of interferometric and absorption filters. To reduce the scanning time, an experimental animal was scanned using the following algorithm: (1) large-step scanning to obtain a general view of the animal (source and detector move synchronously); (2) selection of the fluorescing region; and (3) small-step scanning of the selected region and different relative shifts between the source and detector to obtain sufficient information for 3D reconstruction. We created a reconstruction algorithm based on the Holder norm to estimate the fluorophore distribution. This algorithm converges to the solution with a minimum number of fluorescing zones. The use of tumor cell lines transfected with fluorescent proteins allowed us to conduct intravital monitoring studies. Cell lines of human melanomas Mel-P, Mel-Ibr, Mel-Kor, and human embryonic kidney HEK293 Phoenix were transfected with DsRed-Express and Turbo-RFP genes. The emission of red fluorescent proteins (RFPs) in the long-wave optical range permits detection of deep-seated tumors. In vivo experiments were conducted immediately after subcutaneous injection of fluorescing cells into small animals.