A one-layer model of laser-induced fluorescence for diagnosis of disease in human tissue: applications to atherosclerosis.

This paper describes a general model of tissue fluorescence which can be used both to: 1) determine chemical and physical properties of the tissue, and 2) design an optimal algorithm for clinical diagnosis of tissue composition. This model is based on a picture of tissue as a single, optically thick layer, in which fluorophores and absorbing species are homogeneously distributed. As a specific example, the model is applied to the laser induced fluorescence (LIF) of normal and atherosclerotic human aorta using 476 nm excitation.

Argon ion laser-excited autofluorescence in normal and atherosclerotic aorta and coronary arteries: morphologic studies.

Argon ion laser-excited autofluorescence was studied in unstained frozen sections of 47 normal and atherosclerotic human aortas and coronary arteries by means of a bright-field microscope modified for fluorescence microscopy with 476 nm argon ion laser epillumination, and compared to morphology in serial sections stained with H & E, Movat pentachrome, and oil red O. Normal artery autofluorescence correlated morphologically with the structural protein fibers elastin and collagen in the intima, media, and adventitia. Atherosclerotic plaque autofluorescence correlated morphologically with lipid or calcified deposits in the atheroma core.

Fluorescence spectroscopy of turbid media: Autofluorescence of the human aorta.

Fluorescence spectra of turbid media depend on the geometry of excitation and collection. The geometry dependence of 476-nm excited fluorescence of the human arterial wall was investigated both experimentally and with a Monte Carlo simulation. Optical properties and the fluorescence yield of each of the three arterial layers were determined.

Spectral diagnosis of atherosclerosis using an optical fiber laser catheter.

This communication demonstrates that fluorescence spectra of human aorta with good S/N ratios can be collected using an optical fiber laser catheter. The performance of this catheter is compared to a non-fiber optic collection system with an equivalent delivery/collection geometry. For a given sample, fluorescence lineshapes obtained using the two systems are identical; differences in peak fluorescence intensity are related to the different collection efficiencies of the two systems.

Lyme carditis: an important cause of reversible heart block.

Lyme disease is a tick-borne spirochetal infection, characterized by erythema chronicum migrans and an acute systemic illness. The disease is endemic in many parts of the north-eastern United States. Without treatment, late rheumatic, neurologic, and cardiac complications frequently occur.

An overview of activities at the Laser Biomedical Research Center.

Research projects on laser heating and ablation and on spectroscopy of biological tissues are described. The discussion focuses on studies regarding microscopic laser light scattering of biological cells and structures, ablation of calcific tissue using pulsed HF laser radiation, and fluorescence and its use in diagnosing atherosclerosis. A specifically designed multifiber laser catheter constructed to collect tissue fluorescence spectra using fiber optics is described.

Alteration of spectral characteristics of human artery wall caused by 476-nm laser irradiation.

Fluorescence spectroscopy is a promising new technique for discrimination of normal and atherosclerotic arterial tissues. It has been suggested that this technique be used as a guidance system for laser angiosurgery catheters; however, irradiation by 476-nm light can change the spectroscopic properties of arterial tissue. We present studies that establish intensity levels and exposure times at which alterations in tissue spectral properties are minimal.

Removal of surgically induced fibrous arterial plaques by argon ion laser angiosurgery using a multifiber delivery system. An experimental study in the dog.

Removal of intravascular atherosclerotic obstructions by laser irradiation has gained the attention of many investigators, but has proven to be considerably more difficult to accomplish than initially envisioned. We tested, in an animal model, an argon ion laser delivery system that permits control of (1) laser power, (2) exposure time, and (3) laser beam spot size. The study was conducted on surgically, induced focal fibrous plaques in the carotid arteries of nine dogs.

Remote biomedical spectroscopic imaging of human artery wall.

We discuss a general technique, laser spectroscopic imaging (LSI), remote acquisition of spectroscopic images of biological tissues and tissue conditions. The technique employs laser-induced spectroscopic signals, collected and transmitted via an array of optical fibers, to produce discrete pixels of information from which a map or image of a desired tissue characteristic is constructed. We describe a prototype LSI catheter that produces spectral images of the interior of human arteries for diagnosis of atherosclerosis.

Gas volume quantitation during argon ion laser ablation of atheromatous aorta in blood and 0.9% saline media with an optically shielded catheter.

Using an optically shielded fiber optic laser catheter, the amount of gas produced when firing an argon ion laser into 0.9% saline solution or blood alone and into atheromatous aorta in either a blood or 0.9% saline medium was quantitated.

Effects of varying argon ion laser intensity and exposure time on the ablation of atherosclerotic plaque.

Using continuous wave (CW) argon ion laser light, a total of 253 laser exposures of varying power (1.5, 3, 5, 8 or 10 W) and duration (20-1,333 ms) were delivered to four segments of human atheromatous aorta obtained at autopsy. Exposure conditions were controlled by using an optically shielded laser catheter that provided a 500 micron spot of light of known power.

A model for thermal ablation of biological tissue using laser radiation.

We present a theory of thermal laser ablation based on the heat equation and on an energy balance equation derived from it. Ablation is assumed to be brought about by the heating and evaporation of tissue water. The model is three-dimensional, and scattering and the water-steam phase transition are explicitly taken into account.

Reliability of symptoms in assessing control of gastric acid secretion in patients with Zollinger-Ellison syndrome.

In the present study we explored whether the presence or absence of symptoms could provide a reliable way of assessing the adequacy of control of gastric secretion in patients with Zollinger-Ellison syndrome who were treated medically. Over a 5-yr period, 26 Zollinger-Ellison syndrome patients were entered into a prospective study which examined the presence or absence of symptoms that are associated with gastric hypersecretion, the presence of absence of upper gastrointestinal pathology, and the degree of control of gastric acid secretion. During their last admission, 15 of the 26 patients (58%) were symptomatic, but post-drug gastric acid secretion for the 2 h before the next dose of medication was not significantly different from that in asymptomatic patients.

Safety of fiberoptic bronchoalveolar lavage in evaluation of interstitial lung disease.

Over a three-year period, 281 fiberoptic bronchoalveolar lavage procedures were performed on 119 individuals with interstitial lung disease and 22 normal volunteers. There were no major complications. Less than 5 percent of the procedures were associated with minor complications including (2.