Optics: measuring and testing – By dispersed light spectroscopy – With sample excitation
Patent
1996-04-25
1998-07-07
McGraw, Vincent P.
Optics: measuring and testing
By dispersed light spectroscopy
With sample excitation
2504591, G01N 2164
Patent
active
057777322
DESCRIPTION:
BRIEF SUMMARY
FIELD OF THE INVENTION
The invention concerns a process for luminescence-scanning microscopy according to the introductory part of the principal claim and a luminescence-scanning microscope for carrying out this process.
BACKGROUND OF THE INVENTION
Such a process is known from U.S. Pat. No.5,034,613. The described process concerns a process with two-photon excitation. An object to be examined, preferably a biological object, is treated with a luminescent, especially a fluorescing dye. The dye contained in the object is excited by the joint action of two photons and the light emitted by the dye recorded and evaluated. To cover the entire sample, the laser beam is scanned over the object. The values of all points on the object are recorded, making a three-dimensional representation of the results of evaluation possible. The two-photon excitation, in conjunction with the rasters, leads to as direct three-dimensional image of the object. To increase the probability of the two-photon excitation, use is made of laser pulses with a duration in the sub-picosecond range. Lasers which generate such extremely short pulses are very expensive. Moreover, biological objects are often destroyed by the high-output pulses. An excitation of the object with laser pulses in the sub-picosecond range often causes the luminescence signal to "collapse". This "collapse" can be envisioned as a "micro-explosion" which destroys the object material.
SUMMARY OF THE INVENTION
The problem addressed by the invention is to develop a generic process in such a way that the disadvantages cited above do not occur.
It was surprisingly discovered that a measurement of two-photon luminescence is possible with laser pulses of relatively long duration, or even with continuous light, and leads to good measurements. By excitation with laser pulses whose duration is longer than 10.sup.-12 seconds, or by excitation with continuous light, the output peaks in the excitation light are reduced to the point where the destruction of the object does not take place. A very advantageous range of the pulse length lies in the picosecond range. Because the laser pulses used exhibit a lower output than those in the sub-picosecond range, longer measuring times are used, the sensitivity of the detector employed being adapted to the conditions of measurement. It was found that the use of photon counting as the evaluation process yields good measurements. It is particularly advantageous if an avalanche photodiode is employed as the detector. The reception and evaluation of the measurement results are possible even with continuous laser light of moderate output. With an appropriately extended period of measurement and the selection of a detector with a high signal-noise ratio, the results are comparable to those with the process using laser pulses in the sub-picosecond range.
It is of particular advantage that commercial lasers with continuous or pulsed radiation can be used as the light source to carry out the invented process. These are not expensive. Ordinary semiconductor or gas lasers can be employed. Suitable as gas lasers are, in particular, HeNe lasers and krypton lasers. The laser arrangement can also be in the form of an array. The utilization of two or three lasers for illumination of the same object point has proven to be particularly advantageous.
As already stated above, it is essential that a detector with a high signal-noise ratio be used to receive and evaluate the luminescing light. It is of particular importance in that case that the detector used have a correspondingly high sensitivity and a small intrinsic noise. The arrangement of the lasers and detectors in the form of an array and the illumination and measurement of several points thus permitted provides the possibility of shortening the duration of the process. It is advantageous to arrange a beam-scanning device in front of the object, the beam being in that case scanned over the object.
Provision is also made in the case of the invented luminescence-scanning microscope for filters to sep
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"Two Photon Excitation in Time-Resolved Fluorescence Microscopy", Pekka Hanninen, et al, University of Turku, Medical Physics, P.O. Box 123, SF-20521, Turku, Finland, SPIE vol. 2184 (7-8 Feb. 1994 pp. 66-71.
Hanninen Pekka
Hell Stefan
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