B.G. de Grooth

Optical tracking and detection of immunomagnetically selected and aligned cells.

We have developed a platform for cell analysis based on immunomagnetic selection and magnetic alignment of cells in combination with an epi-illumination tracking and detection system. Whole blood was labeled with ferromagnetic nanoparticles and fluorescent probes, and placed in a magnetic field in a chamber. Cells labeled with ferromagnetic nanoparticles moved upward and aligned along ferromagnetic lines deposited by lithographic techniques on an optically transparent surface of the chamber. An epi-illumination system using a 635 nm laser diode as a light source scanned the lines and measured signals obtained from the aligned cells. The cell counts per unit of blood volume obtained with the system correlated well with those obtained from the counts from a standard hematology analyzer and flow cytometer. The cell analysis platform is significantly less complex and more sensitive than current cell analysis equipment and provides additional functionality through its ability to subject the cells to repeated and varied analyses while they remain in a natural environment (i.e., whole blood).

A new imaging mode in Atomic Force Microscopy based on the error signal

A new imaging mode, the error signal mode, is introduced to atomic force microscopy. In this mode, the error signal is displayed while imaging in the height mode. The feedback loop serves as a high-pass filter that filters out the low spatial frequency components of the surface, leaving only the high spatial frequency components of the surface to contribute to the error signal and to be displayed. At a scan rate of typically 10 lines per second, images taken in this mode show very fine detail. Since the applied force stays nearly constant, the error signal mode is especially suitable for imaging soft biological samples with a high level of detail without damaging the surface.

High-resolution imaging of chromosome-related structures by atomic force microscopy.

An atomic force microscope (AFM) was combined with a conventional optical microscope. The optical microscope proved to be very convenient for locating objects of interest. In addition, the high‐resolution AFM image can be compared directly with the traditional optical image. The instrument was used to study chromosome structures. High‐resolution chromosome images revealed details of the 30‐nm chromatide structure, confirming earlier electron microscopic observations. Chromosomes treated with trypsin revealed a banding pattern in height which is very similar to the optical image observed after staining with Giemsa. Furthermore, it is shown that the AFM can be used to locate DNA probes on in situ hybridized chromosomes. Images of the synaptonemal complex isolated from rat spermatocytes revealed details that improve the understanding of the three‐dimensional structure of this protein.

OPTIMIZATION OF MACROMOLECULAR PRODRUGS OF THE ANTITUMOR ANTIBIOTIC ADRIAMYCIN

In our earlier work [10] on aminoribosyl-bound prodrugs of adriamycin (ADR) using poly(α-l-glutamic acid) (PGA) grafted in high yield (90–100 mol.%) with various peptide spacers as a plasma-soluble macromolecular carrier we observed rather low cytotoxic activities in L1210 leukemia and B16 melanoma in vitro assays. These results may be tentatively explained by a decreased susceptibility of the spacer-bound adriamycin moiety to hydrolysis by lysosomal enzymes due to the high spacer load. This hypothesis was tested by the study of two conjugates prepared by a different route. Peptide conjugates of adriamycin (Gly-Gly-Leu—ADR and Gly-Gly-Gly-Leu—ADR) were synthesized using the trityl N-protecting group and were coupled to PGA in 4.5 mol.% load according to the method described earlier [11]. However, these conjugates were almost totally devoid of cell growth-inhibiting activity in L1210 and B16 in vitro tests. The data suggest that either the uptake of the polymeric prodrugs into the cell by pinocytosis is highly dependent on spacer load or molecular weight, or that lysosomal digestion is too slow for efficient release of ADR. Possibly, enzymatic degradation of PGA which is known to occur only between pH 4 and 6 is rate-limiting for release of the drug. Current studies include the enzymatic degradation of PGA—peptide spacer—drug systems using p-nitroaniline as a model drug and papain as the enzyme. By variation of the length and load of spacer it can be estimated under which conditions the release of drug (using UV spectrometry) is faster than degradation of the polymer (as determined by viscometry). In addition, the uptake of PGA and derivatives with a fluorescent label into tumor cells is studied using laser flow cytometry and laser microscopy.

Three dimensional single-particle tracking with nanometer resolution

We have developed a method for three dimensional (3D) tracking of polystyrene spheres with nanometer resolution. The detection technique is based on measuring the displacement of a polystyrene sphere positioned in the center of a laser beam just behind the focus. A change in the lateral position of the sphere causes a deflection of the beam which can be measured using a position sensitive detector. A change in the axial position of the sphere causes a shift in the axial position of the focus behind another lens, which can be measured using an overfilled photodiode. A feedback system is used to keep the sphere in the center of the laser beam to avoid the influence of lateral displacements on the detection of the axial position. Spatial resolution for a 0.92 μm polystyrene sphere was better than 1 nm in three dimensions using a sampling rate of 1 kHz. This method was applied to track spheres bound to adhesion molecules LFA-1 expressed at the surface of living cells. It turned out to be a useful method to ac...

Comparative atomic force and scanning electron microscopy: an investigation on fenestrated endothelial cells in vitro

Rat liver sinusoidal endothelial cells (LEC) contain fenestrae, which are clustered in sieve plates. Fenestrae control the exchange of fluids, solutes and particles between the sinusoidal blood and the space of Disse, which at its back side is flanked by the microvillous surface of the parenchymal cells. The surface of LEC can optimally be imaged by scanning electron microscopy (SEM), and SEM images can be used to study dynamic changes in fenestrae by comparing fixed specimens subjected to different experimental conditions. Unfortunately, the SEM allows only investigation of fixed, dried and coated specimens. Recently, the use of atomic force microscopy (AFM) was introduced for analysing the cell surface, independent of complicated preparation techniques. We used the AFM for the investigation of cultured LEC surfaces and the study of morphological changes of fenestrae. SEM served as a conventional reference.

Fluorescence in situ hybridization on human metaphase chromosomes detected by near-field scanning optical microscopy

Fluorescence in situ hybridization on human metaphase chromosomes is detected by near‐field scanning optical microscopy. This combination of cytochemical and scanning probe techniques enables the localization and identification of several fluorescently labelled genomic DNA fragments on a single chromosome with an unprecedented resolution. Three nucleic acid probes are used: pUC1. 77. p1–79 and the plasmid probe α‐spectrin. The hybridization signals are very well resolved in the near‐field fluorescence images, while the exact location of the probes can be correlated accurately with the chromosome topography as afforded by the shear force image.

Operation of a scanning near-field optical microscope in reflection in combination with a scanning force microscope

Images obtained with a scanning near field optical microscope (SNOM) operating in reflection are presented. We have obtained the first results with a SiN tip as optical probe. The instrument is simultaneously operated as a scanning force microscope (SFM). Moreover, the instrument incorporates an inverted light microscope (LM) for preselection of a scan area. The SiN probe is operated in the contact regime causing a highly improved lateral resolution in the optical image compared to an alternative set-up using a fiber probe, which is also presented. The combined microscope is operated either in open loop or as a force regulated SNOM. Near field optical images can be directly compared with the topography displayed in the simultaneously recorded SFM image.

Experimental and model investigations of bleaching and saturation of fluorescence in flow cytometry

We investigated the fluorescence emission from three fluorophores commonly used for labeling cells in flow cytometry. We have demonstrated that the fluorescence emission from cells labeled with fluorescein-isothiocyanate (FITC), phycoerythrin (PE), and allophycocyanin (APC) is considerably saturated and bleached in standard flow cytometric conditions. Therefore, for optimization of fluorescence detection in a flow cytometer, it is important to know the emission kinetics in detail. We made a mathematical model of the optical processes involved: absorption, fluorescence emission, nonradiative decay, photodestruction, and triplet state occupation. The validity of the model was experimentally tested with a set of averaged fluorescence pulses, measured in a large range of intensities and illumination times. The fluorescence of APC could be completely described by the model and produced the following rate constants: photodestruction rate kb1 = 6 x 10(3) s(-1), triplet state population rate k12 = 2 x 10(5) s(-1), and depopulation rate k20 = 5 x 10(4) s(-1). The fluorescence kinetics of FITC- and PE-labeled cells could not be fitted with only three parameters over the entire range, indicating that other optical processes are involved. We used the model to determine the sensitivity of our flow cytometer and to calculate the optimum conditions for the detection of APC. The results show that in principle a single APC molecule on a cell can be detected in the presence of background, i.e., autofluorescence and Raman scattering by water.

Cell Analysis System Based on Immunomagnetic Cell Selection and Alignment Followed by Immunofluorescent Analysis Using Compact Disk Technologies

BACKGROUND Although the flow cytometer has become the standard in cell analysis, it has limitations. Recently, we introduced a new cell analysis method based on immunomagnetic selection and aligning of cells. No flow system is needed and cell analysis can be performed in whole blood. METHODS Whole blood is incubated with fluorescent labels and immunomagnetic nanoparticles. The blood is injected into a capillary that is in a strong magnetic field. The immunomagnetic-labeled cells move upward and align themselves along ferromagnetic lines present on the upper surface of the capillary. An optical focus and tracking system analogous to that used in a conventional compact disk player focuses a 635-nm laser-diode on the magnetically aligned cells. The emitted fluorescence signals are projected on two photomultipliers. Allophycocyanin (APC)-labeled CD4 (CD4-APC) and Cyanin5.5 (Cy5.5)-labeled CD8 (CD8-Cy5.5) antibodies and Oxazine750, all red excited, are used as fluorescent labels. RESULTS A differential white blood cell count performed in whole blood is obtained using the CD4-APC in combination with Oxazine750. The results are compared with the Technicon-H1 hematology analyzer. Correlation coefficients of 0.91 for neutrophilic granulocytes, 0.93 for lymphocytes, 0.93 for monocytes, and 0.96 for eosinophilic granulocytes were obtained. Immunofluorescence is demonstrated using CD4-APC and CD8-Cy5.5. The absolute counts obtained for CD4+ and CD8+ are compared with the Coulter Epics XL flow cytometer. Correlation coefficients of, respectively, 0.91 and 0.94 were obtained. CONCLUSION We conclude that our system is as capable as a standard flow cytometer or hematology analyzer for a reliable routine white blood cell analysis, including immunophenotyping, and can be used as an easy-to-handle disposable white blood cell test.