1. Cell Structure and Cell Function
1.1 Structural flow cytometry:
The flow cytometric determination of structural cellular constituents
(Tab.1) is in use for many years e.g. for the determination of DNA
distributions, cellular antigen contents or natural pigment analysis like
chlorophyll or phycobiliproteins in plankton cells. Simultaneous
biophysical measurements of electrical or optical (FSC) cell volume
and optical granularity (SSC) complement the cell characterization.
1.2 Functional flow cytometry:
Structural flow cytometric measurements do not permit to follow rapid
functional changes of cells such as e.g. changes of intracellular pH, of
cellular excitation or of energy production.
Functional changes are early indicators of cell growth, death or differentiation e.g. in clonal development of the immune or hematopoietic system but they equally indicate signalling for specific actions of differentiated cells e.g. granulocytes under cytokine influence or thrombocytes in prethrombotic conditions.
Comparing for a moment a cell with a house: when somebody puts on his coat, no structural but a functional change has occured because neither the number of persons nor the coats change. Recognition of this action provides the diagnosis of the functional change but potentially more important the prognosis that somebody will soon leave the house.
The extraction of prognostic features from cell function measurements is of high interest for medicine but also for cell biological research in general.
2. Cell function:
2.1 Microscopical methods:
The determination of single cell functions was difficult and limited in
the past because microelectrodes had to be introduced into single cells
e.g. for transmembrane potential or pH-measurements. More recently patch
clamping techniques have enlarged the potential for functional investigations
on cells or membrane fragments but only the development of laser scanning
microscopes and digital imaging techniques has really opened the large
potential for cell function measurement with fluorescent dyes.
The main advantage of the microscope is the possibility for detailed morphological single cell observation. Disadvantages are difficulty of quantitation, usually lower speed of analysis, sample exposure to high light intensities causing fluorescence bleaching, sample heating and observation of cells in the very small fluid volume under the cover slip with potentially suboptimal conditions of osmotic pressure, nutrient or oxygen/CO2 concentrations. Prolonged exposure to high light intensities may in addition influence the biochemical behaviour of cells.
2.2 Flow cytometric methods:
Cell functions (Tab.1) can be determined at high speed in flow cytometers
with a multitude of biochemically specific, non toxic fluorescent indicator
molecules close to the in-vivo state and without prolonged exposure to unusual
light levels. Heterogeneous cell suspensions from the body but also from sweet
and salt water microorganism suspensions can be investigated with a minimum of
preparation.
The acceleration in the flow cytometer and the transition of a cell through the sensing light beam takes only fractions of a second (5-50usec) i.e. the influence of the measurement process on the cells is minimal. Furthermore flow cytometry offers ideal statistical sampling as well as optimal biochemical conditions during the pre-measurement phase. This mostly outweighs the usual impossibility to investigate the same cell several times e.g. following restaining with other biochemical markers which represents a typical advantage of the microscope.
Functional cell assays are easily performed by flow cytometry. The addition of dye or dye cocktail is followed by an incubation time between 1 and 15 min. In most instances the stained cell sample can then be measured immediately. In some instances there is a centrifugation step followed by resuspension of the cells in buffer to lower the extracellular dye concentration (e.g. rhodamine123). The centrifugation step can, however, mostly be substituted by a dilution step if the primary assay is performed in a small buffer volume at high cell concentration.
Tab.1
CELL BIOCHEMISTRY BY FLOW CYTOMETRY
STRUCTURE
- DNA/RNA
- proteins
- carbohydrates
- lipids
- antigens
- hormon receptors
- fluorescent in-situ hybridization
FUNCTION
- metabolism: intracellular pH
- excitation: calcium
- energy: transmembrane and mitochondrial potentials
- oxidation: O2-,H2O2, free radicals
- reduction: glutathione, free protein SH-groups
- enzymes: esterases, peroxidases, proteases (cathepsins), glucosidases, phosphatases etc.
3. Flow cytometer setup for functional stains:
3.1 mammalian cells:
Using the 488nm line of an argon ion laser for fluorescence excitation, the
emitted fluorescent light is typically collected by bandpass filters between
510-540nm, 550-590nm and 620-750nm corresponding to the fluorescein (FITC),
phycoerythrin (PE) and tandem conjugate (PE-CY5, PERCP) channel for immune pheno
typing.
Functional stains are usually equally well measurable with a high pressure mercury arc lamp (HBO-100) using a 450-500nm band pass filter for fluorescence excitation in combination with the above emission filters.
The fluorescence emission light channels can be used for a variety of functional stains e.g. the green FITC-light channel for: DiOC6 transmembrane potential, rhodamine123 (R123) mitochondrial potential, dihydrorhodamine123 (DHR) or dichlorofluorescin (DCFH) metabolic burst measurements, rhodamine110 (R110) substrates for the determination of cysteine-, serine-, metallo- or carboxy proteinases, the orange PE-light channel for FLUO-3 calcium or SNARF-1 intra cellular pH-measurmenents while the red light channel is frequently used to check the presence and DNA-distribution of dead cells following staining with propidium iodide (PI).
The strong UV-lines of high pressure mercury arc lamps around 365nm can be used to excite 1,4-diacetoxy-2,3-dicyanobenzene (ADB) for intracellular pH- measurements, INDO1 calcium stain or orthophtaldialdehyde (OPT) free gluta thione and free protein SH-group stain. Fluorescence emission is collected by a 390-440nm bandpass filter and a 500nm long pass filter. The DNA of dead cells is again stained with PI which equally well excites at 365nm and at 488nm.
4. Data evaluation:
Usually several stains are performed on aliquots of the same cell sample. The
measurements are recorded as list mode files (FSC, SSC, F1, F2, F3, time) and
can be automatically evaluated by the
CLASSIF1
program system. The results of this multi window evaluation in several
dimensions are stored in databases.
Given a learning set of clinically or experimentally known cell samples, the software learns the most significant differences from the different databases, merges the data columns of interest into a new database and automatically establishes a self learning classifier.
This classifier can prospectively classify unknown cell samples, stained according to the same rules as the training set samples. Provided that the measurements are properly long term standardized with fluorescent calibration particles, standardized classifiers can be elaborated. They are flow cytometer and laboratory independent and therefore suitable for consensus formation and international standardization.
5. Cytometry on the INTERNET:
Information on new developments can be obtained on Internet
from the Martinsried Cell Biochemistry homepage:
http://www.biochem.mpg.de/valet/cellbio.html
or more generally from the
CytoRelay node. The address (URL) is:
http://www.biochem.mpg.de/valet/cytorel.html
Off-line Internet copies of the entire information on both nodes for use in PC's are obtained either by regularly updated FTP-downloads from pcv4.biochem.mpg.de/cytorel/martins1.zip or biannually from the Purdue Cytometry CD-ROM
6.2 REAGENTS:
PMA = phorbol-myristate-acetate (MW: 662.0),
Nr.P8139, Sigma, St.Louis, USA
H2O2 = perhydrol 30% (MW: 34.01),
Nr.7210, Merck, Darmstadt, Germany
ionomycin = calcium ionophore (MW: 709.0),
Nr.407950, Calbiochem, Bad Soden, Germany
A23187BR = calcium ionophore (MW: 602),
Nr.100107, Calbiochem, Bad-Soden, Germany
gramicidin D = H+-ionophore (MW: ...),
Nr.G-5002, Sigma, St.Louis, USA,
Z-Phe-Ala-CHN2 = cathepsine B,H,L, cysteine proteinase inhibitor
(diazo-methyl-ketone, MW 394.4),
Nr.1040, Bachem, Heidelberg, Germany
Z-Leu-CHN2 = aminopeptidase, metalloproteinase inhibitor (chloro-
methyl-ketone, MW 200.11),
Nr.1260, Bachem, Heidelberg, Germany
DFP = di-isopropylfluorophosphate, cathepsin G serine proteinase
inhibitor, (MW 181,15),
Nr.D08979, Sigma-Aldrich-Chemie, St. Louis, USA
EDTA = 0.2 M pH 7.2 (di-Na EDTA, (MW: 372.25),
Nr.8418, Merck, Darmstadt, Germany
CaCl2 = 0.3 M CaCl2.2H2O solution aqua dest. (MW: 110.99),
Nr.2382, Merck, Darmstadt, Germany
HgCl2 = mercury-II-chloride (MW: 200.59),
Nr.4404, Merck, Darmstadt, Germany
particles = PolybeadTM Carboxylate Microspheres(2.5% Latex-Solids),
UV excitable (365nm),
Nr.18340 4.5um BB, 488nm FITC-excitable
Nr.16592 4.5um, YG Polysciences Ltd., Warrington, USA,
NaCl = Natriumchlorid (MW: 58.44),
Nr.6404, Merck, Darmstadt, Germany
HEPES = N-(2-Hydroxyethyl)-piperazine-N'-2-ethane-sulfonic acid (MW:
238.3),
Nr.25245, Serva, Heidelberg, Germany
HBS-buffer = 0.15M NaCl2, 5mM HEPES pH 7.35
DMF = di-methylformamide, (MW: 73.10),
Nr.D-27054-7, Sigma, St.Louis, USA
DMSO = di-methylsulfoxide, (MW: 78.13),
Nr.D-8779, Sigma Chemicals, St.Louis, USA
Bachem
Lessingstr. 26
D-69115 Heidelberg
Germany
Tel: +49/6221/163091
Fax: +49/61221/21442
E-mail: --
Calbiochem
Lisztweg 1
D-65796 Bad Soden
Germany
Tel: +49/6196/63955
Fax: +49/6196/62361
E-mail: --
Eastman Kodak
LRPD-1001 Lee Road
P.O.Box 92822
Rochester NY 14692-7073
USA
Tel: +1/716/588-4817
Fax: +1/716/722-3179
E-mail: --
Merck
Frankfurter Str. 250
D-64291 Darmstadt
Germany
Tel: +49/6151-72-0
Fax: +49/6151-72-2000
E-mail: --
Molecular Probes
4849 Pitchford Av.
Eugene, OR 97402-9144
USA
Tel: +1/541/465-8300
Fax: +1/541/344-6504
Molecular Probes, Europe
PoortGebouw Rijnsburgerweg 10
NL-2333AA Leiden
The Netherlands
Tel: +31/71-5233-378
Fax: +31/71-5233-419
E-mail: Customer Service and Technical Assistance: 76225.2203@compuserve.com
Internet: Molecular Probes, USA
Polysciences Inc.
400 Valley Road
Warrington, PA 18976
USA
Tel: +1/215/-343-6484
Fax: +1/215/-343-0214
Polysciences Inc. Europe
Handelsstr. 3
D-69208 Eppelheim
Germany
Tel: +49/6221-76576
Fax: +49/6221-764620
E-mail: --
SERVA
Carl-Benz-Str.7
D-69115 Heidelberg
Germany
Tel: +49/6221/502-122, -123, -124
Fax: +49/6221/502-188
E-mail: --
Sigma Chemical Company
P.O.Box 14508
St. Louis, MO 63178-9916
USA
Tel: +1/314-771-5750
Fax: +1/314-771-5757
Sigma-Aldrich Chemie GmbH
Grünwalder Weg 30
D-82041 Deisenhofen
Germany
Tel: +49/89/6513-0
Fax: +49/89/6513-1161
E-mail: --
Internet: Sigma-Aldrich, USA
Sigma-Aldrich, Germany
standard assay:
250ul cell suspension (1x106-107 cells/ml)
+5ul ADB 1mg/ml, PI 2mg/ml cocktail in DMF
- incubate 5min at 22oC
- measure (ADB 20ug/ml (82uM), PI 40ug/ml (60uM))
pH calibration assay:
250ul cell suspension (5x107 cells/ml)
+5ul ADB 1mg/ml, PI 2mg/ml cocktail in DMF
+5ul gramicidine D 1mg/ml in DMSO
+5ul 5% NaN3-solution in HBS buffer
- incubate 10min at 22oC
- dilute 5ul assay aliquots in 250ul portions of 10mM phosphate buffered
saline pH 5.0, 5.5, 6.0, 6.5, 7.0, 7.5, 8.0, 8.5, 9.0 containing 5ul ADB
1mg/ml, PI 2mg/ml cocktail in DMF
- incubate 10min at 22oC
- measure (ADB 20ug/ml (82uM), PI 40ug/ml (60uM), NaN3 0.1%, gramicidin
D 20ug/ml)
6.4.2 INTRACELLULAR CALCIUM:
INDO1/AM: INDO1-acetoxymethylester MW:1009.9 D
- freeze A23187Br or ionomycin ionophore at -85o C or -180o C to prevent decay
assay1: intracellular calcium
250ul cell suspension
+5ul INDO1/AM 1mg/ml (HBO-100), 0.1mg/ml (HeCd laser), PI 2mg/ml
cocktail in DMF
- incubate 15min at 22oC
- measure (INDO1 20.2ug/ml (20.2uM), PI 40ug/ml (60uM))
assay2: ionophore + EDTA = extract intracellular calcium
250ul cell suspension
+5ul INDO1/AM 1mg/ml (HBO-100), 0.1mg/ml (HeCd laser), PI 2mg/ml
cocktail in DMF
- incubate 15min at 22oC
+5ul A23187Br or ionomycin ionophore 1mg/ml DMF
- incubate 10min at 22oC
+5ul 0.2M EDTA pH 7.35
- incubate 10min at 22oC
- measure (INDO1 20.2ug/ml (20.2uM), PI 40ug/ml (60uM), EDTA 4mM,A23187Br 20ug/ml (33uM)
assay3: ionophore + calcium = set intracellular calcium to 1mM
250ul cell suspension
+5ul INDO1/AM (ester) 1mg/ml(HBO-100), 0.1mg/ml (HeCd laser), PI 2mg/ml cocktail in DMF
- incubate 15min at 22oC
+5ul A23187Br or ionomycin ionophore 1mg/ml DMF
- incubate 10min at 22oC
+5ul 0.3M CaCl2
- incubate 10min at 22oC
- measure (INDO1 20.2.ug/ml (20.2M), PI 40ug/ml (60uM), CaCl2 6mM, A23187Br 20ug/ml (33uM))
6.4.3 FREE GLUTATHIONE/FREE PROTEIN SH-GROUPS:
OPT: ortho-phthaldialdehyde MW: 134.1 D
assay1: free glutathione/free protein-SH
250ul cell suspension
+5ul OPT 6.70mg/ml in DMF
+5ul PI 2mg/ml in HBS
- incubate 10min at 0oC
- measure (OPT 134ug/ml, (1mM), PI 40ug/ml (60uM))
assay2: Hg2+ blocking of free SH-groups
250ul cell suspension
+5ul HgCl2 27.15mg/ml in HBS
- incubate 5min at 0oC
+5ul OPT 6.70mg/ml DMF
+5ul PI 2mg/ml in HBS
- incubate 10min at 0oC
- measure (OPT 134ug/ml, (1mM), HgCl2 0.54mg/ml (2.7mM), PI 40ug/ml (60uM))
6.4.4 VITAL DNA STAIN:
Hoechst H33258 bisbenzimide MW: 623.97 D (slow penetration)
assay:
250ul cell suspension
+5ul H33258 0.312mg/ml in HBS
- incubate 30min at 37oC
+5ul PI 2mg/ml in HBS
- incubate 5min at 22oC
- measure (H33258 6.24ug/ml, (10uM), PI 40ug/ml (60uM))
6.4.5 VITAL DNA STAIN:
Hoechst H33342 Bisbenzimide MW: 615.99 D (fast penetration)
assay:
250ul cell suspension
+5ul H33342 0.308mg/ml in HBS
- incubate 30min at 37oC
+5ul PI 2mg/ml in HBS
- incubate 5min at 22oC
- measure (H33342 6.16ug/ml, (10uM), PI 40ug/ml (60uM))
6.5.1 CELLULAR ENERGY:
DI0C6: transmembrane potential 3,3-dihexyl-oxacarbocyanine(3)
MW: 572.5 D propidium iodide (PI) MW: 376.3 D
assay:
250ul cell suspension
+5ul DIOC6 10ug/ml, PI 2mg/ml in dimethylformamide (DMF)
- incubate for 5 min at 22oC
- measure (DiOC6 0.2ug/ml (0.35uM), PI 40ug/ml (60uM))
6.5.2 CELLULAR ENERGY:
R123: mitochondrial membrane potential rhodamine123 MW: 380.8 D
assay:
250ul cell suspension
+5ul R123 0.5mg/ml in DMF
- incubate 30min at 37oC
- dilute with 750ul HBS
+20ul PI 2 mg/ml in 10mM HEPES buffered saline pH 7.35 (HBS)
- incubate 5min at 22oC
- measure (R123 10ug/ml (26uM), PI 40ug/ml (60uM))
6.5.3 METABOLIC STATE:
SNARF1/AM: intracellular pH, SNARF1-acetoxymethylester MW: 568 D
- predilute: 0.568mg/ml (1mM) SNARF1/AM stock solution in DMF daily 1/100
with 2mg/ml PI in HBS (SNARF1/AM 1/100 5.68ug/ml, 10uM)
assay:
250ul cell suspension
+5ul SNARF1/AM 5.68ug/ml, PI 2mg/ml in HBS
- incubate 30min at 37oC
- measure (SNARF1/AM 0.11ug/ml (.2uM), PI 40ug/ml (60uM))
6.5.4 EXCITATION STATUS:
FLUO3/AM: intracellular Ca2+, FLUO3-acetoxymethylester MW: 1130 D
- predilute: 1.13mg/ml (1mM) FLUO3/AM stock solution in DMF daily 1/50
with 2mg/ml PI in HBS (FLUO3/AM 1/50 22.6ug/ml, 20uM)
assay:
250ul cell suspension
+5ul FLUO3/AM 22.6ug/ml, PI 2mg/ml in HBS
- incubate 30min at 37oC
- measure (FLUO3/AM 0.45ug/ml (0.4uM), PI 40ug/ml (60uM))
6.5.5 OXIDATIVE BURST AND PEROXIDASE ACTIVITY:
DHR: sensitive H2O2 and peroxidase indicator system (8 x DCFH-DA)
dihydrorhodamine123 MW: 346.0 D
- DHR stock solution: 1.5mg/ml (4.0mM) in DMF, freeze at: -180oC
- predilute: 5ul DHR 1.5mg/ml in DMF + 500ul 2mg/ml PI in HBS (DHR 1/100,
15ug/ml,40uM, PI 2mg/ml 3mM, DMF 1%), freeze at: -180oC
- PMA stock solution: 0.662mg/ml (1.0mM) in DMF, freeze in 5ul portions in
1.5ml Eppendorf conical tubes with snap caps, predilute freshly with 1ml HBS
(PMA 5uM, DMF 0.5%)
- H2O2: 1/200 (50mM) prediluted from Perhydrol (Merck) with HBS
assay1: spontaneous oxidation
250ul cells
+5ul DHR 15ug/ml, PI 2mg/ml, DMF 1%
- incubate 15min at 22oC
- measure (DHR 0.3ug/ml (.86uM), PI 40ug/ml (60uM), DMF 0.02%)
assay2: PMA stimulation (positive control)
250ul cells
+5ul DHR 15ug/ml, PI 2mg/ml, DMF 1%
- incubate 15min at 22oC or 37oC
+5ul PMA 5uM, DMF 0.5% in HBS
- incubate 10min at 22oC or 37oC
- measure (DHR 0.3ug/ml (.86uM), PI 40ug/ml (60uM), DMF 0.03%)
assay3: peroxidase activity
250ul cells
+5ul DHR 15ug/ml, PI 2mg/ml, DMF 1%
- incubate 15min at 22oC or 37oC
+5ul H2O2 (50mM) prediluted 1:200 with HBS from Perhydrol (Merck)
- incubate 10min at 22oC or 37oC
- measure (DHR 0.3ug/ml (.86uM), H2O2 (1mM), PI 40ug/ml (60uM), DMF
.02%)
6.5.6 OXIDATIVE BURST AND PEROXIDASE ACTIVITY:
DCFH-DA: H2O2 formation and peroxidase activity (less sensitive)
dichlorofluorescin-diacetate MW: 487.3 D
- DCFH-DA stock solution 4.87mg/ml (10mM) in DMF
- predilute daily 10ul DCFH-DA stock solution with 90ul HBS buffer containing
2mg/ml PI (DCFH-DA 1/10 0.487mg/ml 1mM, PI 2mg/ml 3mM, DMF 10%)
- PMA stock solution: 0.662mg/ml (1.0mM) in DMF, freeze in 5ul portions
in 1.5ml Eppendorf conical tubes with snap caps
- predilute freshly with 1ml HBS (PMA 5uM, DMF: 0.5%)
- H2O2: 1/200 (50mM) prediluted from Perhydrol (35% H2O2, Merck) with HBS
assay1: spontaneous oxidation
250ul cell suspension
+5ul DCFH-DA 1/10 0.487mg/ml, PI 2mg/ml in HBS, DMF: 10%
- incubate 15min at 22oC
- measure (DCFH-DA 9.74ug/ml (20uM), PI 40ug/ml (60uM), DMF: 0.2%)
assay2: PMA stimulation (positive control)
250ul cell suspension
+5ul DCFH-DA 1/10 0.487mg/ml, PI 2mg/ml in HBS, DMF: 10%
- incubate 15min at 22oC or 37oC
+5ul PMA 5uM, DMF 0.5% in HBS
- incubate 10min at 22oC or 37oC
- measure (DCFH-DA 9.74ug/ml (20uM), PMA 100nM, PI 40ug/ml (60uM),
DMF 0.2%)
assay3: peroxidase activity
250ul cells
+5ul DCFH-DA 1/10 0.487mg/ml, PI 2mg/ml, DMF 10% in HBS
- incubate 15min at 22oC or 37oC
+5ul H2O2 1/200 50mM in HBS from Perhydrol (Merck)
- incubate 10min at 22oC or 37oC
- measure (DCFH-DA 9.74ug/ml (20uM), H2O2 (1mM), PI 40ug/ml (60uM), DMF 0.2%)
6.5.7 OXIDATIVE BURST:
HE: O2- radical formation/general intracellular oxidation, hydroethidine
MW: 315.0 D
- HE stock-solution: 3.15mg/ml (10mM) in DMF, freeze at: -180oC,
working solution refreeze at: -85oC
- predilute 5ul HE 10mM with 150ul 2mg/ml PI in HBS (HE 1/30,
105ug/ml, 330uM, PI 2mg/ml, 3mM, DMF 3.3%
assay1: spontaneous oxidation
+250ul cell suspension
+5ul HE 1/30 105ug/ml, PI 2mg/ml in HBS
- incubate 15min 37oC
- measure (HE 2.1ug/ml (6.6uM), PI 40ug/ml (60uM), DMF 0.07%)
assay2: PMA stimulation (positive control)
assay3: peroxidase activity
(both assays similarly as above)
6.5.8 OXIDATIVE BURST:
SIMULTANEOUS O2- and H2O2 formation + intracellular oxidation DCFH-DA+HE
- predilute: DCFH-DA stock solution 4.87mg/ml (10mM) in DMF 1+9 to 1mM with
2mg/ml PI in HBS daily
- HE stock-solution: 3.15mg/ml (10mM) in DMF, freeze at: -180oC,
working solution refreeze at: -85oC
- predilute 5ul HE 10mM with 150ul 2mg/ml PI in HBS (HE 1/30,
105ug/ml, 330uM, PI 2mg/ml, DMF 3.3%)
assay1:
+250ul cell suspension
+5ul DCFH-DA 1/10 0.487mg/ml, PI 2mg/ml, DMF 10% in HBS
+5ul HE 1/30 105ug/ml, PI 2mg/ml, DMF 3.3% in HBS
- incubate 15min 37oC
- measure (DCFH-DA 9.74ug/ml (20uM), HE 2.1ug/ml (6.6uM), PI 40ug/ml (60uM),
DMF 0.27%)
assay2: PMA stimulation (positive control)
assay3: peroxidase activity
(both assays similarly as above)
6.5.9 PROTEASES:
6.5.9.1 R110 Substrate Solutions:
R110: protease substrates
Stock solutions (4mM):
- (Z-Arg2)2-R110, cath.B: 6.85mg/ml in DMF, dilute 1/20 with 2mg/ml PI in
DMF to 0.274mg/ml (0.2mM)
- (Z-PheArg)2-R110, cath.B: 5.40mg/ml in DMF, dilute 1/20 with 2mg/ml PI in
DMF to 0.270mg/ml (0.2mM)
- (Z-Ala2)2-R110, cath G: 3.53mg/ml in DMF, dilute 1/20 with 2mg/ml PI in
DMF to 0.177mg/ml (0.2mM)
- (NH2-Leu)2-R110, aminopeptidase: 2.22 mg/ml in DMF, dilute 1/20 with 2mg/ml
PI in DMF to 0.111 mg/ml (0.2mM)
- (NH2-Phe)2-R110, aminopeptidase: 2.49 mg/ml in DMF, dilute 1/20 with 2mg/ml
PI in DMF to 0.125 mg/ml (.2mM)
6.5.9.2 PROTEASE INHIBITOR SOLUTIONS
- DFP: 1M stock solution in DMSO, store at -20oC, dilute 1+4 with HBS prior to use,
observe manufacturers safety instruction and handle DFP with extreme care because it
is a potent neurotoxin (volatile cholinesterase inhibitor, antidot: atropine, detoxification
in 5M NaOH, prepare DFP stock solution and 1+4 dilution under ventilated hood, DFP is
stable for several days in protein free physiological solutions !)
- Z-Phe-Ala-CHN2, 3.94mg/ml (10mM) stock solution in DMSO, store at -20oC, dilute
1+4 with HBS prior to use (2mM).
- Z-Leu-CHN2, 2.00mg/ml (10mM) stock solution in DMSO, store at -20oC, dilute 1+49
with BS prior to use (0.2mM).
6.5.9.3 PROTEASE ACTIVITY ASSAYS
250ul cell suspension 1x106-1x107 cells/ml
+5ul substrate 0.2mM in DMF
- incubate 15-30min at 22oC or 37oC
+5ul PI 2mg/ml in HBS
- incubate 5min at 22oC
- measure (R110 substrate 4uM, PI 40ug/ml (60uM))
6.5.9.4 PROTEASE INHIBITION ASSAYS:
cathepsin B,H,L inhibitory assay (cystein proteinases):
250ul cell suspension 1x106-1x107 cells/ml
+5ul Z-Phe-Ala-CHN2 2mM in HBS
- incubate 15min at 22oC or 37oC
+5ul substrate 0.2mM in DMF
- incubate 15-30min at 22oC or 37oC
+5ul PI 2mg/ml in HBS
- incubate 5min at 22oC
- measure (R110 substrate 4uM, Z-Phe-Ala-CHN2 40uM, PI 40ug/ml (60uM))
cathepsin G inhibitory assay (serine proteinases):
250ul cell suspension 1x106-1x107 cells/ml
+5ul DFP 50mM in HBS
- incubate 15min at 22oC or 37oC
+5ul substrate 0.2mM in DMF
- incubate 15-30min at 22oC or 37oC
+5ul PI 2mg/ml in HBS
- incubate 5min at 22oC
- measure (R110 substrate 4uM, DFP 1mM, PI 40ug/ml (60uM))
aminopeptidase inhibitory assay (metallo proteinases):
250ul cell suspension
+5ul Leu-CMK (chloromethylketone) inhibitor 0.2mM in HBS
- incubate 15min at 20oC or 37oC
+5ul substrate 0.2mM
- incubate 15min at 20oC or 37oC
+5ul PI 2mg/ml in DMF
- incubate 5min at 22oC
- measure (R110 substrate 4uM, CMK 40mM, PI 40ug/ml (60uM))
R110: reaction product control assay (control, only once to setup flow cytometer):
- prepare R110 stock solution 7.33mg/ml (20mM) in HBS
- predilute 1/100 with HBS (R110 0.2mM)
250ul cells suspension 1x106-1x107 cells/ml
+5ul R110 0.2mM (73.3ug/ml) in HBS
- incubate 15-30min at 22oC or 37oC
+1000ul HBS, centrifuge 30 seconds, 1000 x g
+250ul HBS to resuspend sediment
+5ul PI 2 mg/ml in HBS
- incubate 5 min at 22oC
- measure (R110 1.46ug/ml (4uM), PI 40ug/ml (60uM))
6.5.9.5 R110 PROTEASE SUBSTRATE STORAGE:
R110 protease substrate storage and aliquotation:
- take 250ul 4mM substrate solution in DMF which is good for the staining of 1000
cell samples
- aliquot 50ul portions into five Eppendorf cap or screw top
plastic vials
- store four aliquots at -85oC
aliquots:
- take the remaining 50ul aliquot:
50ul substrate 4mM
950ul DMF
1000ul substrate solution 0.2mM for staining of 200 samples
- aliquot this 0.2mM substrate solution in 50ul portions into Eppendorf cap or screw top
vials and store at -85oC
- thaw for measurements one 0.2mM aliquot which is good for the staining of 10 cell
samples. Left over substrate solution may be refrozen or stored at 4oC in the dark in a
refrigerator.
6.5.10 Esterase activity:
FDA: esterase substrate fluorescein diacetate MW: 416 D
- predilute: FDA stock solution 4.16mg/ml (10mM) in DMF daily 1/100 with 2mg/ml PI in
HBS (FDA 1/100 41.6ug/ml 100uM)
assay:
250ul cell suspension
+5ul FDA 41.6ug/ml, PI 2mg/ml in HBS
- incubate 15 min 22oC
- measure (FDA 0.83ug/ml (2uM), PI 40ug/ml (60uM))
6.5.11 DNA/RNA:
AO: vital DNA/RNA acridine orange MW: 301.83 D
assay:
250ul cell suspension
+5ul AO 0.4mg/ml, PI 2mg/ml in DMF
- incubate 15 min 0oC or 22oC
- measure (AO 8ug/ml (26uM), PI 40ug/ml (60uM))
7.CELL PREPARATION AND FIXATION
7.1 Tissue Cells
Cells from tissues may be obtained mechanically or enzymatically.
Enzytmatic treatment requires enzymatic action and usually 37oC
incubation which may modify or remove cell surface antigens as
well as alter the metabolic status of viable cells.
Tissues are removed from the body, suspensed and short term stored in buffered saline or tissue culture solution at 0-4oC on ice. Small tissue pieces (50-100mg) are cut with a blade knife (no scissors because of tissue compression) and chopped with a multiblade tissue chopper (e.g. McIlwain) in two steps with 90o rotated sample stage.
The chopped tissue is resuspended in 2-4ml physiological solution in a 50ml Falcon tube with conical bottom, mechanically treated by 20-30 time sucking back and forth with plastic tip pipette (e.g. Eppendorf) whose tip has been cut to provide an opening of 1.5-2.5mm. Bubble formation is carefully avoided. Cells are washed twice by centrifugation at 200xg for 10min with 50ml physiological solution. Cells are carefully resuspended at each centrifugation step in 3-5ml physiological solution by sucking the sediment several times back and forth without bubbles with the plastic tip pipette before filling up to 50ml. Following the last centrifugation, the resuspended cells are ready for viable cell assays or fixation. All working steps and centrifugations are done at 0-4oC to maintain the metabolic state of the cells as good as possible.
7.2 Leukocytes and Bone Marrow
7.2.1 Erythrocyte Lysis
Blood or bone marrow cell samples for flow cytometric
immunophenotyping are obtained by erythrocyte lysis following
suspension of cells in 0.9% ammonium chloride (NH4Cl) solution
pH 7.35. Since substantial acidification followed by alkalinization
occurs in unlyzed leukocytes, the lyzing solutions for
immunophenotyping are *unsuitable* for flow cytometric cell
function studies.
7.2.2 Cell Sedimentation
7.2.2.1 Histopaque 1g Sedimentation
3ml of a Histopaque 1.077g/ml solution (e.g. Sigma 1077-1)
are filled into a 10ml polycarbonate or glass tube. 3 ml
heparin anticoagulated blood (10-20 IU/ml) are layered
directly from the syringe by running the blood via the
wall of the about 30o inclined tube onto the Histopaque.
Bone marrow samples are filled into a separate test tube
and sucked back and forth without bubbles using a
plastic tip pipette as described under
7.1
Heparin is preferred to EDTA or citrate to maintain
normal Ca2+ level in the blood plasma. This is essential
for proper cell function.
Erythrocytes aggregate heavily at the blood/dextran interface and quickly sediment into the Histopaque while non aggregating and slower sedimenting leuko- and thrombocytes remain in their natural environment. After about 30-45min at room temperature most erythrocytes have sedimented while the upper 2ml of the suspension containg leuko- and thrombocytes are carefully removed with a 1ml plastic tip pipette and stored at 0-4oC on ice until staining. Cell are >90% leuko- and thrombocytes.
7.2.2.2 1g Sedimentation
Instead of Histopaque underlayering, 10ml heparinized blood
can also be allowed to sediment for 1 or 2h at room temperature
in a narrow i.e. 1-1.5cm diameter polycarbonate or glass test tube.
The upper 1ml is carefully removed with a 1ml plastic tip pipette.
The advantage is that no centrifugation is required. More blood
and a longer sedimentation time are, however, required. The leukocyte
enrichment factor is also substantially lower than in
7.2.2.1 as well as in
7.2.2.3.
7.2.2.3 Centrifugation
Heparinized blood is centrifuged for 5min at 150-200g.
The buffy coat, barely layered on top of the still
loose erythrocyte column is carefully removed. This
procedure provides about 10-50 fold leukocyte enriched
erythrocyte suspensions in plasma. This is a good
environment e.g. for phagocytosis assays because
leuko- and thrombocyte aggregation in the presence
of bacteria is largely inhibited.
7.2.2.4 Bacteria Phagocytosis
50ul leukocyte preparation (buffy coat after 200g centrifugation)
in 1.5ml Eppendorf cups
+5ul vital E-coli K12 strain (Sigma) bacteria suspension (3x10**9/ml)
photometric extinction 0.100 at 350nm for 3x10**7 bacteria/ml in HBS-buffer
- keep 10ul of the assay at 0oC and dilute with 1ml cold HBS-buffer
- incubate the remaining 40 ul in water bath at 37oC, mix gently every 15min
- control assays are 50ul leukocyte preparation with 5ul HBS-buffer, incubated
and treated as the assays with bacteria.
- remove 10ul aliquots at 30 and 90min and dilute with 1ml cold HBS-buffer,
store all samples at 0-4oC on ice.
- stain 250ul diluted samples (ca 1x10**7 cells/ml) with any of the
above functional stains in the presence of PI.
7.3 Cell Fixation
Cell fixation preserves cells for longer storage periods.
It is important for flow cytometry to fix in suspension,
in physiological solutions without protein and at
0-4oC to maintain the cells as close as possible to their
actual metabolic state.
7.3.1 Aldehydes
Aldehydes fix by denaturation and chemical modification of
proteins i.e. by covalent reaction with free amino groups
of e.g. lysine residues. The fixation frequently alters
peptide chain antigens of intracellular proteins while
the glyco-antigens of the cell membrane glycocalix remain
largely unaffected. Cell become rigid because protein
cross linking occurs i.e. they suspend well.
The cell membranes of intact cells remain relatively
unpenetrable to larger molecules e.g. antibodies.
Electrical cell volume sizing remains largely unaffected
but DNA stainability is substantially reduced. This may be
overcome by longer staining times.
Formaldehyde or paraformaldehyde are mostly used in flow cytometry to avoid the UV or 488nm induced cellular autofluorescence in the blue and green induced by the well cross-linking glutaraldehyde.
a. Freshly prepared (weekly) 3.5% formaldehyde solution:
1 part 35% formaldehyde (formalin) solution (Merck 4003, MW:30.03)
9 parts HBS-buffer pH 7.35
+ ... ml 0.1N NaOH (MW: 40.0) until pH 7.35 remains stable
discard when pH <7.0
b. Fixation:
1 part protein free cell suspension (5x10**6 - 5x10**7 cells/ml) in HBS-buffer pH 7.35
+1 part fixation solution (3.5% formaldehyde)
- mix rapidly by shaking of inject fixative quickly into
homogeneous cell suspension e.g. by 5ml plastic tip pipette
- fix for at least 1h
- keep fixed cells at 0-4oC in the dark in the fixative
- wash cells twice in 50ml HBS-buffer prior to use e.g. for antibody
incubation for removal of fixative.
7.3.2 Organic solvents
Methanol, ethanol, acetone denature protein mainly by
removal of bound H2O molecules but without covalent
modifications of protein structure. Organic fixative remove
furthermore membrane and structural lipids to some extent
i.e. the cells become permeable e.g. to antibody molecules.
Due to shrinking by water removal and permeabilization, the
electrical volume sizing signals as well as light scatter
signals are substantially modified as compared to viable
cells. Intracellular as well as cell membrane antigens are usually
well preserved in organic fixatives and DNA staining is quick
and with comparatively good CV's.
Problems arise from cell clumping by ethanol or acetone during or after fixation. Methanol at 0-4oC is a well performing fixative for blood, bone marrow, smear or mechanically obtained tissue cell suspensions.
a. Smear and tissue cells:
3ml protein free cell suspension (5x10**6 - 5x10**7 cells/ml)
+ 7ml (Merck Nr.6009 p.a)
- mix rapidly or inject 0-4oC methanol
- fix for at least 1h at 0-4oC
- centrifuge 10min at 200g, remove supernatant e.g. with Pasteur pipette until 1.5-2ml
- resuspend samples with plastic tip pipette
- store samples at 0-4oC in the cold in 3ml glass vials with screw cap
- wash cells twice with 50ml HBS-buffer prior to use e.g. antibody incubation
b.Strongly erythrocyte containing cell suspension:
1 part protein free cell suspension as under a.
+1 part methanol
- mix rapidly or inject methanol
- wait ca 5min at 0oC to lyse erythrocytes
- centrifuge for 5-10min at 200g to sediment unlysed cells
- remove supernatant immediately by suction
- resuspend sediment with 2ml 70% methanol (7 parts methanol,
3 parts HBS-buffer ph 7.35) by plastic tip pipette
- store samples at 0-4oC in the cold in 3ml glass vials with screw cap
- wash cells twice with 50ml HBS-buffer prior to use e.g. antibody incubation
8. SELECTED LITERATURE REFERENCES
8.1 Flow Cytometric Methods:
1. Valet G., A.Raffael, L.Moroder, E.Wünsch, G.Ruhenstroth-Bauer:
Fast intracellular pH determination in single cells by flow- cytometry.
Naturwissenschaften 68,265-266(1981)
2. Valet G., Raffael A.:
Determination of intracellular pH and esterase activity in vital cells by flow-cytometry.
Paesel, Frankfurt, 1984
3. Valet G.:
A new method for fast blood cell counting and partial differentiation by flow-cytometry
Blut 49,83-90, (1984)
4. Valet G., A.Raffael:
Determination of intracellular calcium in vital cells by flow- cytometry.
Naturwiss. 72,600-602,(1985)
5. Treumer J., G.Valet:
Flow-cytometric determination of glutathione alterations in vital cells by o-
phthaldialdehyde (OPT) staining.
Exp.Cell.Res. 163,518-524,(1986)
6. Burow S., G. Valet:
Flow-cytometric characterization of stimulation, free radical formation, peroxidase
activity and phagocytosis of human granulocytes with 2,7-dichlorofluorescin (DCF).
Eur.J.Cell Biology 43,128-133,(1987)
7. Rothe G., G.Valet:
Phagocytosis, intracellular pH, and cell volume in the multifunctional analysis of
granulocytes by flow-cytometry. Cytometry 9,316-324,(1988)
8. Rothe G., A.Oser, G.Valet:
Dihydrorhodamine123: a new flow cytometric indicator for respiratory burst activity in
neutrophil granulocytes.
Naturwiss.75,354-355,(1988)
9. Rothe G., G.Valet:
Flow cytometric analysis of respiratory burst activity in phagocytes with hydroethidine
and 2'7'-dichlorofluorescin.
J.Leuk.Biol. 47,440-448,(1990)
10. Rothe G., A.Emmendörfer, A.Oser, J.Roesler, G.Valet:
Flow cytometric measurement of the respiratory burst activity of phagocytes using
dihydrorhodamine 123.
J.Immunol.Methods 138,133-135,(1991)
11. Banati R.B., G.Rothe, G.Valet, G.W.Kreutzberg:
Respiratory burst in brain macrophages: A flow cytometric study on cultured rat
macrophages.
Neuropath.Appl.Neurobiol. 17,223-230,(1991)
12. Rothe G., S.Klingel, I.Assfalg-Machleidt, W.Machleidt, Ch.Zirkelbach, R.Banati,
W.F.Mangel, G.Valet:
Flow cytometric analysis of protease activities in vital cells. Biol.Chem.Hoppe Seyler
373,547-554,(1992)
13. Assfalg-Machleidt I., G.Rothe, S.Klingel, R.Banati, W.F.Mangel, G.Valet,
W.Machleidt:
Membrane permeable fluorogenic rhodamine substrates for selective determination of
cathepsin L. Biol.Chem.Hoppe Seyler 373,433-440,(1992)
14. Rothe G., G.Valet:
Measurement of phagosomal hydrogen peroxide production with dihydrorhodamin123
in: Handbook of Flow Cytometric Methods, Ed: J.P.Robinson, Z.Darzynkiewicz, Ph.Dean,
L.Dressler, H.Tanke, L.Wheeless, Wiley-Liss Inc., New York 1993, p.155-156
15. Rothe G., G.Valet:
Simultaneous measurement of NADPH oxidase activity and phagosomal oxidation with
hydroethidine and 2'7'-dichlororfluorescin diacetate,
in: Handbook of Flow Cytometric Methods, Ed: J.P.Robinson, Z.Darzynkiewicz, Ph.Dean,
L.Dressler, H.Tanke, L.Wheeless, Wiley-Liss Inc., New York 1993, p.157-158
16. Rothe G., G.Valet:
Measurement of NADPH oxidase activity with hydroethidine,
in: Handbook of Flow Cytometric Methods, Ed: J.P.Robinson, Z.Darzynkiewicz, Ph.Dean,
L.Dressler, H.Tanke, L.Wheeless, Wiley-Liss Inc., New York 1993, p.159-160
17. Rothe G., G.Valet:
Measurement of neutrophil elastase activity with (N-benzyloxycarbonyl-Ala-Ala)2-rho-
damine110,
in: Handbook of Flow Cytometric Methods, Ed: J.P.Robinson, Z.Darzynkiewicz, Ph.Dean,
L.Dressler, H.Tanke, L.Wheeless, Wiley-Liss Inc., New York 1993, p.200-201
18. Rothe G., G.Valet:
Measurement of mononuclear phagocytic cathepsin B/L activity with (N-
benzyloxycarbonyl-Arg-Arg)2-rhodamine110,
in: Handbook of Flow Cytometric Methods, Ed: J.P.Robinson, Z.Darzynkiewicz, Ph.Dean,
L.Dressler, H.Tanke, L.Wheeless, Wiley-Liss Inc., New York 1993, p.202-203
19. Banati R.B., G.Rothe, G.Valet, G.W.Kreutzberg:
Detection of lysosomal cysteine proteinases in microglia: Flow cytometric measurement
and histochemical localization of cathepsin B and L.
Glia 7,183-191,(1993)
20. Klingel S., G.Rothe, W.Kellermann, G.Valet:
Flow cytometric determination of cysteine and serine proteinase activities in living cells
with rhodamine110 substrates.
Methods Cell Biology 41,449-459,(1994)
21. Klingel S., S.Ganesh, H.Kahle, G.Valet:
Fluorogenic rhodamine110 substrates for the flow cytometric determination of
aminopeptidase and cathepsin D activities in living cells.
J.Anal.Cell.Pathology 6,257,(1994)
22. Klingel S., S.Ganesh, H.Kahle, G.Valet:
Flow cytometric aminopeptidase and cathepsin D determination in living cells by
fluorogenic rhodamine substrates.
Cytometry Suppl.7, p.77,(1994)
23. Elsherif T., H.Kahle, S.Klingel, S.Ganesh, G.Valet:
Early functional changes in human T-cells induced to apoptosis by X-irradiation or
cortisone.
Cytometry Suppl.7,p.25,(1994)
24. Ganesh S., S.Klingel, H.Kahle, G.Valet:
Flow cytometric determination of aminopeptidase activities in viable cells using
fluorogenic rhodamine110 substrates.
Cytometry 20,334-340(1995)
8.2 Cytostatic Drug Assays:
1. Valet G., Warnecke H.H., Kahle H.:
Cytostatic drug testing by flow-cytometry.
Paesel, Frankfurt, 1984
2. Valet G., H.H.Warnecke, H.Kahle:
New possibilities of cytostatic drug testing on patient tumor cells by flow cytometry.
Blut 49,37-43, (1984)
3. Neubauer A., R.Sauer, G. Valet:
Cytostatic drug testing in human leukemias by multiparameter flow-cytometry.
Blut 55,433-445,(1987)
4. Neubauer A., G.Valet, D.Huhn:
Flow-cytometric determination of intracellular pH, esterase activity and cell volume in
human leukemic cell lines following in-vitro incubation with cytostatic drugs.
J.Anal.Cell.Pathology 2,49-58,(1989)
5. Hasman M., G.Valet, H.Tapiero, K.Trevorrow, T.Lampidis:
Membrane potential differences between adriamycin sensitive and resistant cells as
measured by flow cytometry
Biochem.Pharmacol. 38,305-312,(1989)
6. Lampidis Th.J., C.Castello, A.Giglio, B.C.Pressman, P.Viallet, K.W.Trevorrow,
G.K.Valet, H.Tapiero, N.Savaraj:
Relevance of the chemical charge of rhodamine dyes to multiple drug resistance.
Biochem.Pharmacol. 38,4267-4271,(1989)
7. Lampidis Th.J., N.Savaraj, G.K.Valet, K.Tevorrow, A.Fourcade, H.Tapiero:
Relationship of chemical charge of anticancer agents to increased accumulation and
cytotoxicity in cardiac and tumor cells: relevance to multidrug resistance.
J.Cellular Pharmacology 1,16-22,(1989)
8. Wulf G., H.Falk, U.Weiershausen, G.Valet:
Antimetabolic and cytostatic potential of 4-amino-N-(2'-aminophenyl)-benzamide
(Dinaline) on adriamycin-sensitive (FL) and resistant (ARN) Friend leukemia cells.
J.Cell.Pharmacol 1,109-118,(1990)
8.3 Data Analysis:
1. Valet G., M.G.Ormerod, H.H.Warnecke, G.Benker,
G.Ruhenstroth-Bauer:
Sensitive three-parameter flow-cytometric detection of abnormal cells in
human cervical cancers: A pilot study. J.Canc.Res.Clin.Oncol. 102:177-184,(1981)
2. Valet G., L.Rüssmann, R.Wirsching:
Automated flow-cytometric identification of colo-rectal tumor cells by
simultaneouus DNA, CEA-antibody and cell volume measurements.
J.Clin.Chem.Clin.Biochem. 22,935-942, (1984)
3. Valet G., H.H.Warnecke, H.Kahle:
Automated diagnosis of malignant and other abnormal cells by
flow-cytometry using the DIAGNOS1 program system.
In: Clinical Cytometry and Histometry, Eds: G.Burger, J.Ploem,
K.Goerttler, Academic press, London 1987, p.58-65
4. Valet G., M.Valet, D.Tschöpe, H.Gabriel, G.Rothe,
W.Kellermann, H.Kahle: White cell and thrombocyte disorders:
Standardized, self-learning flow cytometric list mode data classification
with the CLASSIF1 program system. Ann.NY Acad.Sci.677,233-251,(1993)
5. Höffkes H.G., G.Schmidtke, U.Schmücker, G.Brittinger,
G.Valet: Computerized analysis of cells from patients with acute
myelogeneous leukemia prepared by density gradient centrifugation or
erythrocyte lysis and measured by flow cytometry.
Lab.Hematol.1:128-134,(1995)
6. Valet G., G.Roth, W.Kellermann:
Risk assessment for intensive care patients by automated classification
of flow cytometric oxidative burst, serine and cysteine proteinase
activity measurements using CLASSIF1 triple matrix analysis.
Methods Cell Biol. 1997 in press
7. Valet G., H.G.Höffkes:
Automated classification of patients with chronic lymphatic leukemia
and immunocytoma from flwo cytometric three colour immunophenotypes.
Comm.Clin.Cytometry 1997 in press
8.4 Clinical Applications:
1. Rothe G., W.Kellermann, G.Valet:
Flow cytometric analysis of phagocytosis, respiratory burst, intracellular pH and
cytosolic free calcium of granulocytes of posttraumatic and septic patients.
in: Immune Consequences of Trauma, Shock and Sepsis, eds: E. Faist, J.Ninnemann,
D.Green, Springer Verlag, Berlin 1989, p.235- 240
2. Rothe G., W.Kellermann, G.Valet:
Flow cytometric parameters of neutrophil function as early indicators of sepsis- or
trauma-related pulmonary or cardiovascular organ failure.
J.Lab.Clin.Invest. 115,52-61,(1990)
3. Liewald F., N.Demmel, R.Wirsching, H.Kahle, G.Valet:
Intracellular pH, esterase activity and DNA measurements of human lung carcinomas by
flow-cytometry
Cytometry 11,341-348,(1990)
4. Liewald F., L.Sunder-Plassmann, H.Dienemann, H.Kahle, G.Wulf, G.Valet:
Prognostic value of flow cytometrically determined DNA-ploidy, intracellular pH and
esterase activity of non-small cell lung carcinoma.
Anal.Cell.Pathology 4,103-114,(1992)
5. Liewald F., R.Hatz, M.Storck, K.H.Orend, M.Weiss, G.Wulf, G.Valet, L.Sunder-Plasmann:
Prognostic value of deoxyribonucleic acid aneuploidy in primary non small-cell lung
carcinomas and their metastases.
J.Thoracic Cardiovasc.Surgery 105,1476-1482,(1992)
6. Rothe G., W.Kellermann, J.Briegel, B.Schaerer, G.Valet:
Activation of neutrophils by tumor necrosis factor-a during sepsis.
in: Immune Consequences of Trauma, Shock and Sepsis Vol.II, Ed: E. Faist,
J.Ninnemann, D.Green, Springer Verlag, Berlin 1993, p.727-733
7. Tarnok A., J.Hambsch, M.Borte, G.Valet, P.Schneider:
Immunological and serological discrimination of children with and
without post-surgical capillary leak syndrome.
in: The Immune Consequences of Trauma, Shock and Sepsis Vol.III, Ed: E.Faist,
Monduzzi Editore, Bologna 1997, p.845-849
8.5 Marine Plankton:
1. Sieracki M., G.Valet, T.Cucci:
Report on advanced workshop on fluorescent probes for marine flow cytometry: UseUse of
fluorescent probes in the study of phytoplankton physiology and cellular biochemistry.
Signal and Noise 6,1-2,(1993)