DIRECT DETECTION METHOD FOR TICK-BORNE INFECTIONS AND A CELL TECHNOLOGY MEDIUM FOR THE METHOD

Abstract

This invention relates to a method for the direct detection of tick-borne infections, wherein the human/animal body fluid sample, ideally blood sample to be examined is obtained directly on a specified amount of cell technology medium establishing a partially hostile (semi-hostile) environment, the sample and the cell technology medium are mixed, incubated and stored, if required, meanwhile, the cells and pathogens of the subject are in the semi-hostile environment, then corpuscles and pathogens are separated; a small amount of blood cells from the “buffy coat” layer and blood cells located a few cell layers beneath it are supplemented to and mixed with the gained plasma, the sample is concentrated and the test is finally performed to detect pathogens in the plasma and in blood cells.

The claimed matter covers cell technology medium applied and its application interesting methods.

Claims

1. A method for detecting tick-borne infections in human/animal body fluid of a subject, the human/animal body fluid comprising a blood sample, the method comprising: adding the blood sample directly into a specified amount of cell technology medium establishing a partially hostile (semi-hostile) environment due to its low-level antibiotic or preservative content aiming at bacteriostatic effect and lowered sugar content, mixing the blood sample and the cell technology medium, and, if required, incubating and storing the blood sample and the cell technology medium, wherein, cells and pathogens of the subject are in the semi-hostile environment, separating corpuscles and pathogens by centrifuging with a low-speed of 2-4000 g, thus obtaining plasma, blood cells and a separating layer called “buffy coat,” removing the plasma, mixing a small amount of blood cells from said “buffy coat” layer and blood cells located a few cell layers beneath it with the plasma, concentrating the sample, and testing to detect pathogens in the plasma and in blood cells.

2. The method of claim 1, wherein the sample intended to be examined is put directly on the cell technology medium and mixed by carefully turning the cell technology medium and the added sample up and down.

3. The method of claim 1, wherein the volumes of the sample to be examined and the cell technology medium are approximately equal.

4. The method of claim 1, wherein the separation of corpuscles and pathogens is performed with sedimentation, or low-speed centrifuging or, if required, filtration.

5. The method of claim 1, wherein the concentrating step is performed with applying a very high-speed centrifuging, min. with 15 000 g.

6. The method of claim 1, wherein the mixture containing equal proportion of the sample to be examined and the cell technology medium is centrifuged with applying a low-speed of 3000 g thus obtaining plasma, to which a small amount comprising 5-10 microliters of the “buffy coat” layer and from the corpuscles and erythrocytes located a few cell layers beneath it is re-mixed to the plasma and then centrifuged with high-speed centrifuging, with 15 000-20 000 g, then both infections within blood cells (corpuscles) and the bacteria moving freely in the plasma are observed.

7. A cell technology medium for the method of claim 1, wherein the cell technology medium contains: 125-200 mg/l Tetracaine, 1500-2000 mg/l Mannitol, 0.76-0.114 mg/l EGTA [Ethylenebis(oxyethylenenitrilo)tetraacetic acid], an amount of 0.60 mg/l Magnesium chloride, 2000-4000 mg/l Caffeine-sodium benzoate (coffeinum natrii benzoici), 75-105 mg/l Glycerol, an amount of 10 000 mg/l Trisodium citrate, in a given case 1.00 mg/l Hoechst 33342 stain solution, 20-40 ml distilled water, wherein it also contains 2500-2900 mg/l Glucose, 0.8-1.2 ml/g Phenol Red sodium salt stain and the medium is supplemented to 100 ml with RPMI 1640 growth medium.

8. A cell technology medium according to claim 7, wherein it contains both Hoechst 33342 and Phenol Red sodium salt stain for the direct visual method.

9. A procedure according to claim 7, wherein only Phenol Red sodium salt is applied as a stain.

Description

EXAMPLE 1

[0123] The composition of the cell technology medium:

[0124] 1.00 mg/l Hoechst 33342 stain solution, 5 mg/l Phenol Red sodium salt, 200 mg/l Tetracaine, 2000 mg/l Mannitol, 0.76 mg EGTA, 0.61 mg/l Magnesium chloride (containing 6 water crystalline hydrate), 4000 mg/l Caffeine, 10 000 mg/l Trisodium citrate, 2500 mg/l Glucose, 105 mg/l Glycerol (87%) and 30.00 ml distilled water and RPMI 1640 culture medium ad 100.00 ml

EXAMPLE 2

[0125] Basically, the components of example 1 are applied, but an exhaustive list on the components of the culture medium is also provided. Therefore, the composition is the following:

[0126] COMPOSITION OF THE CELL TECHNOLOGY MEDIUM 1. 200 mg/l Arginine, 2. 56.82 mg/l Asparagine (H2O), 3. 20.00 mg/l Aspartic acid, 4. 0.20 mg/l Biotin, 5. 0.005 mg/l Vitamin B12, 6. 59.00 mg/l Cysteine disodium, 7. 0.76 mg/l EGTA, 8. 15.00 mg/l Phenylalanine, 9. 5.00 mg/l Phenol Red, 10. 1.00 mg/l Folic acid, 11. 105 mg/l Glycerol (87%), 12. 2500 mg/l Glucose, 13. 20.00 mg/l Glutamic acid, 14. 300.00 mg/l Glutamine, 15. 1.00 mg/l Glutathione, 16. 10.00 mg/l Glycine, 17. 15.00 mg/l Histidine, 18. 20.00 mg/l Hydroxyproline, 19. 1.00 mg/l Hoechst 33342, 20. 35.00 mg/l Inositol, 21. 50.00 mg/l Isoleucine, 22. 0.25 mg/l Calcium pantothenate, 23. 70.00 mg/l Calcium nitrate [Ca(NO3)2 6×H2O], 24. 400 mg/l Potassium chloride, 25. 4000.00 mg/l Caffeine and sodium benzoate, 26. 3.00 mg/l Choline chloride, 27. 50.00 mg/l Leucine, 28. 40.00 mg/l Lysine, 29. 0.61 mg/l Magnesium chloride (6×H2O) (5 mM), 30. 100 mg/l Magnesium sulphate (7×H2O), 31. 2000.00 mg/l Mannitol, 32. 15.00 mg/l Methionine, 33. 6000.00 mg/l NaCl, 34. 2000.00 mg/l NaHCO.sub.3, 35. 800.00 mg/l Na2HPO4, 36. 1.00 mg/l Nicotinamide, 37. 1.00 mg/l p-Aminobenzoic acid, 38. 20.00 mg/l Proline, 39. 1.00 mg/l Pyridoxine, 40. 0.20 mg/l Riboflavin, 41. 30.00 mg/l Serine, 42. 200.00 mg/l Tetracaine, 43. 1.00 mg/l Thiamine, 44. 25.00 mg/l Tyrosine disodium salt, 45. 20.00 mg/l Threonine, 46. 10 000 mg/l Trisodium citrate, 47. 5.00 mg/l Tryptophan, 48. 20.00 mg/l Valine, 49. distilled water ad 1000.00 ml

[0127] The following is an example for the procedure of the invention:

EXAMPLE 3—PROCEDURE

[0128] Maximum 5 ml human blood (4.00 ml) or other body fluid sample from a specific patient is obtained directly on 4 ml cell technology medium of the invention. The cell technology medium is filled in the test tube/container in advance and the sample is obtained on that. The sample is carefully mixed (turning the tube/container up and down carefully) and then incubated for 120 minutes. Then the sample is stored for up to 2-3 weeks. Dual centrifuging is performed afterwards. Firstly, the sample is centrifuged with 3000 g for 10 minutes. 4450 microliters of supernatant and 50 microlitres from the buffy coat and the critical layer beneath it are mixed. These are then concentrated with the application of centrifuging with 17 000 g on 15-25° C. for 10 minutes and the supernatant is discarded afterwards. The part of the 4 ml sample that is intended to be examined is in this way concentrated into 10 μl, containing the sediment of the whole blood sample, from which approximately 2 μl is examined with dark-field microscope.

EXAMPLE 4—PROCEDURE

[0129] Sampling and sample preparation are the same as in example 3. Nevertheless, after high-speed centrifuging the sediment is resuspended in 50 μl supernatant and tested with PCR. We note that the optional Hoechst stain is not always supplemented to the cell culture medium in the case of PCR test, as it may inhibit the performance of certain PCR kits. Compatibility with kits must be checked in advance.

EXAMPLE 5—PROCEDURE

[0130] Sampling and sample preparation are the same as in example 3. Nevertheless, after high-speed centrifuging the sediment is resuspended in 5-10 μl supernatant and examined with Raman microscopy. The Raman microscope stimulates the concentrated sample with wavelengths characteristic for pathogens and components found in the sample and records the individually modified wavelength of the light. Special methods may be required for the amplification of the signal.

EXAMPLE 6—SAMPLE STORAGE

[0131] The cell technology medium of the invention is suitable to maintain a human or animal sample in a similar condition as it was at the moment of sampling with respect to corpuscles (blood cells), other cells or microbial flora present in the blood or in the corpuscles, so that the testing can be performed within the following 2-3 weeks. The fact that the examination of tumorous cells was also possible, supports this statement. The sample is obtained directly on the medium, in equivalent proportion, reasonably, obtaining 4 ml blood on 4 ml cell technology medium. For any intended examination on the sample, sample preparation must be performed according to the intended examination and the 4+4 ml sample must be handled as a native sample. The applied test can involve any kind of test method and affect any components of the sample including blood cells, pathogens or damaged cells. During certain procedures, in which sample concentration is relevant (e.g. number of blood cells in a unit of volume), it must be taken into consideration that the sample was diluted to double volume with the cell technology medium.