DE10113712A1 - Data carrier, to take chemical and especially bio-chemical substances for the identification of reactions, as a gene chip, has CD structure of pits formed by defined points of non-mirrored surfaces to take the substances - Google Patents

Abstract

Data carrier comprising optical data carrier where points (42) are formed with a protective layer (43), is new. The data carrier surface is mirrored, and the protective layer is removed. The chemical/bio-chemical substances are pressed on to the surfaces which are not mirrored. The shaped points project over the data carrier surface (40), or they lie in the surface. The points are arranged in a spiral path on the data carrier.

Description

The invention relates to a method with the chemical sub punch on punctiform points of an optical data carrier can be applied. The chemical substances are said to then used for certain detection reactions can be.

With the previous gene chip technology, the dimensions of the spots on which the biochemical material is applied is due to the accuracy of the application technology certainly. It is not possible to get narrowly delimited spots less than a micron in diameter. It is therefore not yet possible, for example an op table media for a detection reaction, using the existing technology for reading out CDs can be processed. The well-known and proven Technology for reading CDs would, however, apply to the Offer evaluation of detection reactions.

Equally suitable as CD are their further developments, such as CD-ROM, CD-R and DVD as well as magneto-optical and mag netic carrier. In the further description the  The term CD always synonymous with all such carriers and measurements carrier used.

The invention has for its object a possibility to create on an optical disc in one of the Size of the pits of conventional CDs corresponding size che apply mixed substances with which bio have chemical reactions carried out.

The invention proposes a method for solving this problem with the features mentioned in claim 1. far Erbil cations of the invention are the subject of dependent claims, their wording as well as the wording of the summary is made by reference to the content of the description.

Optical data carriers, for example CDs, have a ver mirrored surface on which the one used for reading Laser beam is reflected. In a predetermined track so-called pits are arranged within the level, i.e. ver indentations in a size of about 0.9 to 0.6 microns. In so-called lands lie between the pits, So places where the mirroring is not disturbed. The invention now proposes point in such a track shaped digits the size of pits to adres Sieren. By applying a protective layer to the individual the addressed point-like positions created the rest of the surface of the optical data to mirror the wearer. Then you can not mirrored areas the desired chemical substances be applied, for example with the help of a contact pressure. It is also conceivable to partially mirror before Apply chemical substances in front. The chemical substances are then arranged in such places net that are in the track and that of an optical  Readout device can be read out. It will possible, known technologies for evaluating the reactions consulted.

The punctiform spots can be such spots act towards the surface of the optical data wearer are sublime. These places can be special simply without further measures using contact pressure print with the desired chemical substance.

However, it is also possible and is based on the invention suggested that with the chemical substances too provided punctiform points in the surface of the optical disk. Here's for applying the protective layer uses a stamping process.

In a development of the invention it can be provided that as Protective layer a varnish is used.

In particular, it can be provided that the mirroring preventing varnish is used. It is possible to paint to use that takes the mirroring, but after his Removal then also replaces the mirroring. Especially but it is favorable if a varnish is used that the Mirroring does not take place on which the mirroring layer therefore not liable.

In a further development of the invention it can be provided that after removing the protective layer the punctiform Places to be coated with the left. These are to molecules on the surface, especially on the Polycarbonate surface of conventional optical data tie carrier.  

According to the point locations along one Track arranged, the additional punctiform points for Has tracking an optical scanning. It can these are indentations but also increases.

In a further development of the invention can be provided be that after the chemical reaction signaling ele elements are applied. This can be, for example trade so-called beads.

According to the invention can be provided after the application of the to perform signaling elements after-mirroring.

Further features, details and advantages of the invention he give preferred execution from the following description Forms of the invention, the claims and based on the drawing. Here show:

Figs. 1 to 6, the process steps for producing a measuring beam;

Fig. 7 to 9 process steps for the production of a stem pels;

Fig. 10 to 12 different process steps in a second embodiment;

FIG. 13 is a possibility of preparing a sub master from the master pattern;

Fig. 14 shows a further possibility of producing a submaster;

Fig. 15 in an enlarged scale a first possibility of the formation of the dot-shaped sites;

Fig. 16 shows a second possibility of the formation of the dot-shaped sites;

Fig. 17 shows a third way of forming the punctiform points.

Fig. 1 shows schematically and simplified a cross section through a glass master 1 , which is coated on one side with a photoresist 2 . This forms the output for the creation of a master. Layer 2 of the photoresist is exposed with the aid of a controlled laser, the laser beam exposing point-like locations which are arranged along a spiral line. This forms the original spiral shown schematically in FIG. 2.

A father 3 (see FIG. 3) is produced by nickel deposition, which thus represents a negative of the structure of FIG. 2. A further nickel deposition produces a mother structure 4 from the father 3, see FIG. 4. A son structure 5 is produced from the mother structure 4 by a further deposition process. Any number of son structures 5 can be produced. This son structure 5 is used to manufacture support structures 6 in the form of blank CDs on which all pits are present using injection molding processes. This is shown in Fig. 6 Darge. Any number of supports 6 can also be generated from any number of son structures 5 .

FIG. 7 shows how a glass master coated with negative photoresist is exposed from the glass master 1 shown in FIG. 2. This results in a negative substrate 7 , which is shown in FIG. 7 above the glass master 1 .

With the aid of a laser beam 8 , which is focused with optical devices 9 , the photoresist layer 10 of a further substrate 11 is partially exposed through the negative substrate 7 (see FIG. 8). From this further substrate 11 , which represents a first submaster, a negative for a silicone stamp is produced by depositing nickel stamps or by repeated electroforming. This stamp 12 is shown in FIG. 9. It contains are a subset of ridges 13, the animals at the Kontakt certain subsets of ridges 14 of the measuring beam 6 shown in FIG. 6 is determined. Detector molecules can be applied to certain elevations or pits of the measuring carrier by aligned contact of the stamps 12 with the measuring carriers 6 . By using a large number of stamps, which are produced with the help of many submasters, a wide variety of detector materials can be applied to the different subsets of pits.

A measuring carrier provided with the detector molecules can then be wetted with a sample to be examined, which leads to A wide range of reactions leads. The result can then be read out using a CD device, whereby the assignment between the measurement results and the evaluator software.

FIGS. 10 and 11 show in which a nega tive substrate 15 is produced by coating with a negative photoresist and exposure by the Urmaster through an embodiment. A negative substrate 18, mirror-image spiral, is produced from the negative substrate 15 by exposure. This negative substrate 18 is used in a similar manner to produce a son substrate 16 , see FIG. 12, with the aid of which an inverse CD 17 can be produced by injection molding. The pits protrude from the side of the CD facing away from the laser. Starting from the substrate 18 , another substrate with the original spiral can be produced by exposure to a positive photoresist. This can be further processed according to FIGS. 8 and 9 into masters 18 for silicone stamps, which subsets of the "negative" pits protruding from the CD can address.

In a further embodiment of the method, starting from a negative substrate 7, an etching mask is created by congruent mastering, which addresses defined subsets of lands. Applying a photo-resistive layer to a son and then exposing it through the etching mask with the same covering subsequently permits targeted etching of the son. This creates structures of a defined depth on the son, which after the injection molding on the CD represent elevations that protrude from the land plane from the side facing away from the laser. The height of these structures can differ from the depth of the pits. The increase allows greater tolerances both in the manufacture of the stamp and in the alignment of the CD and stamp.

FIG. 13 shows in more detail an alternative method step to the method shown in FIG. 8. A laser double head 20 contains two permanently connected laser heads. A laser head is used to generate a weak reading beam, represented by the double arrow 21 . This reading beam 21 reads out the negatively oriented CD master 22 . The laser head 20 contains a second strong laser that generates a write beam 23 controlled. This write beam 23 can be switched on and off by the logic of the double head 20 . A connected computer searches for the subset of the master's pits to be copied and controls the read-write logic. The fixed coupling of the two laser heads, in conjunction with a definition of a parallel orientation to the axis of rotation, ensures a spatial 1: 1 structure of the subset structure of the pits. The actual process for manipulating the stamp consists of curing or entry into the master stamp structure 24 , which is held on the underside of a stamp holder 25, for example by negative pressure. At the bottom of the stamp holder 25 existing solvent 26 is cured by exposure to the writing beam 23 . After the subset of pits is completely written, the excess solvent is rinsed out and removed. Tracking is only in the reading direction, since both heads are rigidly connected and the entire head is moved. The focus is adjusted in both arms.

FIG. 14 shows a device which is similar to the device according to FIG. 13. It is used here to create a positive sub-copy of a CD master. Connected by the axis 27 , the CD master 22 and the sub-copy 28 of the CD master that are to be produced rotate synchronously with one another. The side of the copy 28 facing the laser head 20 is coated with a layer 29 of photoresist which can be exposed by the write beam 23 . A connected computer searches for the subgroup of the master CD pits to be copied and controls the read-write logic. Attention is paid to an adapted focus size of the two beams, namely the reading beam 21 and the writing beam 23 . With the same size of the focus of the two beams, this results in a 1: 1 copy of the pits.

Fig. 15 shows once again, on an enlarged scale, a section through an optical data carrier. In contrast to the conventional CDs, the pits 41 are raised above the surface 40 here. A coating 43 is applied to the surface of one of the pits 42, which ensures that this surface remains free of reflection when mirroring. After the protective layer 43 has been removed, a certain chemical substance is then printed on the surface of this pit. Since the surface of the pit 42 is raised, the printing can be done relatively easily.

In the embodiment shown in FIG. 16, the pits 41 are, as usual, formed as depressions. At a point 44 where there is no pit, a lacquer layer 43 is applied, which then, when mirroring from above, ensures that this point remains free of mirroring. Here, then, similar to the embodiment according to FIG. 15, the chemical substance is then printed on. After attaching a signaling element such. B. beads and subsequent mirroring also creates a place where the mirroring is disturbed.

Fig. 17 shows a possibility similar to Fig. 16. In a country where there should actually be a mirroring, a protrusion 45 protruding from the plane 40 is formed, which can then be provided with a lacquer layer in the same way as in the embodiment according to FIG. 15. After removing the lacquer layer, an unmirrored area is produced here, which can be used for printing with the chemical substance.

Claims (12)

1. Method for applying chemical and biochemical substances to precisely defined, punctiform locations on an optical data carrier, with the following method steps:

• 1. 1.1 the punctiform points ( 42 ) are provided with a protective layer ( 43 ),
• 2. 1.2 the surface of the data carrier is mirrored,
• 3. 1.3 the protective layer ( 43 ) is removed,
• 4. 1.4 the chemical substance is printed on the non-mirrored areas.

2. The method of claim 1, wherein the printing is contact printing. 3. The method according to claim 1 or 2, wherein the punctiform points ( 42 ) against the upper surface ( 40 ) are raised. 4. The method according to any one of claims 1 to 3, wherein the punctiform points in the surface ( 40 ) of the data carrier. 5. The method according to any one of the preceding claims, in which a varnish is used as a protective layer.   6. The method according to claim 5, in which as protection layer a varnish to prevent mirroring is used. 7. The method according to any one of the preceding claims, where after removing the protective layer punctiform places with links for the che mix and coated biochemical substances be that on the unmirrored surface be liable. 8. The method according to any one of the preceding claims, where the punctiform points along a track are arranged, which are also punctiform Locations for tracking an optical scan having. 9. The method of claim 8, wherein the track leadership positions as pits or as him hat pits are trained. 10. The method according to any one of the preceding claims, which signal after a biochemical reaction giving elements, especially so-called beads, be applied. 11. The method according to claim 10, in which after the up bring the signaling elements a verver mirroring takes place. 12. The method according to claim 10 or 11, in which before Applying part of the signaling elements mirroring takes place.