EP1690091A1 - Novel hybrid probes with enhanced luminescence - Google Patents

Abstract

The invention relates to hybrid particle probes, comprising a nanoparticle of gold with a diameter in the range 2 to 30 nm with at least one, preferably 1 to 100 organic probe molecules and at least 10, preferably 10 to 10,000 molecules with luminescent activity, grafted to the surface thereof, by means of gold-sulphur bonds and a method for production thereof.

Description

The present invention relates to the technical field of probes for detection, monitoring and quantification in biological systems. More particularly, the subject of the invention is new hybrid probe particles, the core of which consists of a gold nanoparticle on which are on the one hand probe molecules and on the other hand molecules with luminescent activity, as well as their preparation process. The use of probes associated with a marker, in biological systems for the detection (recognition) or the monitoring of specific substances, called targets, is a common technique in the field of medical diagnosis and research in biology. Such probes are particularly used for flow cytometry, histology, immunological tests or fluorescence microscopy as well for the study of biological materials as of non-biological materials. Common labeling systems are for example radioactive isotopes of iodine, phosphorus and other elements such as the enzyme peroxidase or alkaline phosphatase, the detection of which requires a particular substrate. In most cases, the selective coupling between the marker and the substance to be detected is carried out by a single or an association of functional molecules. The selectivity of the binding is essential in order to unambiguously identify the target substance to be detected. The reactions ensuring the coupling are known and described for example in "Bioconjugate Techniques", GT Hermanson, Académie Press, 1996 or in "Fluorescent and Luminescent Probes for Biological Activity. A Practical Guide to Technology for Quantitative Real-Time Analysis ”, Second Edition, WT Mason, ed., Académie Press, 1999. Fluorescent organic dyes are widely used for labeling. These are fluorescein, Texas Red or Cy5, which are selectively linked to a specific biological or organic substance playing the role of probe. After excitation of the labeled probe by an external source, most often electromagnetic, the presence of the target biological or organic substances linked to the probe is demonstrated by the emission of fluorescence from the latter. Lowering the detection thresholds is a major objective that would lead to the improvement of biochips (analysis and identification of biomolecules) and the development of more efficient probes capable of tracking individual target biomolecules, in order to to study their cellular activity, or capable of highlighting the interactions existing between unicellular beings (bacteria, protozoa ...) and minerals which are manifested by local physicochemical modifications of the environment (variation of pH, force ionic, oxygen concentration). The current limitation to lowering detection thresholds lies in the difficulty of functionalizing a biomolecule or a particular site of a biological substrate, constituting the target to be detected, by more than one fluorescent organic function (most often a molecule) . To lower the detection threshold, it is proposed in the prior art to mark the probe intended to bind with the target to be detected, with intrinsically luminescent particles. In particular, nanoparticles of semiconductor material have given rise to intense research. US Patent 5,990,479, and international patent applications published under the number WO 00/17642 and WO 00/29617 show that fluorescent semiconductor nanocrystals, which belong to the class of elements II-NI or III-N and those, under certain conditions, are compounds of the elements of the 4 ^th main group of the periodic table may be used as a fluorescent marker for biological systems. Due to the phenomenon known as the quantum size effect, the emission wavelength of a fluorescent semiconductor nanocrystal is imposed by its size. Thus, by varying the size of these nanocrystals, a wide range of the spectrum can be covered, from visible light to near infrared. Their use as a biological marker is described by Warren CW Chan, Shuming Nie, Science, 281, 2016-2018, 1998, and by Marcel Bradiez Jr, Mario Moronne, Peter Gin, Shimon Weiss, A. Paul Alivisatos, Science, 281, 2013 -2016, 1998. The preparation of semiconductor nanocrystals with a well-defined emission wavelength, that is to say with a small size dispersion, requires very high precision and requires perfect control of the operating conditions. and the progress of the synthesis. They are, therefore, very difficult to produce. The wide palette of colors offered by these semiconductor crystals results from a variation in size of the order of a few Angstroms (that is to say a few atomic layers). Syntheses in solution rarely achieve such a degree of precision. In addition, the recombination of electron-hole pairs observed at the surface of the nanocrystals limits the quantum yield to a low value. To get around this problem, a core / shell structure has been proposed: this involves individually coating the fluorescent semiconductor nanocrystals with a layer of semiconductor material with a wider gap (ZnS, CdS ). In addition, the selective labeling of biomolecules by fluorescent semiconductor nanocrystals requires the formation of a layer of polysiloxane functionalized with amino groups (epoxy and carboxylic acid). These will constitute anchor points for the biomolecules. The preparation of these nanocrystals therefore requires at least three synthesis steps, the first two of which are very delicate and is therefore difficult to industrialize. Labeling with oxide nanoparticles made luminescent by doping with luminescent ions (rare earth) is not, despite promising results, still very widespread. Its main drawback lies in the low quantum yield which requires the use of a laser to excite the luminescent ions present in the crystal matrix. On the other hand, the luminescence properties are very clearly altered when these particles are used directly in an aqueous medium. Marking with vesicles or polymer beads, or polysiloxanes, filled with luminescent organic compounds is effective for visualization in luminescence, but often requires fairly large particles (several tens of nanometers) and remains difficult to use in certain applications where more great "molecularity" is sought. Different strategies using grafted gold particles have already been developed. None, however, succeeded in satisfactorily increasing the emitted luminescence. Most of the work has been focused on the labeling and detection of oligonucleotides, one of the ends of which has been modified by a thiol function. If the grafting of an oligonucleotide strand constitutes a common step of the different strategies identified in the prior art, the means used for detection are very variable. Indeed, Pileni et al. in J. Phys. Chem B, 107, 27, 6497-6499, 2003 describe the immobilization of nanoparticles functionalized with strands of oligonucleotide fhiolated by hybridization with the complementary strand present on nanometric gold islands deposited on a glass surface. Immobilization (and therefore detection of the oligonucleotide) is demonstrated by a significant increase in the sensitivity of surface plasmon resonance transmission (T-SPR) spectroscopy. The electrochemical detection of oligonucleotides has also been envisaged by Li et al. in Analyst, 128, 917-923, 2003 and Hsing et al. in Langmuir 19, 4338-4343, 2003. The immobilization of gold nanoparticles functionalized by strands of oligonucleotide on biochips (by hybridization) facilitates the germination of silver crystals (by reduction of the salts of silver cations (I )) inducing an increase in the detection current. The optical properties of gold have also been used for marking and detection. Thus, Richards-Kortum et al. in Cancer Research, 63, 1999-2004, 2003, showed that gold nanoparticles could be used for the detection of cancer cells. Indeed, immobilization on the nanoparticles of biomolecules interacting selectively with cancer cells makes it possible to obtain probes whose detection is based on the capacity of the nanoparticles to reflect the incident light emitted by the confocal microscope. Gold nanoparticles can be used as an optical contrast agent thanks to the optical absorption and reflection properties associated with the plasmons of gold. Another approach has been developed by Mirkin et al. in J. Am. Chem. Soc. 125, 1643-1654, 2003 which showed that the hybridization of two complementary strands of oligonucleotide, carried by two distinct gold particles, induced a bringing together of these particles and therefore a displacement of the plasmon band (resulting from collective oscillations electrons from the conduction band). The color change of the colloid (from red to purple) can then be used for the detection of oligonucleotides in solution or on DNA microarrays. Dubertret et al. in Nature Biotechnology, 19, 365-370, 2001, used the fluorescence extinction observed. for certain organic dyes adsorbed on gold to prepare DNA probes. They showed that the hybridization of a strand of oligonucleotide marked by a fluorophore and immobilized on the surface of gold with a free strand made it possible to restore the luminescence of the fluorophore, thanks to the distancing of the latter from the gold surface, generated by hybridization. The emission of light of wavelength characteristic of the organic fluorophore indicates the presence of the free oligonucleotide. This luminescence quenching technique is used to detect the presence of oligonucleotide in solution. The coating of the metallic core with a layer of polysiloxane type was also carried out in WO 99/01 766. However, the process used does not allow the homogeneity of the polysiloxane layer to be controlled, making it more difficult to control the surface of the nanoparticle and therefore control of the number of molecules that can be grafted onto it. All these approaches of the prior art are restrictive, because they can only apply under certain conditions. Electrochemical detection does not make it possible to follow the fate of a biomolecule in vivo. The technique of Mirkin et al. is limited to the detection of nucleic acids. In addition, the displacement of the plasmon band can be caused by other factors (increase in salt concentration, temperature, aging). In this context, one of the problems that the invention proposes to solve is to provide new nanometric-sized biological probes allowing detection, labeling and quantification, in vitro and in vivo, in biological systems, with sensitivity. and reproducibility. Another problem, which the invention proposes to solve, is to provide new easily detectable biological probes, by virtue of their emission of fluorescence or luminescence exacerbated after excitation. The invention also aims to provide new polyfunctional biological probes of controlled size and composition, produced according to a simple process, easily industrializable. To achieve these objectives, the invention proposes new hybrid probe particles comprising a gold nanoparticle with a diameter included in the range from 2 to 30 nm at the surface of which are grafted by gold-sulfur bonds on the one hand, at least one, and preferably from 1 to 100, organic probe molecules and on the other hand, at least 10, and preferably 10 to 10000 organic molecules with luminescent activity. The invention also proposes a new type of probe where the exacerbated luminescence is coupled to a dense nanometric metallic core, thus allowing another investigation system such as transmission electron microscopy and / or based on the properties of reflection, absorption. and / or diffusion associated with the plasmons. The subject of the invention is also various methods for preparing the hybrid probe particles as defined above. The description below, with reference to the appended figures, allows a better understanding of the subject of the invention. Fig. 1 highlights the persistence of luminescence of lissamine rhodamine B derivatives after grafting onto gold nanoparticles. Fig. 2 shows the absorption spectra of a colloidal solution of gadolinium oxide nanoparticles alone or associated with gold nanoparticles. Fig. 3 is a schematic illustration of the principle of the biochip used. Fig. 4 shows the influence of dilution (Laser Argon, λ _exc = 480 nm, P = 600 μW) during immobilization by hybridization on a biochip of gold nanoparticles functionalized by 5 molecules with luminescent activity (thiol derivative of the lissamine rhodamine B) and with an oligonucleotide. Fig. 5 shows the fluorescence observed after immobilization on Sepharose beads by hybridization of gold nanoparticles comprising an oligonucleotide and a variable number of molecules with luminescent activity (thiolated lissamine rhodamine B: rhoda-SH). Fig. 6 represents the quantification of the fluorescence signal observed on the

Fig. 5. Fig. 7 compares the light intensity obtained after labeling of oligonucleotide by a single molecule with luminescent activity (derived from lissamine rhodamine B) and by a gold nanoparticle comprising 100 molecules with luminescent activity (lissamine rhodamine B thiolated). Beforehand, the definitions of certain terms used in the present patent application are given below. The terms “molecule with luminescent activity”, “fluorophore”, “dye”, “fluorescent molecule” will be used indifferently to designate entities which it is possible to detect by virtue of their optical emission activity in the visible and near infrared . By “organic” molecule is meant the conventional definition well known to those skilled in the art, namely a carbonaceous molecule optionally containing one or more elements chosen from: O, N, P, S and halogen. Compounds based on silicon and / or metals are, of course, not part of organic molecules. By probe molecule is meant a compound which has at least one recognition site allowing it to react with a target molecule of biological interest. The term "polynucleotide" means a chain of at least 2 deoxyribonucleotides or ribonucleotides optionally comprising at least one modified nucleotide, for example at least one nucleotide comprising a modified base such as inosine, methyl-5-deoxycytidine, dimethylamino- 5- deoxyuridine, deoxyuridine, diamino-2,6-purine, bromo-5-deoxyuridine or any other modified base allowing hybridization. This polynucleotide can also be modified at the level of the internucleotide bond, at the level of the skeleton. Each of these modifications can be taken in combination. The polynucleotide can be an oligonucleotide, a natural nucleic acid or its fragment such as DNA, a

Ribosomal RNA, a messenger RNA, a transfer RNA, a nucleic acid obtained by an enzymatic amplification technique. By "polypeptide" is meant a chain of at least two amino acids. The term "protein" includes holoproteins and heteroproteins such as nucleoproteins, lipoproteins, phosphoproteins, metalloproteins and both fibrous and globular glycoproteins, enzymes receptors, enzyme / substrate complexes, glycoproteins, antibodies, antigens. The term "antibody" includes polyclonal or monoclonal antibodies, antibodies obtained by genetic recombination, and antibody fragments. The term "antigen" designates a compound capable of being recognized by an antibody whose synthesis it has induced by an immune response. By nanoparticle, we mean a particle of nanometric size. These nanoparticles can be of any shape. Particles of spherical shape are, however, preferred. The core of the hybrid probe particles according to the invention consists of a gold nanopaticule, preferably of average diameter comprised in the range going from 2 to 30 nm, preferably in the range going from 4 to 20 nm and preferentially in the range ranging from 5 to 16 nm. The average size is deduced here by photon correlation spectroscopy (quasi-elastic light scattering, λ = 633 nm) and by analysis of photos taken in transmission electron microscopy (TEM). The use of gold is particularly advantageous for the following reasons: - gold is compatible with living organisms and has a fairly high tolerance threshold, - gold is a metal which is very difficult to oxidize, which makes it possible to obtain nanoparticles with high stability (in particular the conservation of its zero oxidation state and of metallic behavior), - the synthesis of gold nanoparticles is easy, - gold is non-paramagnetic, - gold has an affinity particular for sulfur, which makes it possible to graft thiolated derivatives, the gold-sulfur bond being known to be particularly strong, - gold is visible in TEM imaging, - gold has an absorption in surface plasmon, this which makes it possible to obtain information on the nanoparticle, in particular on its size. These gold nanoparticles are polyfunctionalized by grafting of different thiol derivatives which provide: - the biological recognition given by grafting of at least one, preferably from one to 100 and preferably from 1 to 10, probe organic molecules, - the luminescence in biological medium given by grafting from at least 10, preferably from 10 to 10,000, preferably 10 to 1,000, organic molecules with luminescent activity, advantageously 100 to 500, - the solubility adapted according to the working environment, - redispersion, - non-aggregation. Functionalization is easy, the different grafted molecules being linked in a quasi-covalent manner to the gold nanoparticle by gold-sulfur bonds. In the context of the invention, the various molecules (probe molecules, molecules with luminescent activity, or other organic molecules) are linked, either directly to the nanoparticle by an Au-S bond, or via an organic molecule acting as a spacer, linked to the nanoparticle for an Au-S bond. If, at present, the nature of the Au-S bond remains undetermined, it is nevertheless recognized that the thiolate groups are strongly bound to the surface of gold. According to Dubois, and Nuzzo in Ann. Phys. Chem. 43, 437-, 1992 and Ulman A. in Chemical Reviews 96, 1533-1554, 1996, the binding energy is 40 kcal.mol ^"1 (against 87kcal.mol ^{" 1} for the SH bond) and the energy balance of the adsorption of an alkanethiolate on gold is negative (- Skcal.mol ^"1 , exothermic reaction). The Au-S interaction being established after grafting of thiol derivatives is so strong that the latter cannot be expelled from the surface by successive washes. The use of thiol derivatives therefore appears particularly suitable for immobilizing dye molecules and biomolecules on the surface of gold nanoparticles. A large number of organic molecules with luminescent activity are grafted on the surface. nanoparticles of gold. Advantageously, the number of luminescent activity molecules grafted on the surface of the gold nanoparticle is at least 10 times greater than the number of organic probe molecules grafted. inve ntion, the organic molecules with luminescent activity, also called dyes, are fixed on the gold either directly (in this case the dyes are thiolated) or indirectly by means of a short organic spacer (the spacer being, preferably, a thiolated molecule comprising between 2 and 50 carbon atoms). The dyes are therefore not linked to an oligonucleotide or to a DNA fragment, as described in the international application published under the number WO 03/027678. According to the invention, the dyes are bonded almost covalently on the gold nanoparticle by gold - sulfur bond. By this method, the fluorescence of the dyes is preserved after grafting and is not reduced by the presence of gold which absorbs strongly around 520 nm, which was not the case for the compounds previously chosen and adsorbed directly on the gold. In addition, the luminescent function is ensured by a large number of organic molecules with luminescent activity grafted onto the gold nanoparticle, leading to a strong emission in fluorescence after excitation, which makes it possible to obtain a global final luminescence by widely exalted object. . The hybrid nanoparticles according to the invention then become viewable both by confocal microscopy due to absorption or reflectivity (optical contrast agent) and by electron microscopy (electronic contrast agent). First of all, the target biomolecule is more easily identified because, instead of being marked by a single fluorophore, it is "marked" by several tens of luminescent molecules. A biochip composed of Sepharose beads carrying oligonucleotide (d (A) ₂₂ ), immobilized on the surface of an elastomer (Fig. 3) is used, to demonstrate the amplification obtained through the use of nanoparticles hybrid probes according to the invention carrying lissamine rhodamine B derivatives and oligonucleotides. The strands complementary to those immobilized on the surface of the biochip are marked, either by a single molecule of fluorophore (Lissamine rhodamine B) (Fig. 3A), or by a hybrid nanoparticle according to the invention carrying a multitude (2- 200) of thiolated rhodamine B lissamine molecule (Fig. 3B and Fig. 4). Figs. 5 and 6 clearly show the increase in fluorescence with the number of organic fluorescent molecules (lissamine rhodamine B functionalized by a thiol function). However, beyond 400 fluorescent molecules, the intensity no longer increases and retains the value measured for gold nanoparticles on which are immobilized 400 fluorescent organic molecules. These results were obtained on gold nanoparticles with a diameter of 12 nm. As shown in Fig. 3, following the hybridization reaction between complementary strands, for the same number of labeled strands having reacted with the immobilized strands, that is to say the same number of target molecules in the sample, a higher fluorescence intensity is expected . This is illustrated in FIG. 7 showing the variation in fluorescence intensity obtained as a function of the quantity of strands present in the sample, marked either with a lissamine rhodamine B molecule, or with a hybrid probe particle according to the invention. In this specific case, several strands may be present on the surface of the nanoparticle, but it is recognized that only one of these strands will have the possibility of reacting with an immobilized strand. The curve shown in Fig. 7, takes these parameters into account and assumes that a hundred strands are present on the surface of the nanoparticle, only one reacting with the strand immobilized. As can be observed, an increase in the signal by a factor of ten can be obtained between the molecules marked by a fluorophore (white square) and those marked by a probe hybrid particle according to the invention carrying a hundred fluorophores (black square ). Despite the partial absorption of the light signal emitted by the organic dye due to the gold colloid, an increase in intensity by a factor of 10 is observed. According to a first advantageous variant of the invention, the grafted dyes emit at a wavelength situated outside the maximum absorption of the plasmon of gold (at 540 nm). Advantageously, the luminescent activity molecules are fluorescent organic dyes whose maximum emission differs by at least 25 nm from the maximum absorption of the plasmon of gold. Electroluminescent or chemiluminescent compounds, for example derivatives of luminol may be used. Luminescent compounds, called two-photon or anti-stoke emission compounds, the wavelength of the emitted light is greater than the excitation wavelength, preferably at least 200 nm can also be grafted. Lanthanide complexes, rhodamine derivatives and more particularly those of lissamine rhodamine B are particularly preferred dyes. As shown in Fig. 1, the grafting of lissamine rhodamine B and its derivatives onto gold nanoparticles only causes a reduction by a factor of 3 in the luminescence intensity obtained, compared with the same amount of free dyes (individualized molecules) . By increasing the number of lissamine rhodamine B molecules grafted, the luminescence per biological molecule to be detected is further increased. According to another advantageous alternative embodiment of the invention, the non-radiative transfers between the organic dyes and the gold are limited, so as to obtain nanoparticles with reduced luminescence quenching. For this, it is possible, for example, to cover at most 75% of the gold nanoparticle with a covering material having dielectric characteristics allowing the shift of the plasmon band of gold outside the zone of emission of the luminescent molecules. This covering material is, for example, chosen from polysiloxanes, SiO ₂ , ZrO ₂ , Ln ₂ O ₃ and lanthanide oxohydroxides. The coverage must be partial, so as to leave on the gold nanoparticle a sufficiently large free surface for the grafting of luminescent and biological molecules. In fact, the grafting of the probe organic molecules and of the luminescent molecules is done directly on the gold particle and not on the covering material. Fig. 2 shows, by way of illustration, how grafting with a gadolinium oxide makes it possible to eliminate the absorption of surface plasmon in the visible range. Another way to obtain nanoparticles with reduced luminescence quenching is to graft luminescent activity molecules via a thiol organic spacer. The use of organic dyes previously grafted onto “rigid spacers” (organic thiol molecules comprising, for example, a benzene ring) makes it possible to maintain the luminescent center at an average distance from the surface greater than 0.5 nm. These spacers preferably contain at least 6 carbons and less than 50, and are for example chosen from mercaptophenols, dihydrolipoic acid and thio-poly (ethylene glycol). Furthermore, the hybrid probe nanoparticles according to the invention are relatively photostable. The probes according to the invention are perfectly suited to a wide variety of biological targeting, the specifics being dependent on the nature of the probe molecules grafted to the surface of the gold nanoparticle. The biological probe molecules are advantageously chosen from polynucleotides of the DNA, RNA or oligonucleotide type, proteins of the antibody, receptor, enzyme, enzyme / substrate complex type, glycoproteins, polypeptides, glycolipids, oses, polysaccharides and vitamins. Oligonucleotides thiolated or linked to a thiolated spacer are particularly preferred. The probe organic molecules can also be any type of molecule allowing the biotin-streptavidin interaction. It is also possible to graft onto the gold nanoparticle other thiol organic molecules, distinct from the probe organic molecules and molecules with luminescent activity. These thiolated organic molecules preferably comprise at least one alcohol, amino, sulfonate, carboxylic acid or phosphate function. We can choose to graft 1 to 1000, preferably 10 to 1000, of these other organic molecules. The functions provided by these other molecules are, for example, better stability, solubility adapted as a function of the working environment, easy redispersion, non-aggregation, better selectivity. The invention therefore cleverly combines gold nanoparticles, biological probe molecules and molecules with luminescent activity, so that the luminescence is not "destroyed" by the absorption of gold, but on the contrary increased overall compared to an isolated molecule (effect of many of the grafted compounds) and that the probe molecules retain their effectiveness vis-à-vis biological targets. The hybrid gold nanoparticles according to the invention are easily synthesized by the Frens method (citrate route) of which there are many variants (citrate / tarmic acid) or by that of Brust called the NaBH ₄ route. For the citrate route, one can for example refer to Nature Physical Science 241, 20-22, 1973. In this case, the reduction of hydrogen tetrachloroaurate by citrate in the aqueous phase provides gold nanoparticles coated with citrate. The latter plays a dual role: it allows the growth of nanoparticles to be controlled and prevents the formation of aggregates. The citrate / tarmic acid combination provides also nanoparticles coated with citrate whose dimensions are smaller. The grafting of thiol molecules onto the gold nanoparticles proceeds by gradual replacement of the citrate molecules by addition per portion of the solution of thiol molecules. This step is delicate because an excessively brutal replacement induces the precipitation of the nanoparticles. The immobilization of different thiol molecules takes place in as many stages (one stage = complete addition of a solution of thiol species) as there are different molecules. For the NaBH route, reference may in particular be made to J. Chem. Soc, Chem. Commun., 1655-1656, 1995. The NaBH route consists essentially of reacting, in an aqueous medium and in the presence of sodium borohydride, hydrogen tetrachloroaurate with the thiol derivatives which it is desired to graft. The grafted thiol derivatives are prepared according to methods well known to those skilled in the art. By thiol derivatives is meant an organic molecule comprising at least one thiol-SH function. These thiol functions can be obtained from dialkyl sulfides or dialkyl disulfides. These different routes are well known to those skilled in the art, who will be able to provide numerous variants. Without limitation, a description of various advantageous variants of the process is given below. According to a first variant, the process for preparing hybrid probe particles according to the invention comprises the following steps: - preparing a colloidal suspension of gold nanoparticles with a diameter in the range from 2 to 30 nm, by reduction of a gold salt, and in particular hydrogen tetrachloroaurate, in aqueous or alcoholic phase and in the presence of citrate, - add, to the colloidal suspension obtained, an aqueous or alcoholic solution of organic molecules thiol probes grafted on the surface gold nanoparticles by gold-sulfur bond to replace citrate molecules, - add, to the colloidal suspension obtained, an aqueous or alcoholic solution of luminescent activity molecules grafted onto the surface of gold nanoparticles by gold bond -sulfur to replace citrate molecules. In the case of the citrate and citrate / tarmic acid routes, the preparation of the hybrid probe particles comprises at least three stages. Advantageously, the first consists in preparing in the aqueous phase gold particles of nanometric size generally comprised between 10 and 20 nm according to the citrate route and between 6 and 15 nm according to the citrate / tarmic acid route, and this, advantageously, by reduction of HAuCl. 3H ₂ O by citrate (citrate route) in an Au / Citrate ratio between 0.170 and 0.255 and by the citrate / tarmic acid couple (citrate / tarmic acid) in citrate and acid ratios tannic / citrate between 0.170 and 0.255 and between 0.030 and 10, respectively. The gold nanoparticles are then covered by citrate molecules adsorbed on their surface. Colloids can optionally be purified by dialysis against water. In the case of the citrate and citrate / tarmic acid pathways, the functionalization of the nanoparticles is carried out in several stages. Each step corresponds to the grafting of only one kind of molecules. The grafting takes place by replacing the citrate present on the surface of the nanoparticles and therefore requires a slow addition of the solution containing the molecules to be grafted comprising a thiol function. The quantity of molecules grafted onto the gold nanoparticles is advantageously between 0.1 and 60% of the free sites. The grafting of molecules with biological activity, for example thiol oligonucleotides, folic acid modified by a thiol function or grafted on thiol poly (ethylene glycol) (PEG), is preferably carried out by adding 1 to 500 μl of a aqueous solution with a concentration between 0.1 μM and 40 μM. The quantity of probe molecules grafted onto the surface of the gold nanoparticles is advantageously between 1 and 200 probe molecules per particle. The second step consists in grafting the organic dye carrying one or more thiol functions by adding, preferably, from 3 to 200 μl of an aqueous (or ethanolic) solution of the thiol dye of concentration between 0.1 and 400 μM. The number of grafted thiolated dyes is advantageously between 10 and 400 per particle, for particles with a diameter of 12 nm in particular. It is equally possible to graft the biological probes before or after that of the dyes. Possibly can be successively added before, between or after the two preceding stages and in an indifferent order the solutions of different thiol species such as sodium mercaptoethanesulfonate, succinic acid, PEG terminated by a thiol function. When the functionalization is complete, the hybrid gold nanoparticles are purified by column chromatography (Sephadex ™ G-25 M, eluent: buffer solution of pH between 7 and 9). According to another variant of the citrate or citrate / tarmic acid pathway, the method comprises the following steps: - preparing a colloidal suspension of gold nanoparticles with a diameter in the range from 2 to 30 nm, by reduction of tetrachloroaurate hydrogen, in aqueous or alcoholic phase and in the presence of citrate, add, to the colloidal suspension obtained, an aqueous or alcoholic solution of thiolated spacers functionalized with an ionizable function capable of reacting with probe organic molecules or molecules with luminescent activity at graft, the said spacers coming to be grafted on the surface of the gold nanoparticles by gold-sulfur bond in replacement of citrate molecules, add an aqueous or alcoholic solution of organic molecules probes functionalized to react with the ionizable function carried by the grafted spacers on the surface of the gold nanoparticle, and / or add an aqueous or alcohol solution ic of organic molecules probes functionalized to react with the ionizable function carried by the spacers grafted on the surface of the gold nanoparticle. Instead of directly grafting a thiolated organic molecule with luminescent or biological activity on the surface of a gold nanoparticle, this other variant consists in carrying out the grafting by condensation between two complementary reactive functions present for one in the active molecule to graft (dye, probe ...) and for the other at the end of a thiolated molecule immobilized on the surface of the gold and playing the role of spacer. The grafting of an organic molecule with luminescent or biological activity requires the presence of a thiol function to ensure lasting immobilization on the gold particle. Most of these molecules do not have them. The thiol function can be introduced by organic synthesis before grafting (case of the citrate protocol). Another way of proceeding consists in grafting the active molecule devoid of thiol function on a thiolated spacer present on the surface of the gold nanoparticle. Compared to the previous protocol, the step of grafting active thiol molecules is replaced by two steps. The first consists in immobilizing the thiolated spacer serving as an anchor point (spacer arm) for the molecule with luminescent or biological activity. Advantageously, from 1 to 500 μl of an aqueous solution of the spacer with a concentration of between 0.1 and 400 μM is then added to the colloid of gold nanoparticles. The number of immobilized thiol molecules is advantageously between 0.1% and 50% of free sites. Then, an aqueous solution of the active molecule to be grafted is added slowly. This solution may possibly contain a reagent facilitating coupling. The elimination of secondary products is carried out by dialysis of the colloidal solution against water. The spacer used as grafting site must necessarily include a thiol function (essential for immobilization on gold) and at least one reactive function (-OH, -NH ₂ , -COCl ...) to ensure subsequent grafting of the active molecule. In order to obtain the best results in sunshine, the carbon chain between the thiol function and the reactive function must be rigid and preferably contains from 6 to 50 carbon atoms. The organic molecule with luminescent or biological activity must necessarily include a reactive function (-SO ₂ Cl, -COCl, -OH, -NH ₂ ) capable of reacting with that carried by the spacer arm immobilized on the surface of the gold nanoparticles. We can in particular refer to Chem. Eur. J, 8, 16, 3808-3814, 2002 and Chem. Common. 1913-1914, 2000. Whatever the protocol used (thiolated active molecule or thiolated spacer), the number of luminescent activity molecules immobilized on the surface of the nanoparticles is determined by UN-visible spectroscopy of the solution after precipitation of the nanoparticles. The difference between the number of molecules added to the colloid and the number of molecules present in the supernatant (after filtration of the precipitate) indicates the number of molecules immobilized on the surface of the gold nanoparticles. According to another variant implementing the ΝaBH ₄ path, the method comprises the following steps: - prepare a colloidal suspension of gold nanoparticles of diameter included in the range from 2 to 30 nm, by reduction of gold salt, and in particular of hydrogen tetrachloroaurate, in aqueous or alcoholic phase and in the presence of NaBH , - add, to the colloidal suspension obtained, an aqueous or alcoholic solution of thiolated spacers functionalized with an ionizable function capable of reacting with the probe organic molecules or the molecules with luminescent activity to be grafted, the said spacers being grafted on the surface gold nanoparticles by gold-sulfur bond, - add an aqueous or alcoholic solution of functionalized probe organic molecules to react with the ionizable function carried by the spacers grafted on the surface of the gold nanoparticle, add an aqueous or alcoholic solution of organic molecules probes functionalized to react with the ionizable function carried by the spacers grafted in surface of the gold nanoparticle. In the case of the NaBHi pathway, the thiol molecules present on the surface of the gold nanoparticles were generally introduced during the synthesis. Some can be substituted but with uncertain control of the number of molecules replaced. The immobilization of molecules with biological activity and organic dyes will be carried out in most cases (for better efficiency) by grafting on thiolated spacers present on the surface of gold nanoparticles. The synthesis by the NaBPLt pathway of hybrid nanoparticles for biological labeling also requires several steps. The first consists in preparing in an alcohol, preferably, methanol, ethanol or dimethylformamide, the gold nanoparticles coated with thiol molecules having an ionizable function in a single step by reduction of HAuCl .3H ₂ O by a solution aqueous NaBH

(Au / NaBH included, for example, between 0.05 and 0.5) in the presence of thiol organic molecules having an ionizable function whose Au / S ratio is advantageously between 0.2 and 10. By this method, the coverage of gold nanoparticles is almost total. As the replacement of thiol molecules on the surface of gold nanoparticles is difficult and as the surface is completely covered, the choice of thiol molecules is decisive. These molecules must allow both excellent redispersion of the nanoparticles in an aqueous solution in order to obtain a stable colloid and the grafting of probe molecules and organic dyes. Thiolated spacers also having an ionizable function (-NH ₂ , -COOH) appear suitable for preparing redispersible and stable gold hybrid nanoparticles (under certain pH conditions) in aqueous solution. In addition, these ionizable functions can be used to immobilize probe molecules and organic dyes by simple condensation reactions (formation of ester, amide, urea or thiourea derivatives, etc.). After reduction and therefore formation of the gold nanoparticles, a precipitate appears. A maximum of 2/3 of the solvent (methanol or ethanol) are then evaporated under reduced pressure at a temperature below 40 ° C. The precipitate is filtered through a polymer membrane (with, for example, a pore diameter equal to 0.22 μm) and washed meticulously with different solvents (chosen according to the nature of the thiol immobilized on the surface). This washing aims to eliminate the by-products of the reduction and the large quantity of non-adsorbed thiols. The powder obtained is, after air drying, redispersed in the aqueous phase within a controlled pH range (which depends on the nature of the ionizable group present in the thiolated molecule). The organic dye is then grafted onto the nanoparticle by reaction between a reactive function, of the type -NH ₂ , -COOH, - SO ₂ Cl, -N = C = O, -N = C = S in particular, present on the dye and the ionizable function of the thiolated spacer grafted onto the gold nanoparticles. This reaction is carried out by adding to the colloidal solution an aqueous or aqueous-alcoholic solution of organic dye, the amount of which is at least four times greater than the number of thiol molecules adsorbed on the gold nanoparticles. Between 0.5 and 10% of the ionizable functions of the thiol molecules adsorbed on gold generally react. The excess secondary products are then eliminated by precipitation of the nanoparticles obtained by a strong variation in the pH (ΔpH> 2). The precipitate is filtered through a membrane (pore diameter equal to 0.22 μm for example) and washed meticulously before being redispersed in aqueous solution within a controlled pH range. The probe molecules are grafted onto part of the 85 to 90% of the ionizable functions remaining after the grafting of the organic dye. The coupling is carried out by adding an aqueous solution of probe molecules, the quantity of which is at least greater than the number of thiol molecules adsorbed on the gold nanoparticles. Between 0.1 and 2% of the ionizable functions of thiol molecules grafted onto gold react. In order to avoid denaruration by repeating the steps of separation, washing and redispersion, the grafting of the probe molecules is advantageously carried out after that of the organic dyes. Excess side products are eliminated as before. The characterization of the nanoparticles is carried out in the solid state by XPS,

XANES, ATG and in the liquid state by UN-visible spectroscopy and XAΝES. Another variant of the process consists in immobilizing the probe molecules by exchange of thiolated probe molecules with other thiol molecules already grafted on the surface of the gold nanoparticles. In order to avoid damaging exchange with part of the thiol molecules coupled to dyes, it is essential in this case to immobilize the molecules with biological activity before that of the organic dyes. However, these exchange reactions are relatively random and difficult to control. It should be noted that in the ΝaBHU pathway, the coverage of gold nanoparticles by thiol molecules is almost complete. The introduction of new thiol molecules therefore takes place only by exchange. It is important to note that for the hybrid probe nanoparticles prepared in the presence of citrate, there is no significant exchange of thiols: the nanohybrids are therefore stable in these cases and the properties retained. The proposed route therefore makes it possible to determine the “coating” of the gold nanoparticle, and therefore the characteristics of the probe particle obtained. According to the invention, it is possible to graft, to the surface of the gold nanoparticles, variable but determined quantities of fluorescent molecules and biological probes. The number of molecules on the surface of the nanoparticles can be easily determined by UN spectroscopy after precipitation of the gold particles, thus making it possible to know the chemical composition of the surface. The new probe particles according to the invention are of very particular interest, in particular, in the improvement of biochips, the study of the interaction between microorganisms and their environment, the individual tracking of biomolecules for the study of cell traffic and of cellular activity. The examples below are given purely by way of illustration and are not intended to be limiting.

Example 1

Preparation of a colloidal suspension of gold nanoparticles by the citrate / tannic acid method.

40 mg of sodium citrate and 10 mg of tannic acid are dissolved in 20 ml of ultra pure water. In parallel, 10 mg of hydrogen tetrachloroaurate, HAuCl ₄ .3H ₂ O trihydrate are dissolved in 80 ml of ultra pure water. The two solutions are then heated to 60 ° C. and then combined by transferring the sodium citrate / tannic acid solution into the gold solution. The mixture is then heated at 60 ° C at reflux for 1 hour then brought to the boil for 10 minutes and finally cooled to room temperature while maintaining stirring. The nanoparticles obtained have an average diameter of 8 nm, which refers to a concentration of 1.67.10 ^" moles of nanoparticles / liter.

Example 2

Preparation of stabilized gold nanoparticles ready to be functionalized by grafting of thiol derivatives.

The surface of the nanoparticles synthesized according to Example 1 is covered with thiol derivatives in precise proportions. The thiol derivatives used are sodium mercaptoethanesulfonate (MES), thiomaleic acid (AT) and mercaptophenol (MP). To a solution of 60 ml of nanoparticles are added 2 ml of aqueous solutions of each thiol derivative, the concentrations of which are as follows: AT: 1.112 × ¹⁰ −7 M obtained by dissolving 16.69 mg in 100 ml of deionized water, MES: 1,112.10 ^"7 M obtained by dissolving 18.26 mg in 100 ml of deionized water, MP: 2,224.10 ^{" 7} M obtained by dissolving 28.50 mg in 100 ml of deionized water. The additions are made successively every 30 minutes, the solution is kept under constant stirring.

Example 3 Preparation of a colloidal suspension of luminescent gold nanoparticles by the citrate / tannic acid method under the same conditions as those of Example 2.

On the hydroxyl functions of the mercaptophenols grafted on the surface of the gold nanoparticles are immobilized fluorescent molecules of rhodamine lissamine B. To 30 ml of solution prepared according to example 2 is added 1 ml of an aqueous solution of lissamine rhodamine sulfochloride B with a concentration of 10 ^"7 M in the presence of 10 ml of concentrated triethylamine. This gives gold nanoparticles carrying on average 200 molecules of lissamine rhodamine B.

Example 4

Synthesis of a thiol derivative of rhodamine lissamine B.

This derivative is obtained by reaction of the amino function of aminothiophenol on the sulfochloride function of rhodamine lissamine B. The reaction takes place at room temperature by dissolution in 100 ml of chloroform of 125 mg of lissamine rhodamine B and 26.9 mg of aminothiophenol in the presence of 1 ml of triethylamine. The solution is stirred for one day and then purified by a chromatographic column of silica with an eluent of dichloromethane / methanol, 9/1 (v / v).

Example 5 Grafting of thiolated derivatives of lissamine rhodamine B prepared according to example 4 on the surface of gold nanoparticles prepared according to example 1.

The preparation is carried out by adding thiolated rhodamine B lissamine solutions to the solution of gold nanoparticles with mechanical stirring. This addition is of variable quantity and concentration depending on the number of fluorescent molecules desired per nanoparticle; this number can vary from 1 to 400 for nanoparticles 12 nm in diameter. For example, for a desired ratio of 100 molecules of lissamine rhodamine B per nanoparticle, the addition will be 1 ml of an aqueous solution at 1.67.10 ^"5 M of lissamine rhodamine B thiolated on 10 ml of a solution at 1 , 67.10 ^"8 M gold nanoparticles.

Example 6

Grafting of a sulfur terminated folic acid derivative. A sulfur derivative of folic acid is obtained by grafting a bt -? - aminopropylpolyethylene glycol then modification by the reagent of Traut in order to obtain a thiol function. This derivative is grafted to the surface of gold nanoparticles by addition to a solution of nanoparticles prepared according to Example 1.

Example 7

Grafting of oligonucleotides onto the gold nanoparticles The oligonucleotides d (T) 22 terminated by a thiol function used are previously filtered on a column, 69 nanomoles of oligonucleotides diluted in 2.33 ml of water, ie a concentration of 29, 6.10 ^"6 M, are recovered. From 3.35 μl to 335.1 μl (from 0.2 to 20 oligonucleotides per nanoparticle) of this solution are then added to 1 ml of gold nanoparticles prepared according to Example 1, 3 or 5.

Example 8

Grafting of thiolated derivatives of lissamine rhodamine B prepared according to example 4 on the surface of gold nanoparticles prepared according to example 7. On the nanoparticles prepared according to example 7, grafted lissamine rhodamine B derivatives prepared are prepared according to example 4 in a ratio 100 for a gold nanoparticle. This grafting is carried out as described previously in Example 5. Example 9

Synthesis of gold particles partially surrounded by gadolinium oxide particles for offset absorption outside the emission zone of the grafted luminescent activity molecules.

The colloid of Gd ₂ O ₃ 5% Tb nanoparticles was prepared according to the polyol method (R. Bazzi, MA Flores-Gonzalez, C. Louis, K. Lebbou, C. Dujardin, A.

Brenier, W. Zhang, O. Tillement, E. Bernstein and P. Perriat in Journal of

Luminescence 102-103, 445-450, 2003). It consists of directly precipitating luminescent oxide nanoparticles from metal salts dissolved in diethylene glycol. After synthesis, the colloid obtained is dialyzed at 40 ° C in diethylene glycol (1:20 by volume).

Then HAuCl, 3H O is dissolved in the colloid (1: 3 by mass of initial salts).

The solution is stirred for 15 minutes, to turn yellow. Two aqueous solutions containing for the first 1 gl ^"1 of sodium citrate and 1.5 gl ^{" 1} of tannic acid and for the second 0.5 gl ^'1 of NaBË t are prepared in order to reduce the gold salt.

The first solution is added to the colloid, with stirring. After five minutes, the second solution is added (1: 1: 1 by volume). The addition is done slowly drop by drop. The colloid, during the various additions, loses its yellow color to pass through a transparent phase, then through an intense red phase, which appears gradually, direct proof of the presence of gold nanoparticles. Under certain conditions, the luminescence can be greatly exacerbated (by at least a factor

10).

Example 10

Synthesis of gold nanoparticles stabilized by thiol molecules carrying at their end a carboxylic acid function.

To 60 ml of methanol containing 49.10 ^"5 mol of tetrachloroauric acid (HAuCl ₄ , 3H ₂ 0) are added 38 ml of methanol containing from 49 to 196.10 ^{" 5} mol of carboxylic acid carrying one or two thiol functions and 1.96 ml of ethanoic acid.

After 5 minutes of stirring, 13.2 ml of an aqueous solution containing 480.10 ^"5 mol sodium tetrahydruroborate (NaBH ₄ ) are added dropwise to the mixture which darkens.

After 1 hour of stirring, 4 ml of an aqueous hydrochloric acid solution (HCl, 1 N) are added to the reaction mixture. The black suspension obtained is concentrated by partial evaporation of methanol under reduced pressure. The black solid is filtered, washed with 3 × 30 ml of 0.1 N HCl, 2 × 20 ml of water and 3 × 30 ml of diethyl ether. The reaction mixture is then dried at room temperature. The powder obtained can be easily redispersed in an aqueous solution whose pH is greater than or equal to 7.

Example 11

Grafting of luminol onto the gold nanoparticles prepared according to example 10. 8 mg of gold nanoparticles (with an average diameter equal to 5 nm) are dispersed in 10 ml of an aqueous solution of pH 8-10. 1 ml of a 0.1 M solution of 1-ethyl-3- (3-dimethylamino) propyl carbodiimide (EDC) and 0.2 M of pentafluorophenol in propan-2-ol is added to the colloidal solution of nanoparticles Golden. After 90 minutes, 154 μl to 1.54 ml of a 10 ^"2 M aqueous solution of luminol are added. After 150 minutes, the nanoparticles are precipitated by adding a 1N aqueous HCl solution. The resulting precipitate is filtered and washed before being redispersed in an aqueous solution of pH> 7.

Variant: instead of a propan-2-ol solution containing 0.1 M EDC and 0.2 M pentafluorophenol, an aqueous solution of 0.1 M EDC and 0.2 M N- hydroxysuccinimide can be used.

Example 12

Grafting of a thiolated oligonucleotide on the nanoparticles prepared according to example 11. 17

1.11.10 ^"9 mol of thiolated oligonucleotides are added to 1 ml of a colloidal solution of gold nanoparticles (6.7.10 nanoparticles / liter). After 1 h, the particles are precipitated by addition of nanoparticles of HCl 1 Ν The resulting precipitate is filtered and washed before being redispersed in an aqueous solution of pH> 7. Example 13

Grafting of an oligonucleotide terminated by an amino function on the nanoparticles prepared according to Example 11.

To 1 ml of a colloidal solution of gold nanoparticles (6.7.10 ¹⁷ nanoparticles / liter) is added 1 ml of a solution containing 0.1 M EDC and 0.2 M pentafluorophenol in propan-2 ol. After 90 minutes, 1.11 × 10 ⁻⁹ mol of thiolated oligonucleotides d (T) 22 terminated with an amine function are added. After 2 hours and 30 minutes, the nanoparticles are precipitated by addition of a 1N aqueous HCl solution. The resulting precipitate is filtered and washed before being redispersed in an aqueous solution of pH 8-10.

Variant: instead of a propan-2-ol solution containing 0.1 M EDC and 0.2 M pentafluorophenol, an aqueous solution of 0.1 M EDC and 0.2 M N-hydroxysuccinimide can be used.

Claims

CLAIMS 1 - Hybrid probe particles comprising a gold nanoparticle with a diameter included in the range from 2 to 30 nm at the surface of which are grafted by gold-sulfur bonds, on the one hand, at least one, and preferably from one to 100, organic probe molecules and on the other hand, at least 10, and preferably 10 to 10000, molecules with luminescent activity. 2 - Hybrid probe particles according to claim 1 characterized in that the number of luminescent activity molecules grafted on the surface of the gold nanoparticle is at least 10 times greater than the number of organic probe grafted molecules. 3 - Hybrid probe particles according to claim 1 or 2 characterized in that 10 to 1000, preferably 100 to 500, molecules with luminescent activity are grafted onto the gold nanoparticle. 4 - Hybrid probe particles according to one of claims 1 to 3 characterized in that the molecules with luminescent activity are fluorescent organic dyes whose maximum emission differs by at least 25 nm from the maximum absorption of the plasmon gold. 5 - Hybrid probe particles according to one of claims 1 to 4 characterized in that the molecules with luminescent activity are electroluminescent or chemiluminescent compounds, for example derivatives of luminol. 6 - Hybrid probe particles according to one of claims 1 to 4 characterized in that the luminescent activity molecules are luminescent compounds whose wavelength of the emitted light is greater than the excitation wavelength, preferably at least 200 nm. 7 - Hybrid probe particles according to one of claims 1 to 4 characterized in that the molecules with luminescent activity are lanthanide complexes. 8 - Hybrid probe particles according to one of claims 1 to 4 characterized in that the luminescent activity molecules are chosen from rhodamine derivatives and in particular those of lissamine rhodamine B. 9 - Hybrid probe particles according to one of claims 1 to 8 characterized in that at most 75% of the gold nanoparticle is covered with a covering material having dielectric characteristics allowing the shift of the plasmon band of gold outside the emission zone of luminescent molecules. 10 - Hybrid probe particles according to claim 9, characterized in that the covering material is chosen from polysiloxanes, SiO ₂ , ZrO ₂ , Ln ₂ O ₃ and lanthanide oxohydroxides. 11 - Hybrid probe particles according to one of claims 1 to 8, characterized in that the molecules with luminescent activity are grafted to the gold nanoparticles by means of an organic thiolated spacer, this spacer not being identical to probe organic molecules. 12 - Hybrid probe particles according to claim 11 characterized in that the spacer contains from 6 to 50 carbon atoms and is, for example, chosen from mercaptophenols, dihydrolipoic acid and thio-poly (ethylene glycol). 13 - Hybrid probe particles according to one of claims 1 to 12 characterized in that the gold nanoparticle has a diameter in the range from 4 to 20 nm, preferably in the range from 5 to 16 nm. 14 - Hybrid probe particles according to one of claims 1 to 13 characterized in that 1 to 10 organic probe molecules are grafted onto the gold nanoparticle. 15 - Hybrid probe particles according to one of claims 1 to 14, characterized in that the organic probe molecules are chosen from polynucleotides of DNA, RNA or oligonucleotide type, proteins of antibody type, receptor, enzyme, enzyme / substrate complex, glycoproteins, polypeptides, glycolipids, dares, polysaccharides and vitamins. 16 - Hybrid probe particles according to claim 14 characterized in that the organic probe molecules are thiolated oligonucleotides or linked to a thiolated spacer. 17 - Hybrid probe particles according to one of claims 1 to 14 characterized in that the organic probe molecules are molecules allowing the biotin - streptavidin interaction. 18 - Hybrid probe particles according to one of claims 1 to 17 characterized in that in addition, 10 to 1000 other thiol organic molecules, distinct from the probe organic molecules and molecules with luminescent activity, are grafted onto the gold nanoparticle , these other thiolated organic molecules comprising, preferably at least one alcohol, amino, sulfonate, carboxylic acid or phosphate function. 19 - Process for preparing hybrid probe particles according to one of claims 1 to 18 characterized in that it comprises the following steps: - preparing a colloidal suspension of gold nanoparticles of diameter included in the range from 2 to 30 nm, by reduction of a gold salt, and in particular of hydrogen tetrachloroaurate, in aqueous or alcoholic phase and in the presence of citrate, add, to the colloidal suspension obtained, an aqueous or alcoholic solution of organic molecules thiol probes grafting onto the surface of gold nanoparticles by gold-sulfur bond to replace citrate molecules, add, to the colloidal suspension obtained, an aqueous or alcoholic solution of luminescent activity molecules grafting onto the surface of nanoparticles by gold-sulfur bond to replace citrate molecules. 20 - Process for preparing hybrid probe particles, characterized in that it comprises the following steps: - preparing a colloidal suspension of gold nanoparticles with a diameter comprised in the range from 2 to 30 nm, by reduction of hydrogen tetrachloroaurate , in aqueous or alcoholic phase and in the presence of citrate, add, to the colloidal suspension obtained, an aqueous or alcoholic solution of thiolated spacers functionalized with an ionizable function capable of reacting with organic probe molecules or molecules with luminescent activity to be grafted , the said spacers coming to be grafted on the surface of the gold nanoparticles by gold-sulfur bond in replacement of citrate molecules, add an aqueous or alcoholic solution of organic molecules probes functionalized to react with the ionizable function carried by the spacers grafted in surface of the gold nanoparticle, and / or add an aqueous or alcoholic solution of functionalized probe organic molecules to react with the ionizable function carried by the spacers grafted on the surface of the gold nanoparticle. 21 - Process for the preparation of hybrid probe particles according to claim 19 or 20 characterized in that the reduction of the gold salt is carried out in the presence of tannic acid. 22 - Process for preparing hybrid probe particles according to one of claims 1 to 18 characterized in that it comprises the following steps: - preparing a colloidal suspension of gold nanoparticles of diameter included in the range from 2 to 30 nm, by reduction of the gold salt, and in particular of hydrogen tetrachloroaurate, in aqueous or alcoholic phase and in the presence of NaBH, add, to the colloidal suspension obtained, an aqueous or alcoholic solution of thiolated spacers functionalized with a ionizable function capable of reacting with organic probe molecules or molecules with luminescent activity to be grafted, the said spacers grafting onto the surface of the gold nanoparticles by gold-sulfur bond, adding an aqueous or alcoholic solution of functionalized probe organic molecules to react with the ionizable function carried by the spacers grafted on the surface of the gold nanoparticle, add a solu aqueous or alcoholic tion of organic molecules functionalized probes to react with the ionizable function carried by the spacers grafted on the surface of the gold nanoparticle.