FR2708002A1 - Process for the preparation of organometallic complexes and their applications as medication and in chemical catalysis - Google Patents

Abstract

Process for the preparation of organometallic complexes, in which a water-soluble organic compound which contains a carbonyl functional group is complexed with a metal. The said complexes are obtained by the electrosynthesis by placing in a vessel (1) containing the said organic compound a solution (2) in water, two metal electrodes (3, 4) between which an electrical voltage is applied, the anode being the metal to be complexed on the organic compound. The complexes obtained can be employed in therapeutics or in chemical catalysis.

Description

 The present invention relates to a process for the preparation of organometallic complexes.

 The invention also relates to the use of organometallic complexes obtained by the above process, especially as a drug or in chemical catalysis.

 The invention thus relates to a process for the preparation of organometallic complexes, in which a metal-containing organic compound is soluble in water and having a carbonyl function.

 According to the invention, this process is characterized in that said complexes are obtained by electrosynthesis by placing in a tank containing said organic compound in solution in water, two metal electrodes between which an electrical voltage is applied, the anode being in the metal to be complexed on the organic compound.

 This method thus makes it possible to perform, in particular, the complexion of aliphatic or hemicyclic monoses, polyoses, coenzymes, amino acids, proteins, chemical mediators, neurotransmitters, hormones, vitamins, nucleic acids, oligosaccharides, in the presence of metal electrodes.

 Other features and advantages of the invention will become apparent in the description below.

In the accompanying drawings given as non-limiting examples:
- Figure 1 is a sectional view of an electrolytic tank for carrying out the method according to the invention;
FIGS. 2A to 24 represent various organic compounds that can be complexed with a metal, according to the process according to the invention.

 FIG. 1 represents a tank 1 containing an aqueous solution 2 of an organic compound having a carbonyl function which is to be complexed by means of a metal.

 In this tank 1 plunge two electrodes 3, 4 of metal connected to a source of electric current 5. Among these electrodes, the anode is made in the metal to be complexed on the organic compound.

 Reference 6 designates a tube through which an oxidizing gas such as oxygen is sent into solution 2.

 Tests have shown that when a voltage is applied between the two electrodes of the tank, the metal of the anode goes into solution and is fixed on the carbonyl group of the organic compound.

 The invention consists in a first version to solubilize sugars (C61 C12 and C5) and more generally of (Cn) form in batches, but also polyoses (con1) 'and to complex them by electrosynthesis with metals (or natural elements). The sugars used have a ketone function or carbonyl (C = O) function. This carbonyl function, as in fructose, is associated with other alcohol or aldehyde groups. The method in its installation aims at fixing a metal or a plurality of elements (Se Zn) electrochemically on the carbonyl, aldehyde and more rarely on the alcohol function.This metal or natural element associated with the structure may have valencies greater than 1.

 Exceptionally the monovalent elements (Na, K, Li) can be associated with anodic alloys to allow their release in the aqueous medium.

 Other alkali or alkaline earth metals Ba, Ca, Sr may also be associated with anodic alloys.

 The method provides, according to the quantities of products to be produced, to proportionally dimension the electrolytic cell, the size of the electrodes and the current density, as well as the voltage to be imposed on the electrosynthesis medium.

 The first experiments were carried out in experimental tanks of 5 liters of capacity using fructose (C6) of empirical formula C6H120-6 having one or the other of the developed formulas shown in FIGS. 2A and 2B.

 The DC voltage imposed on the terminals varies from 10 to 220 volts and the intensity can vary from 0.3 to several tens of amperes for larger vessels (in the experiment 1 to 3 amperes).

 The spacing of the electrodes varies from 0.5 cm to several centimeters for a tank of 5 liters, the anode is of the same nature as the metal to be displaced and complexed.

 Since fructose is reducing, we choose variable ratios (sugar / water) as well as an external supply of pure oxygen or air, a few liters per minute, to avoid that the form Fe + 2 (ose) predominates over the form Fe + 3 (dare).

 The form Fe2 + (ose is green in color depending on the concentration of Fe2 + ions.

 The Fe3 + (ose) form is bright red and darkening as a function of Fe3 + ion concentration.

 The bath temperature should be maintained between 20 and 50 ° C in order to avoid rapid oxidation of the complex formed Fe 2 + ose or Fe 3 +ose.The bath may deserve moderate agitation.

 The concentration of the metal is a function of the electrolysis criteria imposed and the time given to the electrosynthesis. The products formed are considerably stable, including for Fe2 + (ose), provided that it is kept away from heat and bright light, and that it is easier to store in bottles or glass bottles.

 The concentrations (Fe2 +, Fe3 +) obtained vary from a few mg / l to a few g / l.

The sugar / water ratios are as follows:
To obtain a Fe2 + complex (without O2 outside) 300 g of sugar / 1000 g of water, this ratio can be variable.

 The supply of 02 also allows a better homogenization of the electrolytic medium and thwarts the reduction by sugar. Complementary experiments were conducted with other divalent or trivalent or tetravalent metals. They form stable complexes with fructose and usually with other oses.

The complexed metals were as follows:
Cu: 439 mg / L, Zn: 500 mg / L, Co: 90 mg / L, N: 80 mg / l, Fe: 1300 mg / L, V: 300 mg / l, Mg: 600 mg / L, Sb : 50 mg / L, AI: 10 mg / L,
Ag: 30 mg / L.

Metalloids: C, Se, semiconductors: Ge, Si, and lanthanides more particularly:
Tm: 173 mg / L, Lu: 170 mg / L, Yb: 300 mg / L, La: 150 mg / L,
Gd: 70 mg / L, Nd: 100 mg / L.

 It appears that all metals can be complexed to an ose or polyose using the described electrosynthesis method.

 The process may also use alloy anodes composed of elements such as Na, K, Ca, Ba, Sr, Se.

 This method exceptionally allows these elements to participate in the complexion mechanisms.

 The same process can be used for semiconductors.

Mechanisms of the complexion (case of fructose)
The rotation-vibration spectrum is comparable to a harmonic oscillator whose formula can be simplified to:

For the absorption-rotation-vibration spectrum of the CO molecule, we find:
> C = 0 1650 - 1750 cm -1 G = 1 cm -1
For C - H 3030 cm-1 (aromatic cycle).

 For = C - H 3025 cm1 ethyl.

For O - H 3500 - 3700 cm-1 liter
The IR (Infra-Red) spectra obtained and appended indicate the complexation of Fe3 + at the C = O carbonyl site for 1660 cm-1 (predicted by the calculation), a region for which the substitution energy is lower than on said CH or OH.

 In sugars that do not have C = O functions, the metals will complex on the aldehyde functions more rarely on the alcohol functions.

 The process can also use deuterated water (D20) for the preparation of analysable NMR (nuclear magnetic resonance) complexes and contrast agents.

 The method may also make it possible to use radioactive isotopes associated with pharmaceutical carrier or tagger vectors, and also as biological markers (oncology, viral oncology, immunology).

 The product obtained Fe3 + (fructose type) or iron frutosanate has very important anti-mitotic properties. Its cytotoxicity at 100 mg / L of Fe + 3 tested (in vitro) on tumor lines A549 (lung cancer) MCF7 (777: breast cancer) attests inhibitory activity of the mitosis of tumor cells.

 The product obtained called FLNT4 certainly proceeds to an inhibitory mechanism of viral polymerases of A549 tumor cells.

Absorption of this product at equivalent doses of
ADI, tolerable daily intake, does not cause any side effects.

These tests performed in an anti-cancer center should be extended to other tumor cell lines.

 The present method therefore makes it possible to prepare a complex with selective antimitotic properties on tumor cells with almost zero side effects.

 The interesting properties of this product could be applied to retroviruses (HlV, Epstein-Barr) and generally in immunotherapy, and in chemotherapy as a therapeutic or nutritional adjuvant.

 Fe2 + (ose) is the subject of the same study.

 Fe2 + (ose) and Fe3 + (ose) products can also be considered as therapeutic nutrients for iron deficiency or iron deficiency anemia.

 The product FLNT4 (or Fe2 / 3 +) (fructose) can also be associated with a few percent of lanthanides also complexed with monosaccharides (Cn) in cancer or immunotherapeutic applications.

Use of other sugars and biological consequences
D (+) Ribose, C5 H10 5
The complexion of natural elements metals and metalloids on the ribose, according to the same experimental conditions delivers stable complexes, the Fe3 + or Fe2 + chelation sites being the alcohol or aldehyde functions according to the experimental conditions. The source of riboses being nucleic acids, their importance as structural elements of DNA, RNA, ATP, NADP and flavoproteins and other complexes make it possible to develop specialized complexes in correspondence with the enzyme-metal-substrate problems, but also in function of specialized enzymes (polymerases, helicases, ligases and others).

 D (+) lyxose (C5 H10 0-5) sugar that can be complexed with natural elements, such as Mg, Se, Fe or Zn and Cr or others, could be suitable for cardiovascular therapy (atrophy, sclerosis and other degenerative phenomena heart tissue). Her employment in sports medicine or for the pregnant woman could be considered.

D (+) mannose (C6H12O6)
Sugar forming glycoproteins (mucoproteins) biological fluids, tissues and cell membranes involved in molecular recognition phenomena (antigen) -bodies. The complexion of natural elements (metals or metalloids) will allow the development of "anti-adsorption" drugs, including inhibitors of the dissemination of metastatic cells from a tumor origin. This complex should also allow the realization of hormonological therapeutics. The configuration of biological cells adopts a membrane envelope of "osic" or "sweet" type. The membranes are seeded with glycoproteins, carbohydrates, proteins and lipids. These specialized sugars make it possible, on the one hand, to recognize hostile or beneficial entities and to attach themselves to them as much to paralyze them as to the interest of the cellular economy. These bodies may be hormonal precursors, prions (or parts of viruses), cells, signal molecules, amino acids, bacteria, viruses or retroviruses, toxins, hormones, etc.

 Certain sugars obtained by the method should make it possible to inhibit the action of the surface lectins of the tumor cells and to prevent the dissemination of these cells. The described iron fructosanate, already corroborates this hypothesis.

 The products resulting from the method can be associated with interleukins I, II and cytokines in general, as well as contribute to a better knowledge of cellular communication proteins in the leucocytic hypothesis.

 The complex D (+) mannose and iron or other elements such as lanthanides or selenium will design anti-hemoagglutinative therapy in vascular and circulatory diseases.

 This anti-hemoagglutinating anti-adsorption avoids the fixation of bacteria in the tissues to the detriment of cellular ireconomy.

 Likewise, D (+) mannose or fructose complexed with natural elements praise an important role in lymphocyte defense mechanisms. The applications of these products in immunotherapy are obvious (leukocyte protection against retroviral and viral aggression) inhibition of the GP120 and GP41 (viral glycoprotein) (HIV virus) parts.

oligosaccharides:
In general, by the process, in their water-soluble form, these bodies complex with the natural elements.

The electrosynthesis technique can also be applied to simple or hybrid oligosaccharides such as heparin to form with the latter a nutritional complex of the cardiac muscle and to possess preventive actions on the formation of terminal glycosylation products (or amadori product). ) and to avoid the formation of SCHIFF bases in athematous molecular pathology
disaccharides:
Disaccharides such as maltose, sucrose (sucrose), lactose trehalose, cellobiose also complex with anodic natural elements.

polysaccharides:
The complexion of the rice starch or a soluble type starch delivers a compound formed of a metal of anodic origin and the
Polysaccharide.

protein:
The method makes it possible to treat, by in situ complexion of casein (and an anode metal Fe, Mg, Zn, etc.), cow's milk and a protein of plant origin (soybean). The complexes obtained are stable at the ferrous stage.

 The nutritional application of the process is obvious and compatible with existing agri-food and dairy facilities.

 The process also allows the formation of milk derivatives (yoghurt, cheeses, butters, etc.) without destabilizing the complexion obtained with the metal or element chosen.

Protein complexes:
Proteins, in particular flavoproteins and metalloflavoproteins, by virtue of their peptide bonds containing the carboxyl group CO, allow the formation of stable complexes formed of anodic metals.

 Since the metals or selected elements are attached to the C = O groups and the disulfide bond is not modified by the complexion, the process can be applied to the heme nuclei (myoglobin and hemoglobin).

 The method is interesting in that it could be used to treat human hemoglobin in situ (extracorporeal transfusion reservoir equipped with the method).

 The method is also interesting in that it can allow Rh compatibility in transfusion procedures.

This method applies to severe or accidental iron deficiency and to the restoration of defects in protein synthesis (also treatment for mutant methemoglobinemias) and sickle-shaped molecular disease for red blood cells. The coupling of the enrichment requires a control of the dimensional structure of the protein and its weight, different methods can be used for this purpose (IR spectroscopy,
X, mass) electrophoresis.

Complexion of the porphyrin cyclic system of chlorophyll:
The central disposition of magnesium (Mg) makes it possible to envisage a nucleophilic substitution of the Mg atom by an iron atom (Fe) or other elements (Cu, Zn ...).

 Furthermore, other modifications of the structure obtained and in particular for the group (phytyl C20 H39 2 C (CH2) 2) allows the complexion of a structure very close to the porphyrin ring system of hemin.

 We can consider this substitution analogous to that encountered in the polar structures of pentagonal heterocyclic pyrrolic bases. This operation opens the way to obtaining a substitution compound of the human heme.

 In the experiment carried out, we treat a soluble sodium chlorophyll (chlorophylline Na - Cu).

Complexion of enzymes and coenzymes:
The enzymes can also be complexed with the process.

Several coenzymes and analogous compounds are derived from A.M.P.

adenosine mono-phosphate.

 The complexion of d-ribose already carried out with a large number of anodic elements makes it possible to understand the extent of the process both in the catalytic domain biotechnological and microbiological. Enzymes and co-enzymes that can be complexed (non-limiting list).

 Oxidoreductases, transferases, acyltrans-ferases, transaminases, hydrolases, ligases, proteinases, lyases, aldehyde bases, isomerases, DNA helicases, nucleases, kinases, DNA polymerases, RNA primases, DNA topoisomerases, restriction enzymes, viral or retroviral polymerases, viral primases or retroviral ...).

 Co-enzyme A and (acetyl coenzyme A).

 (See formula developed in Figure 3).

The biological importance of this intermediate product of the general metabolism (citric acid cycle) makes it possible to carry out anodic complexes both on the acetyl CoA complex and on the product.
CoA due to the carbonyl functions present in the acetyl and CoA groups.

 The acetyl CoA and CoA complexion with divalent elements such as Mg, Fe, Zn makes it possible to correct malfunctions of the citric acid cycle, as well as to improve the mechanisms of NADH and FADH2 oxidative phosphorylation.

NAD ± -> NADH (nicotinimide H)
FAD -> FADH2 (flavin adenine H2)
Ubiquinone Q (r) can also be complexed (r = number of isoprenoid units which varies from 6 to 10).

Complexion with trivalent metals of anodic origin
Al3 + but also Ln3 + (lanthanides) and Fe3 +, allows the synthesis of competent compounds in membrane mechanisms subject to both dysfunction, and viral or retroviral attacks, by selective antimitotic properties. The applications of these compounds in chemotherapy and immunotherapy are certain.

Amino acid complexion:
The process allows the complexation of amino acids with CO2H or COOH function with metals or elements of anodic origin.

 The amino acids contain at least two weakly ionizable acidic groups a COO- and NH3 +.

The representation of the complexion can be as follows:

<tb><SEP> raH =
<tb> RoX <SEP> / e <SEP><SEP> site cèrcn / e: <SEP> GO
<tb><SEP> o
<Tb>
The carbonyl site C = O being the site of the metal fixation of anodic origin:
The complex obtained with glutamic acid indicates the generalization of the process in amino-acid complexes. The complexation of CO (NH 2) 2 urea by metals provides a simple and general example of the process (IR absorption spectra).

 The saturated and unsaturated fatty acids (α-linoleic acid or arachidonic acid) as well as glycerols, triacylglycerols and phospholipids can also be complexed by means of the process according to the invention.

Peptide complexes:
Generally a peptide consists of two or more amino acid residues linked together by peptide bonds.

 Representation of the structure of glutathione (- glutamyl cysteinyl - glycine) (see formula developed in FIG. 4) which is an important tripeptide in the hormonological and enzymological synthesis (syntheses of insulin and enzymes).

Complexion sites of anodic metals:
The binding of an iron-selenium anodic complex to glutathione or to the enzyme glutathione peroxidase makes it possible to obtain an immunoprotective complexion of the action of free radicals on the destructuration of the membrane proteins of antibody antigen recognition.

The synergy of these bodies obtained above with the vitamin
E (tocopherol) or an anodic metal complex with vitamin E, delivers an autoimmune-active complement.

Vitamin E in its soluble form delivers a complex with different metals: with anodic iron, it forms a ferrous Fe2 + compound which, under the effect of oxidation, can be transformed into
Fe 3+.

 The concentration obtained is 923 mg / l.

hormones:
Insulin: The anodic metal complexion method applies to insulin.

The most interesting elements seem to be the Zn, Cr,
Co, Ni, Mg and lanthanides. Insulin has indeed a terminal group - COOH allowing the complexion. The complexion can also be applied to the activation mechanisms of proinsulin.

The products of the complexion obtained can be applied in diabetology.

 The drug combination of Zn fructosanate and complexion (insulin Zn) and other elements, allows a better restoration of hormonological activity. These products stimulate the enzymatic synthesis of phosphofructokinase and pyruvate kinase.

glucagon:
The glucagon polypeptide of 29 amino acids can be complexed by the method due to the presence of COOH sites.

steroids:
Cortisol can be complexed by the process due to the presence of 2 C = O carbonyl sites (see Figure 5).

 Testosterone can be complexed by the process due to the presence of a CO carbonyl site (see Figure 6).

thyroxine:
The thyroxine possessing a COOH carboxylic group allows the complexion by the process (see FIG. 7).

Local chemical mediators:
Prostaglandins E2: (see Figure 8)
The presence of a carbonyl group C and the CO2H function in the prostaglandin allows the complexion by the process.

Neurotransmitters: see Figure 9)
vitamins:
Vitamin E in (tocopherol) (see Figure 10).

 The complexion with Fe2 + of anodic origin in solutions (soluble vitamin E form) titrated with 1 to 20 g / liter of water, delivers a green blue Fe2 + compound which can be transformed into Fe3 +. The reaction must be thermally controlled and protected from light.

Complexion with selenium of anodic origin (alloy
Fe-Se) makes it possible to obtain a compound that is immediately useful in the glutathione peroxidase mechanisms. The complexes obtained with both selenium (2+) and lanthanides or iron can be used in immunotherapy or chemotherapy.

 Vitamin K in substituted naphthoquinones, (R) and mainly phylloquinone (vitamin K1), by the presence of 2 carbonyl groups allow the complexion with metals of anodic origin (see Figures 11 and 12).

 Vitamin K3 or menadione by the presence of two carbonyl groups Co also allows a complexion. Vitamin K1, phytonadione, mephytone or pylloquinone (see Figure 13).

 Vitamin K2 or menaquinone with n = 6.7 or 9- (see Figure 14) by the presence of 2 carbonyl groups Co allows the complexion with metals of anodic origin.

 The use of the above-mentioned complexion products in hepatocardiovascular therapeutics and in the syndromes of seed malabsorption is certain; as well as the complexes obtained can serve as antitode to anticoagulants such as 4 hydroxycoumarines.

 The complexes may also contribute to the maintenance of normal levels of factors II, VII, IX, and X of blood coagulation.

Vitamin D
Vitamin C (ascorbic acid) (see Figure 15).

 The presence of a carbonyl group C = O and an oxygen bond carried at C1, C4 allows the complexion of compounds formed of elements of anodic origin.

 The complexation of ascorbic acid with copper and Fe of anodic origin delivers an intermediate compound in the mechanisms of oxidative degradation - the compound obtained uses the Fe3 + form with a concentration of 25 mg / L (experimental condition 0.1 to 1 g of ascorbic acid per liter).

 Oxidation of p-hydroxylphenylpyruvate homo-genetisate and tyrosine homogentisate dioxygenase.

 The products of the complexion can contribute in the therapeutic martial as a curative or preventive as well as in the hormonological mechanisms of the adrenal cortex.

Vitamin A
The complexion of retinoic acid (see Figure 16) is possible due to the presence of the aldehyde site.

Vitamin B2 (Riboflavin) (see Figure 17)
The presence of 2 carbonyl CO groups on the heterocyl-3 amide allows the complexion with metals of anodic origin in the absence of light.

Vitamin B6
The pyridoxal form (see Figure 18) of the natural set of vitamin B6 allows the complexation with metals of anodic origin due to a carbonyl group C present in the aldehyde form of pyridoxal.

 The complexes obtained favor the formation of the pyridoxal phosphate compound in the presence of the pyridoxal kinase enzyme; these compounds being essential in the coenzymatic mechanisms and in the decarboxylation transamination reactions.

Vitamin B12
The presence of 7 C = O carbonyl groups in cobalamin allows the additional complexation of cobalt atoms or, exceptionally, the nucleophilic substitution of the cobalt central atom by a metal of anodic origin.

The compounds obtained are applicable in the secondary neurological disorders (cobalamin deficiency) induced by a primary deficiency of methionine (La).

 This amino acid, in turn, can be complexed by the process.

esters:
Acetylsalicylic acid (Aspirin) (see Figure 19).

 The presence of a CO carbonyl group allows the complexion with metals or metalloids of anodic origin.

 The experiment can be conducted with caution (thermal rise of the electrosynthesis bath) with amounts of 1 to several grams / liter of acetylsalicylic acid.

 The product obtained with the anodic iron is in the stable form Fe3 +.

 The applications of the complexes are numerous both in the vascular and cellular membrane protection but also as promoters of reactions in the conversion of arachidonic acid into prostaglandins.

antibiotics:
Streptomycin (see Figure 20) derived from a trisaccharide having a CHO aldehyde function with the carbonyl group
C = O allows the complexion with the natural elements of anodic origin.

Chloramphenicol (see Figure 21)
The presence of a carbonyl group C = O allows the complexion with metals of anodic origin.

Novobiocin (see Figure 22)
The presence of a carbonyl group and a [CONH] peptide bond on a heterocycle of the type shown in FIG. 22 allows a good complexion of novobiocine with natural elements of anodic origin.

Tetracycline (see Figure 23)
The presence of 3 carbonyl groups allows a very good complexion with the natural elements of anodic origin.

Penicillin (see Figure 24)
Penicillin is an example of a peptide substance having two carbonyl groups allowing a complexion with metals or elements of anodic origin.

 Gramicidin S and oxytocin also having several carbonyl groups allow the complexion by the method.

 Erhythromycin and rifamycin may also allow complexion with the process.

Biotic and therapeutic consequences of formed complexions
Antibiotics considered as specific inhibitors cause side effects, some patients are intolerant to these molecules.

 Erythromycin, tetracycline, chloramptenicol, rifamycin as inhibitors of RNA synthetase, while blocking the mitosis of bacterial or viral agents, cause side effects and can lower immune defenses when administered intensively. The complexion with the process makes it possible to release in the protein and enzymatic medium the metals and natural elements depleted by the antibiotic reaction.

Industrial catalysis:
Complexion of ketones at C = O sites.

 Some aliphatic or aromatic ketones are complexed by the process.

 The natural elements (metals and metalloids) can be substituted for the oxygen of the C = O group.

1. Acetone CH3-CO-CH3
2. Ethyl methyl ketone CH3-CO-C2 H5
3. Cyclohexanone
4. Quinone
The proportion of ketones in the electrosynthesis medium is a function of the reciprocal solubility (water-ketones).

 Complexion experiments can be conducted from a mixture of 5 to 20% ketones.

 The ketones involved in the process are aliphatic, alicyclic, aromatic or mixed ketones.

Aliphatic ketone

Aromatic ketone

Mixed ketone

les aldéhydes
forment des complexes stables avec le procédé.Alicyclic ketone (CH2) n C = O
Complexion of aldehydes:
General education

aldehydes
form stable complexes with the process.

 The ratios aqueous media and aldehydes are dependent on the conductivity of aldehydes and their miscibility with water.

Complexion of carboxylic acids:
General education with the presence of a

 C = O carbonyl site, the carboxylic acids form complexes with the process.

 With gluconic acid, we obtain concentrations above 1800 mg / L.

r avec la présence
groupement carbonyle C = O, les esters forment des complexes avec le procédé.Complexion of esters:
Of general formula

r with the presence
C = O carbonyl group, the esters form complexes with the process.

Complexion of anhydrides:
Of general formula

with the presence of several carbonyl groups
C = O, the anhydrides form complexes with the process.

Complexion of acid halides:
Of general formula

 with the presence of a carbonyl group C = O, the acid halides form complexes with the process.

Complexion with amides:
Of general formula

 with the presence of a carbonyl group CO, the amides form complexes with the process.

Pharmaceutical Magnetotracers - Isotope Markers:
By adding isotopes in electrodes of the same metal, it is possible to fix isotopic elements on organic complexes.

 The method makes it easy to complex isotopic elements for pharmacological and pharmacodynamic studies.

 The application of the method is of general scope and is aimed at both preventive and curative medicine. The method makes it possible to produce transition metal-based pharmaceutical magnetotracers and lanthanides useful in NMR nuclear imaging explorations.

Claims (16)

 A process for the preparation of organometallic complexes, in which a metal is complexed with a water-soluble organic compound having a carbonyl function, characterized in that said complexes are obtained by electrosynthesis by placing in a tank containing said organic compound a solution in water, two metal electrodes between which a voltage is applied, the anode being in the metal to be complexed on the organic compound.  2. Method according to claim 1, characterized in that is applied between the two electrodes a DC voltage between 10 and 220 volts and a current between 0.3 and several tens of amperes.  3. Process according to claim 1, characterized in that the organic compound is a sugar.  4. Process according to claim 1, characterized in that the organic compound is an oligosaccharide.  5. Process according to claim 1, characterized in that the organic compound is a disacharride or a polysaccharide.  6. Process according to claim 1, characterized in that the organic compound is an enzyme or coenzyme.  7. Process according to claim 1, characterized in that the organic compound is a protein, a peptide or an amino acid.  8. Process according to claim 1, characterized in that the organic compound is a hormone.  9. Process according to claim 1, characterized in that the organic compound is a steroid.  10. Process according to claim 1, characterized in that the organic compound is a prostaglandin.  11. Process according to claim 1, characterized in that the organic compound is a neurotransmitter such as glycine, Aminobutyric acid, or acetyl choline.  12. Process according to claim 1, characterized in that the organic compound is a vitamin.  13. Process according to claim 1, characterized in that said organic compound is an ester.  14. The method of claim 1, characterized in that said organic compound is an antibiotic.  15. Use of the organometallic compound obtained according to any one of claims 1 to 14 as a medicament.  16. Use of the organometallic compound obtained according to any one of claims 1 to 14 as chemical catalysis.