Classifications

• • C—CHEMISTRY; METALLURGY
  • C40—COMBINATORIAL TECHNOLOGY
  • C40B—COMBINATORIAL CHEMISTRY; LIBRARIES, e.g. CHEMICAL LIBRARIES
  • C40B30/00—Methods of screening libraries
  • C40B30/08—Methods of screening libraries by measuring catalytic activity
• • B—PERFORMING OPERATIONS; TRANSPORTING
  • B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
  • B01J—CHEMICAL OR PHYSICAL PROCESSES, e.g. CATALYSIS OR COLLOID CHEMISTRY; THEIR RELEVANT APPARATUS
  • B01J2219/00—Chemical, physical or physico-chemical processes in general; Their relevant apparatus
  • B01J2219/00274—Sequential or parallel reactions; Apparatus and devices for combinatorial chemistry or for making arrays; Chemical library technology
  • B01J2219/0068—Means for controlling the apparatus of the process
  • B01J2219/00702—Processes involving means for analysing and characterising the products

Definitions

• the present invention relates to the field of catalysis and aims in particular to propose a method for constituting a database making it possible to quickly identify one or more usable catalysts for the transformation of a compound and more particularly of at least one of its reaction units, according to a given chemical reaction.
• Organic synthesis by catalytic route, and in particular by heterogeneous catalysis, is a synthetic route particularly appreciated at the industrial level.
• the use of a catalyst generally makes it possible to accelerate the reaction rate, to lower the reaction temperature and / or to increase its yield.
• heterogeneous catalysts that is to say insoluble in the reaction medium as opposed to so-called homogeneous catalysts, have the significant advantage of being easily separated from the reaction products, at the end of the chemical reaction considered.
• the present invention aims in particular to allow rapid creation of a database useful for identifying at least one catalyst meeting a reaction criterion.
• the invention meets this need by means of a process for constituting a database making it possible in particular to select at least one catalyst suitable for a reaction, this process comprising the following steps: a) preparing a plurality of different reaction media containing the same probe of reactivity and each at least one catalyst, b) analyze, by an analytical method, each reaction medium after reaction, c) assign in the database, to the reactivity probe a result of the analysis according to step b) , this result characterizing the various reaction products obtained in the reaction medium, where appropriate with their respective yields from this reactivity probe.
• the plurality of different reaction media can include at least two reaction media containing different catalysts.
• reaction media can be used for different probes, and preferably are used systematically for different probes.
• the analytical method can be a liquid or gas chromatography method. Steps a) to c) above can be repeated for a plurality of different reactivity probes and / or a plurality of different reaction media.
• reaction unit designates a unit having at least one function or bond capable of being chemically transformed. This motif can in particular be constituted for example by a saturated bond of a carbon atom with at least one heteroatom, or an unsaturated bond between two carbon atoms, between a carbon atom and at least one heteroatom or between two identical heteroatoms or different.
• the unsaturated bonds between two carbon atoms can be, for example, hydrocarbon bonds C sp of alkynic type, or p2 of alkenic type.
• the term “heteroatom” is intended to cover a nitrogen, oxygen, sulfur, phosphorus, silicon, boron atom, etc. As representative and nonlimiting of units reactionary, the following reasons may in particular be cited:
• the database can contain, for each catalyst listed, information concerning the reaction medium and reaction conditions (temperature, pressure, pH, etc.) in which it has been tested for its catalytic activity.
• the database can individually list the reaction patterns present on the reactivity probes. At least for part of the reaction patterns listed in the database, can be associated with each listed reaction pattern, information aimed at qualifying the state of the links associated with it. It is important to note that the state of the links does not bode well for their reactivity. Thus, it is not identical in a reducing or oxidizing, or acidic or basic medium, for example.
• the state of the bonds of a reaction unit can be indexed using an integer, called state of the bonds and which can vary from 0 to 3, the value 0 generally qualifying the absence of bond and the value 2 characterizing a double bond. Consequently, each pair of reaction unit / reaction medium can be associated with a pair of bond states which can qualify the degree of reactivity of said unit before and after its exposure to said reaction medium. For example, in the event of no reaction, the state of the original links is preserved; in the event of reduction, the state of the links decreases by at least one unit; (a state equal to zero means the rupture of a connection).
• a reduction of one unit can correspond, for example, to the transformation of a triple bond into a double bond or of a double bond into a single bond or alternatively of the replacement of a halogen by a hydrogen.
• the database is preferably a relational database comprising a first entity in which information relating to the reaction patterns listed in the database is recorded, a second entity containing information relating to the state of the links of at least one pattern listed in the first entity, a third entity in which information associated with the various reaction media is recorded, and at least a fourth entity in which information related to the results of analysis of the reaction media is recorded after a reaction.
• a relational database comprising a first entity in which information relating to the reaction patterns listed in the database is recorded, a second entity containing information relating to the state of the links of at least one pattern listed in the first entity, a third entity in which information associated with the various reaction media is recorded, and at least a fourth entity in which information related to the results of analysis of the reaction media is recorded after a reaction.
• the database according to the invention can usefully be exploited according to a method making it possible to deliver at least one item of information relating to the reactivity of a catalyst with respect to the chemical transformation of at least one reaction unit.
• a further subject of the present invention is thus a method for constituting a database making it possible in particular to select at least one catalyst suitable for a reaction, comprising the following steps: a) preparing a plurality of different reaction media containing the same reactivity probe and each at least one catalyst, b) analyze, by an analytical method, each reaction medium after reaction, c) assign in the database to the reactivity probe a result of the analysis according to step b), this result characterizing different reaction products obtained from this probe, and having at least one of the following characteristics: the database is a relational database comprising a first entity in which information relating to the reaction patterns listed in the database is recorded , a second entity containing information relating to the state of the lia of at least one reaction motif listed in the first entity, a third entity in which
• the present invention also relates, according to one of its aspects, to a process for delivering at least one item of information relating to the reactivity of a catalyst with respect to a chemical transformation of at least one reaction unit, this process can be characterized in that it comprises at least the steps consisting in: x) acquiring data relating to said transformation and, where appropriate, to the structural environment of the reaction unit to be transformed, y) identify in a database providing information on the reactivity of a set of catalysts with respect to reaction units listed in the database and present on reactivity probes, at least one listed reaction unit related to the unit to transform, z) select from the database on the one hand on the basis of the listed reaction motif thus identified and on the other hand on the transformation to be carried out at least one catalyst having the reactivity required for the transformation.
• reaction unit related to the unit to be transformed it is to be understood that the reaction unit listed in the database is identical to the reaction unit to be transformed or sufficiently close in structural terms so that one can think that the catalyst which will be selected is useful for the transformation to be carried out. Its reactivity can be equivalent to that of the motif to be transformed and results in the expected chemical transformation or in an equivalent chemical transformation.
• structural environment is meant the environment resulting from the combination and the spatial arrangement of all the reaction units constituting the same molecular entity. The reactivity of a reaction unit is likely to vary significantly depending on whether or not it has other reaction units in its immediate structural environment.
• an ethylenic function depending on whether it is arranged at ⁇ of a ketone function or of a methylene unit, will not manifest the same degree of reactivity during a catalytic hydrogenation or nucleophilic addition reaction.
• the database may contain information which provides information on the influence of the structural environment of a listed reaction pattern.
• the membership of the reaction units listed in reactivity probes which may include several reaction units makes it possible to take into account, where appropriate, the “reaction influence” aspect for the selection of the catalysts, that is to say the influence undergone by a reaction motif in terms of reactivity, due to its associated structural environment.
• the aim of a reaction is to transform, assemble and / or dissociate one or more reaction units from a compound without, if necessary, modifying other units also present.
• the expressions “chemical transformation” and “Chemical reaction” includes not only so-called conventional chemistry, but also biochemistry, and the transformation or reaction can be biological.
• the reactions considered according to the invention can thus be acid catalytic reactions such as for example protection / deprotection reactions, basic catalytic reactions, metallocatalysed multicomponent reactions, trimerization reactions, for example heterocycle formation, pericyclic reactions , thermal and / or photocMrnic reactions.
• transformation is meant a reaction localized at the level of a reaction unit. This term encompasses any type of transformation, assembly or dissociation, insofar as it is localized at the level of a reaction motif.
• the transformation of a reaction unit can reside in the formation of a coupling of two identical or different reaction units.
• transformations liable to take place in a hydrogenation reaction By way of illustration of transformations liable to take place in a hydrogenation reaction, mention may in particular be made of the following transformations: reduction of imine to amine, cleavage of a CN or benzyl CO bond, reduction of a halide, of a nitro amino function, a nitrile amino, reduction of amide, reduction of an alkynic unit, reduction of a ketone to alcohol, reduction of a ketone to alkane and cutting of an ether unit.
• the acquisition in step x) can be, for example, input using a keyboard or a graphic tablet or the reception of data, for example a file. In what follows, the term entered or acquisition will be used independently.
• the data entry in step x) above may include the formulation of a request mentioning the reaction reason concerned and the nature of the transformation which it is desired to undergo.
• the transformation can be formulated using the name of the transformation, for example by selecting it from a list on a drop-down menu.
• the transformation can also be formulated by indicating the variation in the state of the bonds of the functional groups to be transformed or to be preserved at the level of each reaction unit resulting from the transformation or the difference in the state of the bonds in the reaction unit considered between the states before and after transformation.
• data entry may include the formulation of a request concerning the transformation and / or non-transformation of at least two different reaction patterns.
• the request may aim to select a catalyst capable of transform the first motif with sufficient yield while leaving the second intact, or at the very least transform it sufficiently.
• the data entry in step x) can also be done by formulating a transformation request for at least one starting compound.
• the process can include the analysis of the starting and ending compounds with a view to identifying the reactive unit (s) reacting and that or those not reacting. In view of this or these reactive and / or non-reactive reaction units, at least one new request relating to at least one reaction unit of the starting compound can be formulated.
• the method according to the invention may involve: - the decomposition of a starting compound involved in a reaction into different substructures, - the identification of the reaction unit (s) to be transformed and, where appropriate, - the identification of the reaction pattern (s) to be preserved.
• the input of the starting compound and the finishing compound can be carried out for example by drawing their structure, by giving their name or an identifier referring to their structure.
• the data entry in step x) can be done via a computer network, in particular the Internet or Intranet.
• reactivity probes can be more particularly adapted to a given type of reaction. At least some reaction data recorded in the database was acquired by reacting the reactivity probes.
• the latter have in their structure at least one reaction unit capable of being transformed according to a catalytic chemical reaction, this reaction unit being for example chosen from those mentioned above.
• Reactivity probes can be natural or synthetic. They may in particular be hydrocarbon molecules of low mass and which may comprise from 10 to 30 carbon atoms. They can be saturated or unsaturated, linear or branched.
• each reactivity probe comprises at least one reaction motif in a specific structural environment. They advantageously include at least two different reaction units or at least three reaction units including at least two different units or at least four reaction units, including at least two, or even at least three different units.
• the presence of several reaction units on the same reactivity probe can make it possible to increase the number of reaction data acquired with each test of transformation of the probe in a given reaction medium. This allows the database to be filled more quickly.
• the presence of several reaction units can make it possible to demonstrate, if necessary, the influence of the structural environment.
• the reactivity probes used can be more particularly adapted to a given type of reaction. For example for catalytic hydrogenation or other reactions, the probes can for example have at least one reaction unit chosen from the following units: ⁇ / ⁇ ⁇
• This strongly reactive motif can be associated with at least one second motif, or even two other motifs, known on the other hand for a lower reactivity according to this same reaction, for example an aromatic nucleus or the nitrile function of a heterocycle.
• a given reactivity probe it will be these less reactive patterns and their spatial arrangement which will constitute the structural environment associated with the most reactive reaction pattern.
• the number of probes is preferably chosen so as to represent all of the chemical transformations likely to occur in a given reaction.
• For example, for a hydrogenation can be represented through these probes the different possibilities of hydrocarbon unsaturation, aromatic or non-aromatic, the different carboxylated functions COOH, CHO, CO, CONH 2 , the carboimine functions, ...
• reactivity probes suitable for the invention for example for the evaluation of the reactivity of a set of catalysts vis-à-vis a hydrogenation reaction, mention may in particular be made of those having the structures shown below below:
• the database can also contain information, associated with each catalyst and / or reaction motif listed, which can be very diverse and in particular the database can contain data which provide information on the activity of at least some of the catalysts listed for different reaction conditions, in particular the temperature of the reaction medium, the acidity, the pressure, the presence of solvents, the analysis method, etc.
• the database can be loaded on a computer server where the connect computers, for example a personal computer, laptop or desktop. The data can be saved on a computer medium.
• the present invention also relates, according to another aspect, to a method of supplying at least one catalyst which can be used to transform at least one reaction unit of at least one compound according to a given chemical reaction, characterized in that it comprises, in addition steps x), y) and z) defined previously at least one step of supplying the catalyst (s) thus selected.
• This supply step may, if appropriate, include a step of manufacturing said catalyst.
• the present invention also relates, according to another of its aspects, to a computer system which can be characterized in that it comprises means for: i) make it possible to formulate at least one request concerning a chemical transformation transforming at least one reaction unit of at least one compound, ⁇ ) identify, in a database providing information on the reactivity of a set of catalysts vis-à-vis of reaction units listed in the database, a listed reaction unit having a relationship with the motif to be transformed, ⁇ i) select according to the listed reaction motif thus identified in the database and of the transformation to be carried out at least one catalyst having the reactivity required for the transformation and editing this catalyst.
• editing is meant to display, print, save to a file, transmit remotely or deliver.
• the invention also relates to a method for selecting at least one catalyst which can be used for a given reaction, characterized in that the catalyst is selected as a function of the production yield of the reaction products assigned to at least one reactivity probe present in the database and transformed according to said reaction.
• the catalysts listed in the database can be of chemical, organic or inorganic nature, and in particular of organometallic nature, or even biological like proteins, cells or enzymes. In this case, it can be all the catalysts which can be used in homogeneous or heterogeneous organic synthesis.
• the chemical conversion catalysts comprise most of the elements of the periodic table and are generally solid under the usual reaction conditions.
• catalysts based on bismuth, tin, nickel, palladium, antimony, ruthenium, titanium, zirconium, iridium, copper, cobalt, rhodium, platinum and rare earths. These catalysts can be tested individually or in the form of combinations. These catalysts can also be in a supported form.
• the type of support can be chosen from inert clays, zeolites, ceramics, carbon or an inert organic material. It can also be metallic oxides like Al 2 O 3 .
• These supports can be implemented in various solid forms such as, for example, honeycombs, particles or networks.
• catalysts By way of nonlimiting illustration of the catalysts according to the invention, mention may in particular be made of the following catalysts: Pd / Al 2 0 3 ; Pd / BaSO 4 ; Pd CaC0 3 ; Pd / PEI; Pd / CaC0 3 , Pd / C; Pt / C; Ru / C; Re / C; Rh / C; Rh / Al 2 0 3 ; Ir / C; Ir / CaC0 3 .
• the catalysts may or may not be specialized with respect to a biological or chemical reaction, for example a hydrogenation reaction. The reactivity of the catalysts can be assessed in terms of yield and / or selectivity.
• this catalytic activity can also result in a lack of activity for the definite transformation of a reaction unit and be precisely advantageous in this respect.
• this reactivity can result in the manifestation of a particular selectivity at the level of the reaction.
• a catalyst is considered active, within the meaning of the present invention, when it makes it possible to carry out the chemical reaction considered with sufficient yield.
• the database can provide information on the reactivity of all the catalysts selected, with respect to the reactivity probes and the reaction patterns listed, for identical or different reaction conditions. This can make it possible to better appreciate the specificity of the catalysts and thus to optimize the knowledge of their performance in terms of efficiency and especially of selectivity.
• the reaction conditions can be those generally used for the chemical reaction considered.
• co-reactive denotes any compound which, by virtue of its presence in the reaction medium, is capable of participating in the reaction, for example carbon monoxide, and / or of affecting the yield and / or the selectivity of the reaction. . It may especially be an acidic, basic compound, a chelating metal.
• FIG. 1 schematically represents different entities of a database conforming to the invention
• - Figures 2 to 9 represent examples of database entities
• - Figures 10 to 12 schematically represent examples of chromatograms
• - Figure 13 represents a virtual chromatogram
• - Figure 14 is a example of algorithm for generating a virtual chromatogram
• - figure 15 represents an example of virtual chromatogram obtained during the execution of the algorithm of figure 14
• figure 16 schematically represents a computer system allowing to implement the invention
• - Figure 17 is a block diagram illustrating different steps of an example of implementation of the method according to the invention
• - Figures 18 and 19 illustrates nt an example of selection of reaction media following the formulation of a request.
• FIG. 1 illustrates a relational database 5 in accordance with the invention, of which entities 5a to 5g have been represented in a simplified manner.
• the database 5 can store information, for example in the form of tables made up of columns and rows.
• Partly represented in FIG. 2 is the entity 5a entitled “Compound” in which are recorded, for each compound listed in the base, and among which in particular appear the reactivity probes, reaction patterns, and the reaction products, an identifier "ID”, for example a number, the name "Name” of the compound, the reference “MOLE-ID” of a table generated by a commercial tool such as "Chem Draw” comprising the drawing, the molecular weight, the raw formula , etc ..., and if necessary the number of "NbrPartComp" connections that can be modified during reactions.
• ID for example a number, the name "Name” of the compound, the reference "MOLE-ID” of a table generated by a commercial tool such as "Chem Draw” comprising the drawing, the molecular weight
• the database 5 also includes an entity 5b entitled “Tbl PartComp” which contains information concerning the reactivity indices of each compound listed in the entity 5a.
• a large number of experiments is carried out to test the reactivity of the reactivity probes in predefined reaction media, and thus constitute the database 5 with useful information concerning the properties of the catalysts listed in the database with respect to reactivity probes.
• These experiments can be carried out for example according to a standardized procedure by means of plates, also called “blocks”, each comprising a plurality of wells, each plate being associated with a given reactivity probe, each well comprising a different reaction medium, ie that is to say comprising for example in addition to the reactivity probe a particular catalyst, particular co-reagents if necessary, specific solvents, etc.
• the entity 5c entitled “Mixture”, makes it possible to record in the base 5 the information associated with a given reaction medium.
• a primary key “ID” the identifier (s) “ID-Reactive” of the compound or compounds of the medium in which the reaction, each identifier being for example a number, the identifier “ID-Catalyst” of the catalyst used, this being for example also a number.
• the identifiers “ID-Reactive” and “ID-Catalyst” refer for example to compounds referenced in the “Name” column in the 5h “Reactive” and 5i “Catalyst” tables, partially represented in FIGS. 5 and 6.
• the base of data 5 further comprises “Chromato” 5d and “Signal” 5e entities, in which information related to the analysis is recorded chromatography of the reaction media of the plates.
• These entities 5d and 5e have been partially represented in FIGS. 7 and 8.
• the constituents of each well of a given plate are analyzed by liquid or gas chromatography and the entity "Chromato” makes it possible to store the information of each chromatographic injection which is the result of a reaction.
• FIGS. 10 to 12 show three examples of chromatograms obtained by reacting the same reactivity probe in three different reaction media, which made it possible to detect the presence of the compounds Ci to C 4 .
• the entity 5d for example, as can be seen on examining FIG.
• Entity 5e stores the information of a chromatographic signal, that is to say a chromatographic peak. In the entity 5e are recorded for example, as can be seen on examining FIG.
• Entities 5d and 5e can be loaded automatically from at least one result file automatically generated by the chromatograph. Such a file can for example be in the form of the “Result” table partially represented in FIG. 9.
• This table comprises a “Number” column which includes the number of the rows of the table, and seven fields in which are recorded respectively, for field 1, the name of the reagents, for field 2 the serial number of the signal in the chromatogram, for field 3 the retention time, for field 4 the area of the signal, for field 5 the catalyst and the name of the analysis, for field 6 the number of the analysis and for field 7 the yield
• To calculate the yield we first calculate the sum S of the areas shown in the column of field 4 and corresponding to the same analysis, that is to say having the same analysis number in field 6. Then, for a given line, the value carried in the column of field 7 is equal to 100 times that carried in the column in field 4, divided by S. No yield calculation is carried out when the values appearing in the column in field 3 are zero.
• the 5d entity can be loaded automatically from the "Result" file.
• the identifier “ID” is automatically incremented with each new analysis recorded in the database, the column “Type of Chromato” can be filled in with the data appearing in field 5 of the table “Result”, the column “Date of injection ”Can be taken equal to the current date and the number entered in the“ ID-Mixture ”column is obtained by processing fields 1 and 5.
• The“ Program ”and“ ID-Compound ”columns of entity 5d can be fulfilled during the preparation of the plates.
• the entity 5e can also be filled in automatically, the identifier “TD-Signal” being for example a number incremented automatically with each new analysis recorded in the base, the identifier “ID-Chromato” is taken equal to the number “ ID ”of the last analysis processed, the“ Retention Time ”column is filled in from the data in field 3 of the“ Result ”table, as well as the“ Surface ”column which corresponds to field 4 of the result table and the column “Yield” in field 7 of the “Result” table.
• Concerning the filling of the column “ID-Compound” of the entity 5e that is to say the attribution to each signal of the chromatogram of a chemical compound, one can proceed as follows.
• All the signals obtained with the same analytical method that is to say having the same number in the "Program” column of the 5d entity and the same reactivity probe, that is to say the same number in the “ID-Compound” column of entity 5d can be assigned to a virtual chromatogram which would have been obtained by a fictitious experiment giving all the transformation products of a given reactivity probe at once.
• the virtual chromatogram is advantageous in that it makes it possible to automatically assign a compound to each peak on a large number of signals. Once all the signals of this virtual chromatogram of the determined compounds are associated, any corresponding signal obtained with the same analytical method can be assigned the corresponding compound.
• FIG. 13 A very schematic example of a virtual chromatogram, constructed from the signals of the chromatograms of FIGS. 10 to 12, has been represented in FIG. 13. We will now describe an example of a process making it possible to generate such a virtual chromatogram. First, a first list A is generated from the data of the entities
• a third list C of all the signals present in all the analyzes of list A is established and the virtual chromatogram is generated by completing list B according to the algorithm of FIG. 14.
• This algorithm is implemented with a value given for the minimum duration T m tolerated between two signals to consider them as distinct.
• a low value of T m results in a chromatogram with many signals while a value high generates a chromatogram with few signals.
• T m is for example equal to 0.2 min.
• the signals of list C are read sequentially and a retention time variable Ti is initialized to 0.
• step 51 For each signal W of list C thus read, of retention time T c , there a in step 51 sequential reading of the signals of list B, with each signal X of this list being associated with a retention time T b .
• step 52 it is determined whether the retention time T c of the signal W of the list C during reading is greater than Ti and less than the retention time T of the signal X of the list B during playback. reading minus T m . If not, we go to step 53 during which we assign the value T b + T m to the variable Ti and we read the next signal X from list B, with corresponding retention time T b . Then, at step 54, if the list B is not finished, we return to step 52.
• step 52 If at step 52 the retention time T c is greater than Ti and the retention time T c is less than Tb - T m , which corresponds for example to the situation in FIG. 17, we go to step 55 during which we check that the list B is not finished or that T c and greater than Ti. If so, in step 56, we add the peak W to list B and we sort the latter again. Then, in step 57, we pass to the reading of the next signal W of the list C, of corresponding retention time T c and ⁇ is initialized in O. In the next step 58, we verify that the list C n is not finished and if this is the case, we return to step 51. If the test is negative in step 55, we go directly to step 57.
• a time range of retention can be attributed to each compound, by taking for example as lower limit of each range half of the sum of the times of retention of the peak concerned and that which precedes it.
• a range 60 of provisional time which, in the case of FIG. 10, is centered on the top of the peak concerned and whose extent time on either side of the peak peak corresponds to the minimum duration T m tolerated between two signals.
• a method according to the invention is advantageously implemented by means of a computer system which may include, as illustrated in FIG. 16, a computer server 1 connected by a network 2 to a user terminal 3.
• the network 2 is for example an Intranet or Internet network.
• the computer server 1 can also be connected to a data acquisition system 4, this system being able to comprise a manipulator arm and an analysis apparatus such as for example a gas or liquid chromatograph. This analysis device provides data on each reaction medium after reaction, as will be explained below.
• the computer server 1 includes or can access conventional data storage means and in particular may be able to communicate with other computers, via the network 2 or through other networks.
• the terminal 3 is for example a PC type computer connected by a telephone or other link to the network 2.
• the server 1 is arranged to allow in a first step 6, as illustrated in FIG.
• FIG. 18 shows an extract from a data field coming from database 5, each row of which contains information concerning the transformation yield of two reaction patterns whose names are given in the columns entitled “1 st Functional group "and” 2nd functional group "in the presence of a reaction medium, the identifier of which is given in the column entitled " Middle ". On either side of the name of the reaction motif are indicated the state of the bonds.
• the same number to the left and to the right of the name of the reaction motif means that it has not changed. Decreasing by one means, for example, that there has been a reduction.
• the number 2 indicates for example that the reaction unit is still liable to undergo a reduction.
• the number 0 indicates, for example, that the bond has been broken and therefore that the reaction unit is no longer liable to undergo a further reduction step.
• the number 1 indicates that the compound is capable of being transformed and in particular reduced depending on the nature of the bond.
• the reaction motif "Arylketone" did not react and that the reaction motif "1-Alkylalcen" reacted only very weakly, since this reaction unit remained unchanged with a yield of 99.4%.
• reaction unit "Aryliodim” was reduced with a yield of 5.28%, the iodine having been replaced by hydrogen.
• a request concerning two reaction units present within the same reaction medium can be formulated, indicating for each reaction unit whether it is desired that this react or not.
• the request can for example be formulated so as to seek the reaction media which allow the reduction of a reaction motif "Arylbromide” without reducing a reaction motif "Arylketone".
• FIG. 19 shows two result lines corresponding to this query.
• the reaction media 356 and 391 allow the reduction of the “Arylbromim” motif, since the reactivity index has gone from 1 to 0, while leaving the “Arylketone” reactive motif unchanged, entirely for the reaction medium 356 and with a yield of 96.36% for the reaction medium 391.
• Knowledge of the reaction medium makes it possible to go back to the catalyst present in it.
• the data acquisition in step 6 can be done for example by the terminal 3 after connection to the server 1 and identification, if necessary, of the user by an access code.
• the user can himself be a computer system programmed to search for relevant information on a computer network.
• the reaction to be performed can be entered on a keyboard or by means of a mouse, for example on terminal 3, or in the form of an image file or the like, and the data entered may notably include the starting compound (s), and the desired compound (s) on arrival.
• the following step 7 may comprise the decomposition of the compounds involved in the reaction into reaction units and the identification of the reaction units which undergo a transformation and, if necessary, those which are preserved.
• This breakdown can be carried out automatically by a computer system and in particular the server 1, so as to allow the internal formulation of the computer system 6 of a request containing the identity of the reaction patterns concerned and for each of them, the variation the reactivity index, in order to obtain from the database the name (s) of the appropriate catalysts.
• the reaction is a hydrogenation of a compound of formula I as follows:
• the computer system can make it possible to identify two reaction units, namely an ethylenic bond and a carbon-bromine bond.
• Reaction patterns related to these, present on reactivity probes are listed in the database 5.
• the probe n ° 1 below comprises the reaction motif carbon bond - bromine and the probe n ° 2 the ethylenic bond reaction unit.
• probe n ° 2 Database 5 contains information on the reactivity of the listed catalysts, in particular the transformation yield, for each of the reaction patterns of the probe considered. For example, the reactivity of several catalysts with respect to the transformation of the reaction units was tested for each of the two probes, being reported below in Table I for the probe n ° 1 and in Table II for the probe n 2.
• the catalysts Pd C, Pt C, Pd / Al 2 0 3 , Pd / BaS0, Pd / CaCO 3 , Pd / CaC0 3 .Pb and Ir / CaC0 3 are effective in reducing the ethylenic bonding unit and the same Pd / C, Pd Al 2 O 3 , Pd BaSO 4 catalysts for the reduction of the carbon - bromine bond of the bromide motif.
• Table I (probe No. 1)
• Table II (probe No. 2)
• Table III shows a close correlation between the predictive reactivity data acquired using the reactivity probes and the reactivities verified experimentally by carrying out the hydrogenation of the compound of formula I with the seven catalysts identified above.
• the computer system 1 makes it possible to know the catalyst (s) capable of carrying out the desired transformations for the identified reaction units.
• a single effective catalyst can be edited depending for example on criteria such as the commercial availability of this catalyst or the cost of the catalyst. For example, if the catalysts Pd / Al 2 0 3 and Pd / C are suitable and only the catalyst Pd / Al 2 O 3 is available from a company questioned by the computer system, then only this catalyst is edited in response to the request made by a user.
• the catalyst can, if necessary, be addressed physically to the user, or even be produced on demand. If necessary, the catalyst can be addressed with special packaging to facilitate the carrying out of tests.
• the computer system can edit, in addition to the structure of the catalyst, its name, its cost, its efficiency, and its specificities in terms of selectivity.
• the responses to the requests formulated by the user are provided by the server 1, but it is not going beyond the scope of the present invention when the computer system is reduced to a single computer on which turned an application.
• the application can for example be downloaded from a remote site or present on a computer medium such as for example an optical disc and be loaded on the computer.

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• 2005
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