EP3043906A1 - Use of certain organic materials, containing alkali or alkaline-earth metals, for implementing organic chemical reactions - Google Patents

Abstract

The invention relates to the use of organic materials such as plants and sea or land animal shells containing alkali or alkaline-earth metals, preferably calcium, for implementing chemical reactions.

Description

 USE OF CERTAIN ORGANIC MATERIALS CONTAINING ALKALI OR ALKALINE-EARTH METALS FOR THE IMPLEMENTATION OF ORGANIC CHEMICAL REACTIONS

The invention relates to the use of materials of organic origin that is to say bio-based materials containing alkaline or alkaline-earthy, preferably calcium for the implementation of chemical reactions.

In the international application WO 2011/064462 and the application WO 2011/064487 published on June 3, 2011 is described and claimed the invention of Professor Grison and Dr. Escarré relating to the use of a calcined plant or a part of calcined plant having accumulated at least one metal in M (II) form chosen especially from zinc (Zn), nickel (Ni) or copper (Cu), for the preparation of a composition containing at least one metal catalyst whose metal is one of the aforesaid metals in M (II) form from said plant, said composition being free of chlorophyll, and allowing the implementation of organic synthesis reactions involving said catalyst.

WO 2011/064487 describes in particular the use of Thlaspi c erulescens now called Noccaea c erulescens and Anthyllis vulneraria as well as that of many other metallophyte plants hyperaccumulative heavy metals for the preparation of catalysts used in organic chemistry.

Thus, the invention described in WO 201 1/064487 relates to the use of a calcined plant or part of a calcined plant having accumulated at least one metal in M (II) form chosen especially from zinc ( Zn), nickel (Ni) or copper (Cu) in which said plant is chosen in particular from the family Brassicaceae, including species of the genus Thlaspi (noccacea) in particular T. goesingense, T. tatrense, T. rotundifolium, T. praecox, species of the genus Arabidopsis, in particular Arabidopsis hallerii, and of the genus Alyssum, in particular A. bertolonii, A. serpyllifolium, Fabaceae, Sapotaceae, in particular the species Sebertia acminata, Planchonella oxyedra, Convolvulaceae, in particular the species Ipomea alpina, Planchonella oxyedra, Rubiaceae, especially the species Psychotria douarrei, in particular P. costivenia, P. denmentis, P. vanhermanii, Cunoniaceae, especially the Geissois, Scrophulariaceae, in particular species of the genus Bacopa, in particular Bacopa monnieri, algae, in particular red algae, in particular rhodophytes, more particularly Rhodophyta bostrychia, green algae or brown algae.

As a result, plant waste is directly recovered and converted into "green" catalysts or unconventional reagents.

In the international patent application WO2013 / 150197 claiming the priority of the French patent application FR 2 987 759 filed on March 6, 2012, requests not yet published, Professor Grison and his team have shown that unexpectedly some other plants belonging to the Sedum genus, as well as a different plant, Potentilla griffithi, possess different properties of heavy metal hyperaccumulative metallophytes that make them particularly interesting for use in catalysis in organic chemistry.

The plants of the genus Sedum are succulent plants that belong to the crassulaceae family, composed of more than 400 species. They have natural abilities to grow on poor, dry, open soil and difficult conditions. Their foliar system is fleshy and their crops are well-off.

 Among them, three species have developed unusual properties for extracting zinc and cadmium. In particular, Sedum plumbizincicoica and Sedum jinianum have a remarkable ability to extract zinc from polluted soils in southern and eastern China. They have a real potential in phytoextraction and are called "plumbizincicolafor".

However, the application of extracts of these plants as catalysts had never been described before and is the subject of the French patent application FR 2 987 759 as well as the application PCTN ° WO2013 / 150197. PCT Application No. WO2013 / 150197 corresponding to the French patent application No. FR 2 987 759 also describes the preparation of basic catalysts from accumulating plants indicated above. Various basic catalysts have been prepared from oxides resulting from a heat treatment of biomass. The processes described have in common starting from metal oxides, prepared by metal storage plants via the drying and heat treatment steps to obtain a powder consisting mainly of oxides which after hydration give the desired basic catalysts which can be supported for example on silica or basic alumina.

Professor Grison's team has shown that hyperaccumulative transition metal plants such as zinc can be converted into basic catalysts. This property has been illustrated with Sedwn plumbinzicola. Results have been incorporated in PCTN application WO2013 / 150197 through Stetter-type isomerization and aldolization reactions allowing access to a green 1,4-dione. This led to the synthesis of hedione, and more generally to the generalization of the synthesis of cyclopentenones, campholenic aldehyde and its derivatives. In what follows, the term "catalyst" and the term "reagent" can be used interchangeably for each other. In other words, the alkali or alkaline earth metals according to the invention, and in particular calcium, used preferably in the form of salts or hydroxides can be used as reagents or as catalysts. Unless otherwise indicated, the catalysts or reagents used in the practice of the present invention are basic catalysts.

Professor Grison's team has now studied the activity of catalysts or basic reagents derived from materials of organic origin, that is to say from biosourced materials and in particular non-accumulators of transition metals, that is to say common plants, plants rich in calcium salts, in particular calcium oxalate and calcifying or non-calcifying algae but rich in calcium, and reagents derived from marine shells such as shells, oysters, mussels, holy shells - Jacques, crepidulae and other skeletons, shells or shells of non-marine molluscs such as snails, all these shells being rich in calcium carbonate.

Examples of such plants are illustrated in the table below.

C enopodïacées (eg, lamb's quarters, atriplex,

quinoa) brown algae:

 Lemnaceae (eg, duckweed); eg Padina

Berberidaceae (ex: mahonias)

Polygonaceae (ex: rhubarb, all the rumex, red algae:

knotweed) ex: Liagoraceae

 Plantaginaceae (eg large plantain) (Galaxaura / Dichotomaria);

Pontederiaceae. (ex: Pontederia cor data) Corallinaceae: (Amphiroa, Jania) Onagraceae (ex: Jussie creeping); (rhodoliths); Lithothamnium (or Portulacaceae (eg common purslane) lithothamne)

Agavaceae (ex: Yucca) Gigartinaceae

Moraceae (eg Lroko) (eg Chondrus crispus)

 Foams such as bryophyte foams:

Sphagnaceae (ex: Sphagnum or Sphagnum)

Mushrooms such as polypores:

Inonotus oblicuus (or chaga)

Lichens of the family Permaliaceae as

Xanthoparmelia conspera

 Non-calcifying algae but rich in Ca:

Brown algae such as the family Alariaceae: example Undaria pinnatifida (or sea fern), Alaria esculenta, Alaria marginata, Undaria distans, Laminaria digita, Laminaria saccharina

 - Red algae like the Palmariaies family: example Palmaria palmata, family of gigartinaceae example: Chondrus crispus, family of Bangiophyceae,

- Green algae: family of ulvaceae, example Ulva lactuca

Sea shells such as shells, oysters, mussels, scallops, crepidulae, skeletons, shells and other shells of non-marine molluscs such as snails, all of these shells being rich in calcium carbonate. The present invention therefore relates to the use as catalyst of materials of organic origin containing alkali or alkaline earth metals, preferably calcium for the implementation of organic synthesis reactions involving said basic catalyst. The present invention therefore also relates to the use as catalyst of materials of organic origin containing alkali or alkaline earth metals, preferably calcium and substantially free of transition metals, metalloids and post-transition metals for the implementation of organic synthesis reactions involving said catalyst. The post-transition metals also called poor metals constitute a metallic element of the block p in the periodic table. This block includes the following metals: Aluminum, Gallium, Indium, Tin, Thallium, Lead, Bismuth, Polonium, Flérovium.

The term catalyst employed can also be used in the reactive sense. Given the nature of the reactions implemented in the present invention, the two words can be used indifferently.

By basic catalysis is preferably meant the use of a catalyst such as the carbonate or oxide of an alkali or alkaline earth metal which is preferably calcium. The plants used in the practice of the invention according to the present application contain calcium in oxalate form. The heat treatment of calcium oxalate leads to calcium carbonate or calcium oxide depending on the temperature of the treatment carried out (see for example the preparation of catalysts A6a and A6b below). As noted below, calcifying algae and shells contain calcium carbonate. The present invention therefore also relates to the use of extracts of a plant or part of a plant, preferably a plant or part of a plant, an algae or a part of a plant. algae containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), in an amount preferably greater than 5000 ppm, more preferably greater than 50000 ppm by weight having optionally undergone a heat treatment for the preparation of a composition containing at least one basic metal catalyst for the implementation of organic synthesis reactions involving said basic catalyst,

The present invention therefore also relates to the use indicated above characterized in that the materials of organic origin come from a plant or a part of a plant, preferably a plant or a part of plant, an alga or a portion of alga containing an alkali metal or alkaline earth metal content, preferably calcium (Ca), in an amount preferably greater than 50000 ppm by weight, and substantially free of transitions, metalloids and post-transition metals, preferably containing less than 20000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd ), copper (Cu), palladium (Pd) and said optionally heat-treated materials, for the implementation of organic synthesis reactions involving said catalyst.

By plants are meant plants as well as lower plants such as algae, mushrooms, lichens, mosses and ferns.

The alkali metals can be preferably lithium, sodium or potassium, cesium. The alkaline earth metals are preferably selected from magnesium, calcium, or barium, more preferably magnesium or calcium, and more preferably still calcium.

The amount of alkali or alkaline earth metal present in the plants which are the subject of the invention is preferably greater than 5000 ppm, more preferably greater than 50000 ppm by weight. In some cases, this amount can reach 400000 ppm.

The metal levels expressed in ppm are calculated with respect to the total mass of plants having undergone dehydration and before possible heat treatment.

The procedure for the possible thermal treatment to which the extracts of a plant or a part of a plant, preferably a plant or part of a plant, an alga or a part of a plant, are possibly subjected seaweed is described in the application for International patent WO 2011/064487 as well as according to the examples provided below, it is possible for example to operate in a muffle furnace at a temperature of the order of 400 ° C. to 600 ° C., preferably of the order of 5G0 ° C.

It is also possible to operate at temperatures of the order of 500 ° to 600 ° C. to obtain the decomposition of calcium oxalate, which is generally of a basicity close to calcium carbonate.

It is also possible to operate at temperatures of the order of 1000.degree. C. to 1100.degree. C., especially when the source of alkaline metal, most preferably calcium (Ca), is a shellfish shell, in order to obtain the decomposition of calcium carbonate by calcium oxide.

The subject of the present invention is also the use after drying and / or grinding and thermal and / or chemical treatment of an extract of a plant or part of a plant of an alga or part of an algae comprising a high level of alkali or alkaline earth metal, preferably calcium (Ca), in an amount preferably greater than 5000 ppm by weight in the form of a salt such as a carbonate or oxalate for the preparation of a composition containing at least at least one basic metal catalyst, preferably in the form of oxide, salt, preferably carbonates, oxalate, or alkali or alkaline-earth metal hydroxide, preferably calcium (Ca) for carrying out reactions. organic synthesis involving said basic catalyst.

 As indicated above, the invention is implemented with plants rich in calcium. These plants are particularly rich in calcium oxalate whereas the calcifying algae do not contain calcium oxalate but calcium carbonate.

Mention may also be made of other calcium salts than carbonate and oxalate and which are present in the abovementioned plants or other plants, namely phosphates such as phytate, simple carboxylates such as citrate, or carboxylates. osteoids such as uronates of the alginate or polygalacturonate type. The steps of drying and / or grinding can also be carried out according to the indications of the aforementioned international patent application WO 2011/064487 as well as according to the examples provided below. The grinding can be carried out in demineralized water.

The subject of the present invention is also the use after drying and / or grinding and thermal and / or chemical treatment of an extract of a plant or part of a plant comprising a high level of calcium (Ca), in a quantity preferably greater than 5000 ppm by weight, in salt form such as calcium carbonate or oxalate, for the preparation of a composition containing at least one basic metal catalyst in the form of calcium oxide, calcium salt selected from oxalate, carbonate, phosphates such as phytate, simple carboxylates such as citrate or osodic carboxylates such as uronates of alginate or polygalacturonates type, or calcium hydroxide for the implementation of reactions organic synthesis involving said basic catalyst.

Said compositions contain a low percentage of plant material, especially after filtration on sintered glass. The subject of the present invention is also the use of a composition prepared by drying and / or grinding and by thermal and / or chemical treatment of an extract of a plant or part of a plant comprising a high level of calcium (Ca), in an amount preferably greater than 5000 ppm by weight, in salt form such as calcium carbonate or oxalate and containing at least one basic metal catalyst in the form of calcium oxide, salt such as calcium oxalate, or calcium hydroxide, for the implementation of organic synthesis reactions involving said basic catalyst.

The subject of the present invention is also the use as defined above, characterized in that the possible chemical treatment or treatments to which the plant or part of a plant extract is subjected is either a hydration reaction by the water of the oxides obtained by heat treatment is a reaction with an inorganic or organic acid, preferably hydrochloric acid followed by a treatment with a base strong, preferably sodium hydroxide at a pH greater than 12 oxides obtained by heat treatment or salts obtained by drying and / or grinding.

The subject of the present invention is also the use as defined above, characterized in that the materials of organic origin are extracts of a vegetable or part of a vegetable, preferably a plant or a plant. part of a plant, algae or part of algae containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), in an amount preferably greater than 5000 ppm, more preferably greater than 50000 ppm by weight, having optionally undergone a heat treatment, for the implementation of organic synthesis reactions involving said basic catalyst.

The subject of the present invention is also the use as defined above, characterized in that the materials of organic origin are marine shells or shells of non-marine molluscs, said shells containing a high level of alkali metal or alkaline metal. earth, preferably calcium (Ca), preferably in the form of calcium carbonate, in an amount preferably greater than 80%, more preferably greater than 90% by weight, said shells having optionally undergone grinding and / or heat treatment for the implementation of organic synthesis reactions involving said basic catalyst.

The subject of the present invention is also the use as defined above, characterized in that the basic catalyst is an extract of a plant or a plant layer of an alga or part of an alga comprising a high level of alkali or alkaline earth metal, preferably calcium (Ca), in an amount preferably greater than 50000 ppm by weight and containing less than 10000 ppm of metals selected from zinc (Zn), nickel (Ni), Manganese (Mn) Lead (Pb), cadmium (Cd), copper (Cu), palladium (Pd) or marine shells or shells of non-marine molluscs containing a high level of alkali or alkaline earth metal , preferably calcium (Ca), preferably in the form of calcium carbonate, in an amount preferably greater than 80%, more preferably greater than 90% by weight, after drying and / or grinding and / or heat treatment and / or chemical, said catalyst being in oxide form calcium, calcium salt preferably from carbonate, of oxalate, or of alkali or alkaline-earth metal hydroxide, preferably calcium (Ca), for carrying out organic synthesis reactions involving said basic catalyst. The subject of the present invention is also the use as defined above, characterized in that the basic catalyst is an extract of a plant or part of a plant comprising a high level of calcium (Ca), in a quantity of preferably greater than 50000 ppm, and containing less than 10000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd), Copper (Cu) , palladium (Pd) or marine shells or shells of non-marine molluscs containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, preferably greater than 80%, more preferably greater than 90% by weight, optionally after drying and / or grinding and heat treatment and / or chemical said catalyst being in the form of calcium oxide, calcium salt selected from oxalate, carbonate, phosphates te as phytate, simple carboxylates such as citrate, or osodic carboxylates such as alginate or polygalacturonates uronates or calcium hydroxide for the implementation of organic synthesis reactions involving said basic catalyst.

The subject of the present invention is also the use as defined above as a catalyst of an extract of a plant or part of a plant of an alga or part of an alga comprising a significant amount of calcium (Ca), in an amount preferably greater than 50000 ppm and containing less than 10000 ppm by weight of metals selected from zinc (Zn), nickel (Ni), manganese (Mn) lead (Pb), cadmium (Cd), copper (Cu), palladium (Pd) prepared by drying and / or grinding and by heat treatment and / or chemical said catalyst being in salt form such as carbonate, or calcium oxalate, under form of calcium oxide or calcium hydroxide, for the implementation of organic synthesis reactions involving said basic catalyst. By extract is meant a product derived from or derived from a plant of an algae or shell.

The subject of the present invention is also the use as defined above as a catalyst for marine shells or shells of non-marine molluscs containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, in an amount preferably greater than 80%, more preferably greater than 90% by weight, after optional grinding and / or heat treatment and / or chemical said catalyst being in the form of calcium oxide, salt calcium chosen from oxalate, carbonate, simple carboxylates such as citrate, or osodic carboxylates such as uronates of the alginate or polygalacturonate type or of calcium hydroxide for the implementation of organic synthesis reactions involving said basic catalyst.

The subject of the present invention is also the use as defined above, characterized in that the possible chemical treatment or treatments to which the plant or part of a plant extract, marine shells or non-marine shellfish shells are subjected to either a hydration reaction with water of the oxides obtained by thermal treatment or a reaction with a mineral or organic acid, preferably hydrochloric acid followed by a treatment with a strong base, preferably sodium hydroxide solution. pH greater than 12 oxides obtained by heat treatment or salts obtained by drying and / or grinding.

As indicated below, the optional treatment with water is preferably carried out with stirring. The chemical treatment is preferably carried out with a mineral or organic acid such as hydrochloric acid, sulfuric acid or acetic acid, preferably hydrochloric acid followed by a treatment with a strong base, preferably sodium hydroxide. pH greater than 12,

The present invention also relates to the use as described above and characterized in that the plant having a high level of alkali metal or preferably, calcium (Ca), in an amount preferably greater than 50000 ppm by weight, in salt form such that calcium carbonate or oxalate is a common plant naturally rich in carbonate or calcium oxalate, preferably calcium oxalate and containing less than 10000 ppm of metals selected from Zinc (Zn), 3rd Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd), Copper (Cu) ), palladium (Pd) or an alga selected from calcifying algae or non-calcifying algae, preferably calcifying algae.

The subject of the present invention is also the use as described above and characterized in that the plant comprising a high level of calcium (Ca), in an amount preferably greater than 5000 ppm by weight, in the form of a salt such as calcium oxalate is a plant chosen from:

^■ common plants and especially plants rich in calcium oxalates chosen from Liliaceae (such as dieffenbachia); Araceae (such as spotted arum); Amaryllidaceae (such as narcissus); the Chenopodiaceae (such as lamb's-quarters, atriplex, quinoa); Lemnaceae (such as duckweed); Berberidaceae (such as mahonias); Polygonaceae (such as rhubarb, all rumex, knotweed); Plantaginaceae (such as large plantain); the Pontederiaceae. (such as Pontederia cordata); Onagraceae (such as Jussie creeping); Portulacaceae (such as common purslane); the Agavaceae (such as Yucca); Moraceae (such as Iroko)

^■ calcifying algae selected from

^■ green algae such as Halimeda (aragonite); Udotea

^■ brown algae such as Padina

^■ red algae such as Liagoraceae (Galaxaura / Dichotomaria) Corallinaceae: (Amphiroa, Jania) (rhodoliths); Lithothamnium

^■ non-calcifying algae chosen from

^■ brown algae such as those of the family Alariaceae including Undaria pinnatifida (or sea fern), Àlaria Esculenta, Alaria marginata, Undaria distans, Laminaria digita, Laminaria saccharina

^■ red algae such as those of the family

 Palmariales including almaria palmata, those of the family Gigartinaceae including Chondrus crispus, those of the family Bangiophyceae,

^■ green algae such as those of the family Ulvaceae including Ulva lactuca. The subject of the present invention is also the use as described above and characterized in that the plant comprising a high level of calcium (Ca), in an amount preferably greater than 50000 ppm by weight, in the form of a salt such as calcium oxalate or calcium carbonate is a plant selected from:

 - Chenopodiaceae, preferably Lamb's-quarters

- Plantaginaceae preferably large plantain

 - Portulacaceae the common purslane

 calcifying algae, preferably Lithothamnium.

The subject of the present invention is also the use as described above and characterized in that the plant comprising a high level of calcium (Ca), in an amount preferably greater than 50000 ppm by weight, in the form of a salt such as Calcium oxalate is a plant chosen from lamb's-quarters, large plantains, common purslanes or the algae called Lithothamnium. The shells are preferably chosen from molluscs, such as snails such as snails, crepidulae, bivalves such as oysters, scallops, mussels, scaphopods, polyplacophores and monoplacophores, cephalopods, with "Bone" cuttlefish or "feather" squid, egg shells, shells and skeletons such as echinids, cnidarians. The plant which is preferably used may for example be large plantain, rumex, sorrel, lamb's-quarters, corallinades, aragonite halimeda and seaweed, litriothamne.

Calcifying algae often have a significant amount of magnesium.

Non-calcifying algae may also contain a high level of calcium, for example of the order of 5000 to 100,000 ppm.

The shells that are preferably used are oyster shells and mussels that are easily accessible in large quantities.

The present invention also relates to the use as described above and characterized in that the materials of organic origin are marine shells such as shells, oysters, mussels, scallops, crepidulae , skeletons, shells and other shells of non-marine molluscs such as snails, containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, preferably in a higher amount at 80%, more preferably greater than 90% by weight for the implementation of organic synthesis reactions involving said basic catalyst.

The present invention also relates to a process for the preparation of a composition as described above and comprising a metallic agent consisting of at least one alkali metal or alkaline earth metal, preferably calcium (Ca), characterized in that it includes the following steps:

at. dehydration, preferably at room temperature or in an oven at a temperature of the order of 70 ° of the biomass comprising the leaves, stems and / or roots of a plant or a plant extract or a algae or a portion of alga having an alkali or alkaline earth metal content, preferably calcium (Ca), in an amount greater than 50000 ppm by weight in salt form such as carbonate or oxalate and substantially free transition metals, metalloids and posttransition metals, preferably containing less than 20,000 ppm of selected metals among Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd), Copper (Cu), Palladium (Pd) and / or b. Crushing of the dry biomass of a plant or a plant extract, an algae or a portion of algae obtained optionally after dehydration according to stage a)

 or

 vs. Crushing shells or fragments of shells of animal origin and, or

 d. Heat treatment of the biomass obtained in steps a) or b) in a furnace preferably in one or more steps preferably in one step at a temperature of the order of 400 ° C to 600 ° C, preferably of the order at 500 ° C for several hours, preferably for about 7 hours to obtain an alkali or alkaline earth metal salt, preferably calcium carbonate

 Or

 e. Heat treatment of the mass obtained in steps a) or b) or c) in a furnace preferably in one or more steps preferably in one step at about 1000 ° for several hours, preferably for about 7 hours to obtain an oxide of alkali or alkaline earth metal, preferably calcium oxide

and, if desired, the alkali metal or alkaline earth metal salts, preferably the calcium (Ca) or the oxides obtained respectively in stages d), and e) are subject to

 f. Or, for the oxides obtained in stage e) for hydration followed preferably by decantation, evaporation and drying at a temperature of the order of 80 ° C.

 boy Wut. Or for the salts, preferably the calcium carbonate obtained in stage d) for treatment with an inorganic or organic acid, preferably hydrochloric acid followed by a treatment with a strong base, preferably sodium hydroxide at a pH greater than 12, and if desired

the alkali or alkaline-earth metal salts, preferably calcium (Ca), obtained in stage d) and the alkali or alkaline earth metal hydroxides, preferably calcium (Ca), obtained in stages f) or g) are mixed together preferably by co-grinding with a support such as alumina, for example basic alumina, or hydrotalcite to obtain a supported catalyst.

Optional ultrasonic activation is performed by partial immersion of the reactor in an ultrasonic tank containing 0.1% aqueous solution of detergent. The sonication is maintained for about 15 minutes.

Sintered glass with a porosity of 0-1 (large pore size 100 to 250 microns) is placed on a vacuum flask using a rubber cone to seal. The filtration is carried out under reduced pressure using a water pump. Only chlorophyll plant residues are retained. However, if operating at temperatures of 1000 to 1100 °, there can no longer be chlorophyll residues and this step does not need to be performed.

Different inorganic supports can be used to support the catalyst and thus perform a supported catalysis. Typically, montmorillonite K10, silica, alumina or hydrotalcite have been used as support.

The catalysts on inorganic supports can preferably be prepared by co-grinding.

Catalysts on mineral substrates can be prepared as follows:

In a balloon provided with a magnetic bar, is introduced the inorganic support and then the catalyst preferably of type CAT Al or CAT A2. Water is then added and the resulting suspension is stirred at room temperature for 5 hours. This is then filtered, the solid is washed with distilled water, and this is collected for drying in an oven (120 ° C) overnight. Once its mass is stabilized, the resulting catalyst is stored in the desiccator. The catalyst may also be supported on mineral solids, in particular of natural or synthetic origin, such as hydrotalcite. This solid is used as a catalyst support prepared according to the following procedure: the hydrotalcite and the CAT Al or CAT A2 type catalyst are placed in a mortar. The mixture is co-worked at room temperature and then placed in an oven until it is used. However, the basic catalysts according to the present invention are preferably used without support.

The present invention also relates to a process as described above for the preparation of a composition comprising a metal agent consisting of at least one alkaline or alkaline earth metal, preferably calcium (Ca), characterized in that includes the following steps:

 a) dehydration, preferably at room temperature or in an oven at a temperature of the order of 70 ° of the biomass comprising the leaves, stems and / or roots of a plant or a plant or plant extract; an alga or part of an alga having an alkali or alkaline earth metal content, preferably calcium (Ca), in an amount greater than 50000 ppm by weight in the form of a salt such as a carbonate or an oxalate and substantially free of transition metals, metalloids and post-transition metals, preferably containing less than 20,000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb) , cadmium (Cd), copper (Cu), palladium (Pd) and / or b) grinding of biomass, including leaves, stems and / or roots of a plant or part of a plant , an alga or part of seaweed obtained optionally after dehydration according to stage a), and, if desired,

 c) ultrasonic activation or light heating at a temperature of the order of 60 ° C followed by removal of the plant part preferably on a sinter of high porosity of the ground mixture obtained in stages a) or b) and centrifugation or filtration

 and if desired,

d) treatment of salts such as an alkali metal or alkaline earth carbonate or oxalate, preferably calcium (Ca), obtained in steps a) b) or c) with an inorganic or organic acid, preferably hydrochloric acid followed by treatment with a strong base, preferably sodium hydroxide at a pH greater than 12, followed preferably by centrifugation or by filtration of the precipitated solid and if desired

 e) heat treatment of the biomass obtained in step a) or the ground mixture obtained in step b) in a furnace preferably in one or more steps preferably in a step at a temperature ranging from about 400 ° to about 1100 ° during several hours, preferably for about 7 hours

and, if desired, the alkali or alkaline earth metal oxides, preferably calcium (Ca), obtained in step e) are subject to

 f) Or to a hydration followed preferably of a decantation, an evaporation and a drying at a temperature of the order of 80 ° C g) Or treated by a mineral or organic acid preferably the hydrochloric acid followed by treatment with a strong base, preferably sodium hydroxide at a pH greater than 12, preferably followed by centrifugation or filtration of the precipitated solid,

 and, if desired,

 h) salts such as alkali or alkaline earth carbonate or oxalate, preferably calcium (Ca), obtained in steps a) b) or c) alkali or alkaline earth oxides, preferably calcium (Ca), obtained in stage e) and the alkali or alkaline earth metal hydroxides, preferably calcium (Ca), obtained in stages d), f) or g) are mixed, preferably by co-grinding with a support such as alumina, for example basic alumina, silica, zeolites, for example montmorillonite, or hydrotalcite to obtain a supported catalyst.

The present invention also relates to a process for preparing a catalyst comprising a metal agent consisting of at least one alkali metal or alkaline earth metal, preferably calcium (Ca), characterized in that it comprises the following steps:

a) Grinding of marine shells or shells of non-marine molluscs containing a significant level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, in an amount preferably greater than 80% more preferably greater than 90% by weight

and or b) heat treatment of marine shells or shells of non-marine molluscs containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, preferably in excess of 80 %, more preferably greater than 90% by weight or the ground biomass obtained in stage a), in a furnace preferably in one or more steps preferably in one step at about 1000 to 1100 ° for several hours, preferably for about 7 hours

 and if desired

 c) ultrasonic activation or light heating at a temperature of the order of 60 ° C followed by removal of the plant part preferably on a sinter of high porosity of the ground mixture obtained in steps a) or b) and a centrifugation or filtration

 and if desired,

 d) treatment of salts such as an oxalate, an alkali metal or alkaline earth metal carbonate, preferably calcium (Ca), obtained in steps a) b) or c) with an inorganic or organic acid, preferably hydrochloric acid followed by a treatment with a strong base, preferably sodium hydroxide at a pH greater than 12, followed preferably by centrifugation or filtration of the precipitated solid and, if desired, the alkali metal oxides or alkaline earth metal oxides preferably calcium (Ca), obtained in stage b) are subject to

e) either to a hydration preferably with water, followed preferably by decantation, evaporation and drying at a temperature of the order of 80 ° C. f) or else treated with a mineral acid or organic, preferably hydrochloric acid followed by a treatment with a strong base, preferably sodium hydroxide at a pH greater than 12, followed preferably by centrifugation or filtration of the precipitated solid

 And, if desired,

g) salts such as an alkali metal or alkaline earth metal carbonate, preferably calcium (Ca), obtained in steps a) b) or c) alkali or alkaline earth metal oxides, preferably calcium (Ca) , obtained in stage b) and the alkali metal or alkaline earth metal hydroxides, preferably calcium (Ca), obtained in stages d), f) or g) are mixed, preferably by co-grinding with a support such as alumina for example, basic alumina, silica, zeolites, for example montmorillonite, or hydrotalcite to obtain a supported catalyst.

The subject of the present invention is also a process as described above for the preparation of a composition comprising a metal agent consisting of at least one alkaline or alkaline earth metal, preferably calcium (Ca), characterized in that includes the following steps:

 a) dehydration, preferably at room temperature or in an oven at a temperature of the order of 70 ° of the biomass comprising the leaves, stems and / or roots of a plant or a plant or plant extract; an algae or a portion of alga having a high level of alkali or alkaline earth metal, preferably calcium (Ca), in an amount preferably greater than 50000 ppm by weight in the form of a salt such as a carbonate or an oxalate and substantially free of transition metals, metalloids and post-transition metals, preferably containing less than 20,000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), cadmium (Cd) copper (Cu), palladium (Pd)

 and or

 b) Crushing of the dry biomass of a plant or a plant extract, an algae or a part of seaweed obtained, if appropriate, after dehydration according to stage a)

 And if desired

 c) Ultrasonic activation or light heating followed by removal of the plant part preferably on a high porosity sinter of the ground mixture obtained in stage a) or b) and centrifugation or filtration

 and, if desired, salts such as an alkaline or alkaline earth metal carbonate or oxalate, preferably calcium (Ca), obtained in steps a), b) or c) are subjected to:

 d) a treatment with a mineral or organic acid, preferably hydrochloric acid followed by treatment with a strong base, preferably sodium hydroxide at a pH greater than 12,

and, if desired, e) salts such as an alkali metal or alkaline earth carbonate or oxalate, preferably calcium (Ca), obtained in steps a) b) or c) and alkali or alkaline earth metal hydroxides preferably calcium (Ca), obtained in stage d) are mixed, preferably by co-grinding with a support such as alumina, for example basic alumina, zeolites for example montmorillonite, silica or hydrotalcite to obtain a supported catalyst,

The present invention also relates to a process as described above for the preparation of a composition comprising a metal agent consisting of at least one alkaline or alkaline earth metal, preferably calcium (Ca) from the leaves, stems and / or roots of a plant or a plant extract or an algae or a portion of alga having a high level of alkali or alkaline earth metal, preferably calcium (Ca), in preferably in excess of 50000 ppm by weight in salt form such as carbonate or oxalate and substantially free of transition metals, metalloids and post-transition metals, preferably containing less than 20000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd) characterized in that it comprises, before the heat treatment of the mass obtained in stages a) or b ) a step of extracting the chlorophyll with the aid an organic solvent, preferably acetone, ethanol or isopropanol.

The present invention also relates to a process as described above characterized in that the plant having a high level of calcium (Ca), in an amount preferably greater than 5000 ppm by weight, in the form of a salt such as 1 Oxalate Calcium is a plant chosen from:

^■ common plants and especially plants rich in calcium oxalates chosen from Liliaceae (such as dieffenbachia); Araceae (such as spotted arum); Amaryllidaceae (such as narcissus); the Chenopodiaceae (such as lamb's-quarters, atriplex, quinoa); Lemnaceae (such as duckweed); Berberidaceae (such as mahonias); Polygonaceae (such as rhubarb, all rumex, knotweed); Plantaginaceae (such as large plantain); the Pontederiaceae. (such as Pontederia cordata); the Onagraceae (such as Jussie creeping) Portulacaceae (such as common purslane); the Agavaceae (such as Yucca); Moraceae (such as Iroko)

^■ calcifying algae selected from

 ■ green algae such as Halimeda (aragonite); Udotea ■ brown algae such as Padina

^■ red algae such as Liagoraceae

 (Galaxaura / Dichotomaria); Corallinaceae: (Amphiroa, Jania) (rhodoliths); Lithothamnium.

The dry extracts derived from the above-mentioned plants and algae are readily converted into basic biobased catalysts according to various possible protocols.

The process for preparing the basic biobased catalysts is preferably carried out according to the following methods:

- Case of type A plant species: common plants and rich in calcium oxalates

1. Metal carbonates can be obtained from ashes derived from the aforementioned species and then used directly supported or not: cat Al;

 - 2. The metal hydroxides can be generated by hydration of the oxides, then used supported or not; (The supports may be basic alumina, silica, zeolites, hydrotalcite): cat A2;

3. The metal hydroxides can be generated from successive ash treatments: treatment with an inorganic or organic acid (HCl or H ₂ SO ₄ ), recovery with sodium hydroxide at controlled pH (pH = 13), centrifugation and drying at 60 ° C. ° C: cat A3;

 4. If type A species are rich in calcium oxalate, heat treatment is not necessary to isolate it. The insolubility of calcium oxalate in water is used to isolate quickly and easily a white solid very rich in Ca.

This solid consisting of oxalate is then subjected to a heat treatment to obtain the catalyst consisting of carbonate or calcium oxide depending on the temperature at which the oxalate: cat A4 is subjected. Case of type B species: for algae

The calcifying algae are dried and finely ground. Calcium carbonate is obtained which can be subjected to a heat treatment of the order of 1000 ° to obtain calcium oxide: cat B.

All of these biosourced catalysts, easy to access and easy to use, are excellent substitutes for corrosive bases, of dangerous use and avoid any reaction treatment. They are removed by simple filtration of the reaction medium and treatment with oxalic acid if necessary. This simplicity of process contrasts with the conventional use of pure and commercial calcium hydroxide, which is presented as a solid difficult to handle in a protic medium. It is then presented as a viscous, sticky product whose texture and specific surface are unsuitable for such processes. The polymetallic nature of the medium gives the solid a finely divided, easily handled and reactive solid appearance. It is due to the presence of cations of physiological origin (enzymatic cofactors, magnesium derived from chlorophyll, phosphates ...) which allow a very good dispersion of calcium.

Experimental part: preparation of catalysts

Description of the different processes:

CAT Al: 420 g of dehydrated samples of plants rich in Ca are burned in a muffle furnace at 50 ° C. for 7 hours. 183 g of a solid rich in metal carbonates are obtained. Supported CAT Al: 1.7 g of a solid rich in metal carbonates are co-milled with 5 g of support (eg basic alumina, montmorillonite), then activated by heating for 15 minutes at 150 ° C.

The carbonate-rich solid also includes other anions, especially phosphates. - CAT A2: 10 g of metal carbonates from the previous heat treatment are introduced into a beaker and watered with stirring water. 30 ml of water are added. A gray suspension is obtained; agitation is maintained lh.

 After decantation, the pH is 10. The medium is concentrated in a rotary evaporator, oven-dried at 80 ° C. 10.1 g of a gray powder are obtained.

CAT A2 supported: 1.7 g of metal carbonates are co-milled with 5 g of support (eg basic alumina), then activated by heating for 15 minutes at 150 ° C. - CAT A3: 10 g of CAT Al are introduced into a 250 ml flask with 50 ml of 12M HCl are added with stirring. The solution obtained is filtered on celite. After evaporation and concentration, 4.9 g of a solid is collected and dried at 80 ° C. 3 g of the above solid are dissolved in 70 ml of distilled water with a few drops of HCl to promote complete dissolution. The precipitation of the metal hydroxides is carried out by adding a concentrated sodium hydroxide solution up to pH =

13. The white suspension obtained. It is centrifuged. 2.7 g of solid are obtained and stored in an oven.

- CAT A4: 50g of leaves are cut, crushed in demineralised water.

 After an ultrasonic activation or a slight heating, the plant part is eliminated using a sinter of high porosity (size 1). The residual aqueous phase is centrifuged. The solid residue, rich in calcium oxalate, is treated as in 3 (heat treatment of plantain at 1000 ° C which leads to a composition close to cat A3).

Typical compositions are presented below depending on the origin of the natural species. They were analyzed by ICP MS. The results are expressed in mass percentages. In the table below and in the following tables, only the content of metal cations of interest is indicated. The content of anions (in particular oxalates, carbonates or phosphates) does not appear in this table. The sum of the percentages is therefore less than 100%.

The 13.9 indication for calcium means that the sample analyzed contains 13.9 g of calcium per 100 g of total mass. Ca Mg Zn PS Mn Se K Na Cu Fe

% mass

 Cat A3

 Derived from Plants

 common 13.9 1.6 0.4 0.3 3 - - 21.0 - 0.0 0.2 Ex: large

 plantain

 Cat B

 Algae Derivative 34.1 3.5 0.06 0.4 0.17 4.8 0.01 2 3.7 0.01 - Calcifying

 Ex: Lithothamne

These novel catalysts have been tested in various reactions such as: isomerization, chemoselective hydrolysis of acid-derived functions, controlled esterification, alkylation, elimination, aldolization and related reactions, carbonylation reactions. The initial hypothesis is verified: some of these reactions are possible without a transition metal (eg isomerizations, chemoselective hydrolysis, controlled esterification, intramolecular and intermolecular aldolizations, alkylation, elimination, carbonylation). These results are very important from an industrial point of view, because they make it possible to extend the field of biosourced catalysts to very readily available raw materials; finally, the protocols are very simple to implement.

The basic entity may be an oxide, a carbonate or preferably a hydroxide of alkaline and especially alkaline earth derivatives. It can be supported or not.

CAT A5: The catalyst derived from oyster shells is prepared as follows:

The shells are directly placed in a calciner. It is heated to 1000 ° C for about 7 hours. The resulting powder, very rich in calcium oxide, is stored under an inert atmosphere, or used directly. In this case, it is rehydrated by progressive additions to the water. The pH is then about 12. The aqueous phase obtained may constitute the reaction medium or undergo the liltration / drying sequence in an oven. In this case, the solid obtained can be used as a catalyst or reagent in another medium, such as an ethanolic medium. Mass% Ca Mg Zn Mn PS Se Na Cu Fe

Cat AS

 51.2 0.7 0.07

 Derived from oysters 0.1 0.02 - - 0.08 1.09 0.0 2.3

CAT A6: 95g of fresh plantain, washed and drained are placed in an IL flask containing 500 mL of ethanol. The mixture is refluxed for 1 hour with mechanical stirring. The solution is filtered and the residual solid dried under reduced pressure at 100 ° C.

 90 g of plant material are treated at 500 ° C for 7 hours to obtain 7.70 g of a residue rich in metal carbonates, called CAT A6a.

 If the 90g of plant material are treated at 1000 ° C for 7h, then a solid rich in metal oxides, called CAT A6b, is obtained.

Treatment with a green organic solvent (ethanol, propanol, acetone) makes it possible to reduce the concentration of Mg and to increase the concentration of Ca and Ba of the catalyst prepared, and its basic power. It thus makes it possible to reduce the catalytic mass of the catalyst used. A mineral composition of plantain treated (CAT A6b) or not (CAT A6c) with an organic solvent and then calcined at 1000 ° C. illustrates the modification of the mineral composition expressed in ppm.

Mineral composition in ppm of a catalyst (or reagent) of plant origin after treatment or not with a green solvent

CAT A6b and CAT A6c have a reactivity similar to CAT A5. The presence of other metal elements allows easy hydration and not exothermic.

The present invention also relates to the use of a composition as described above containing at least one basic metal catalyst comprising a extract having optionally undergone heat treatment of a plant or part of a plant, of an alga or part of an alga having a high level of alkali or alkaline earth metal, preferably calcium (Ca) in an amount preferably greater than 50000 ppm by weight and substantially free of transition metals, metalloids and post-transition metals, preferably containing less than 20000 ppm of metals selected from Zinc (Zn), Ni (Ni ), Manganese (Mn) Lead (Pb), Cadmium (Cd) or marine shells or shells of non-marine molluscs containing a significant level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, in an amount preferably greater than 80%, more preferably greater than 90% by weight for the implementation of organic synthesis reactions of functional transformations by catalysis involving the a basic catalyst characterized in that said organic synthesis reactions are chosen from isomerization, chemoselective hydrolysis, controlled esterification, transesterification, alkylation, elimination and carbon-carbon bond formation reactions such as that the reactions of the type of electrolysis, C-glycosidation, carbonylolation such as the Wittig-Horner reaction, transesterification reactions, acylation, epimerization, condensation, cyclization, di-, tri-, The present invention also relates to the use of a composition as described above, characterized in that the organic synthesis reactions are chosen from hydrolysis reactions and more particularly from chemoselective hydrolyses. of acid-derived functions, transesterification reactions and intramolecular electrolysis reactions and intermolecular or related.

The present invention also more specifically relates to the use of a composition as described above containing at least one basic metal catalyst comprising an extract having optionally undergone heat treatment of a plant or part of a plant, of an alga or part of an alga having a high level of alkali or alkaline earth metal, preferably calcium (Ca), in an amount preferably greater than 5000 ppm by weight or sea shells or shells of non-marine molluscs containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, in amount preferably greater than 80%, more preferably greater than 90% by weight for the implementation of organic synthesis reactions functional transformations by catalysis involving said basic catalyst characterized in that said organic synthesis reactions are selected from the reactions of preparation of α, β-ethylenic carbonyl derivatives by isomerization, the cross-linked aldolization reactions using variously functionalized aldehydes such as vanillin or masked in hemiacetal form, such as the aldoses, the monoesterification of dicarboxylic acids, the soft hydrolysis of plurifunctional esters, transesterification of carboxylic esters.

The present invention also more specifically relates to the use of a composition as described above containing at least one basic metal catalyst for the implementation of organic synthesis reactions involving said basic catalyst, the alkali metal concentration. or alkaline earth, preferably calcium (Ca) is between 5,000 and 400,000 mg.kg- ¹ for calcium and between 3,000 and 300,000 mg.kg- ¹ for magnesium contained in the catalysts from the leaves , stems and / or roots of a plant or part of a plant or of an algae or a portion of alga having a high level of alkali or alkaline earth metal.

The present invention also relates to one of the compositions as obtained by implementing the method described above.

The present invention also more specifically relates to one of the compositions as obtained by carrying out the method described above and containing at least one basic metal catalyst selected from an alkali metal or alkaline earth metal, preferably calcium (Ca), in an amount greater than 5,000 ppm, preferably in an amount greater than 50,000 ppm, and in particular greater than 100,000 ppm for calcium (Ca) and in an amount greater than 3,000 ppm, preferably greater than 40 000 ppm, and in particular greater than 80 000 ppm magnesium (Mg), comprising at least one of said metals in oxide form, salt such as carbonate or calcium oxalate or hydroxide. In general, the invention is preferably implemented with a high level of calcium to generate a catalyst as basic as possible. The other cations are not generally necessary and the invention can be implemented with a low transition metal content.

Magnesium generally gives lower experimental results than calcium. It is therefore preferable to lower the level present in the catalysts.

As indicated above, when very high temperatures of the order of 1000-1100 ° C are used during the heat treatment step, no chlorophyll remains in the residues obtained. However, the presence of initial chlorophyll may leave, in the final product, magnesium oxide that may want to eliminate.

This disposal can be carried out under the following conditions:

The biomass constituted by the extracts of a plant or a part of a plant, preferably a plant or part of a plant, an algae or a portion of a seaweed can be treated by the ethanol or acetone so as to pass chlorophyll in solution. The filtrate thus obtained is substantially free of chlorophyll and can be used for subsequent reactions. It is thus possible to obtain a reduction of about 5 to 10% of the solid mass of catalyst.

In oyster shells, magnesium is in very small quantities.

A very important advantage in practice of the use of catalysts or reagents of the invention which consist of alkali or alkaline earth metals, preferably salts such as carbonates or calcium hydroxides is the possibility, at the end of reaction of remove them from the aqueous reaction phase by passage with calcium oxalate (by addition of oxalic acid) which is a salt insoluble in water and precipitates.

The aqueous reaction phase therefore does not need to be treated to remove the catalyst used. II - Synthetic applications of biosourced basic catalysts

Experimental part: application of catalysts

- isomerization reaction

An example of isomerization is the migration of a double bond under thermodynamic control. It can be catalyzed quantitatively by a biosourced CATA1 type catalyst preferably supported on basic alumina, montmorillonite or hydrotalcite.

Gf: functional group, R ^1, R ² , R ³ , R ⁴ - alkyl group, aryl, heteroatom

This type of transformation can lead to the preparation of 2-heptenal, a molecule widely used in perfumery and in the cosmetics industries.

 Experimental conditions:

50 mg of 3-heptenal are added to a suspension of 2 ml of water and 100 mg of metal oxides (CATA1) supported on basic alumina. The reaction is followed in IR (displacements of the vibration band of the double bond C = C 1659 to 1637 cm -1, and the C = O double bond 1726 to 1683 cm -1). After stirring for 1 hour, the reaction is filtered and the medium is evaporated under nitrogen. The reaction is complete (IR control and 1H NMR). - chemoselective hydrolysis of functions derived from acid i) basic biosourced catalyst

R ¹ -COOR ² * ^■ R ¹ -COOH

ii) oxyalkyl, cycloalkyl, alkenyl, cycloalkenyl, aryl, mondo-, di- or trisubtitled acid; alkenyl, alkenyl

The advantage of the catalysts is to allow gentle hydrolysis on fragile or multifunctional substrates and then to facilitate the reaction treatments. This is for example the hydrolysis of an ethyl ester carried by a quaternary carbon: unlike the alkali hydroxides, it is possible to avoid the secondary reactions of decarboxylation and isomerization.

Similarly, the hydrolysis of an ester borne by a functionalized or unsaturated aromatic ring is easily achieved using basic biosourced catalysts. Protonation of the carboxylate formed by a natural organic acid, oxalic acid is doubly advantageous:

 - it avoids the use of corrosive mineral acids;

 - It allows the precipitation and recovery of calcium salts by formation of insoluble calcium oxalate.

This reaction is preferably carried out with a catalyst derived from oyster shells or a mixture of oyster shells and mussels or crepidulae. Experimental conditions:

Example 1

R = H, Me, OH; R '= linear or branched alkyl, cycloalkyl, aryl 10 mmol of methyl benzoate are added to 100mg of biosourced catalyst preferably CATA3 type. A minimum of the H ₂ O / MeOH mixture is added to ensure good agitation. After 1 h of heating at 60 ° C, oxalic acid is added. The medium is concentrated. Sublimation of the medium makes it possible to obtain very pure benzoic acid.

Example 2

6.327 mL of methyl salicylate (7.403 g, 48.65 mmol, 1 eq) was added to 125 mL of milliQ water. then CAT A5 catalyst derived from a mixture of oyster shells and mussels (90% CaO of the total mass of the cat, 1 eq in Ca) is introduced in small portions into a 250 mL three-necked flask with stirring magnetic.

The reaction medium is refluxed for 90 minutes (the coloring of the milky medium can change from a very slightly green tint to yellow or orange depending on the catalyst batch). The pH, initially at 12, reaches the value of 9.

The acidification of the reaction medium is carried out with a natural organic acid, oxalic acid.

Three objectives are expected:

- The protonation of the phenate

 - The protonation of the carboxylate

- Precipitation of calcium salts in the form of calcium oxalate. 12.3 g (2 eq) of oxalic acid dihydrate are added hot until a pH ~ 2 is obtained. The coloring of the very dense milky medium changes to pink and then to light violet. Precipitation of calcium oxalate is observed. After 5 minutes of stirring, the medium The filtrate is filtered hot on porosity 4. The light yellow filtrate is washed with hot water, concentrated in a 250 ml flask, cooled to 5 ° C and then filtered on the previous frit containing the previous solid residue. The total conversion of methyl salicylate is confirmed by TLC (eluent: cyclohexane / acetone: 8/2). Saicylic acid is recrystallized from water (solubility in water at 100 ° C = 66 g / L, at 25 ° C - 2.24 g / L, at 0 ° C = 1.2 g / L). The crystals are filtered through porosity 3, rinsed with 20 ml of milliQ water at 5 ° C. and dried under reduced pressure over P ₂ 0 ₅ for 12 h. 97% of white crystals are obtained. The purity of the salicylic acid is controlled by GC MS>98%; characterizations: GC / MS, IR, mp: 157-159 ° C. An ICP MS analysis confirms the absence of calcium contamination of saiicylic acid.

- controlled esterification:

 The example of the controlled monoesterification of the primary alcohol of vanillic alcohol in the presence of the free phenol function is demonstrative. The described biosourced basic catalysts are much softer and more selective than the conventional acetic anhydride / pyridine system which does not allow this chemoselectivity.

Catalyst CAT A5 is also a transesterification catalyst. Thus, it is capable of facilitating the transesterification of ethyl butyrate by methanol. Supported on a porous silica, the leaching phenomena are limited.

Another reaction of interest is the monesterification of natural dicarboxylic acids. The control of the monoesterification is possible thanks to the basic properties mild catalysts used. The proposed process is based on three successive transformations one pot:

 the formation of the anhydride in situ;

 trapping of the anhydride formed by the alcohol present;

precipitation of the salt derived from the ester acid.

 n = 0.1 R = H, alkyl, aryl = alkyl, cycloalkyl,

Example:

10 mmol of succinic acid are mixed with 100 mg of metal oxides (CATA1). The mixture is heated until observation of the sublimation of the succinic anhydride. 10 mmol of cyclohexanol are added to the medium. This is heated to 70 ° C. The reaction is monitored by TLC (vanillin revelation); it is quantitative. No diester formation is observed. The medium is neutralized with oxalic acid.

Metal hydroxides (CAT A 2, A3) and lithothamne (CATB) can be used; in this case, prior or in situ sublimation of the diacid anhydride is necessary if we want to achieve the same yields. - alkylation

 Basic biobased catalysts are able to promote alkylation reactions. Thus, for example, it is possible to carry out the "O-alkylation" of a carboxylic acid.

CATA or CATB

1COOH + R ² XR ¹ COOR ²

R = alkyl, cycloalkyl, aryl

R ^z = alkyl, akenyl

The protocol is exemplified with an alkylating agent such as propyl bromide and acetic acid.

 CATB

MeCOOH + Pr ⁿ X "- eCOOPr"

- operating conditions

Example: 10 mmol of acetic acid and 10 mmol of bromo-propane are mixed with 100 mg of lithothamne (CAT B). After 2 x 30 seconds of microwave activation at 600 W, the mixture is filtered and analyzed by IR. The formation of propyl acetate is complete (v (C = O) = 1735 cm ^-1 ).

- elimination

The second-order beta-elimination can be catalyzed by biobased catalysts.

R = alkyl, aryl, functional group éEectroattractor

X = Cl, Br, 1, OSO ₂ alkyl or aryl

Formula wherein alkyl represents a linear or branched 1 to 6 carbon atom unit, preferably methyl and aryl is preferably a phenyl radical. This is, for example, the conversion of 2-bromoethylbenzene to styrene which is easily carried out with all CATA 1-5 and CATB catalysts by microwave activation (2 minutes, 400 ° C., 600W).

- aldolization and related reactions:

Reactions involving an acidic hydrogen alpha to one or two electron-withdrawing functional groups and an electrophilic partner such as a carbonyl derivative (aldehyde or ketone) or an acid derivative (nitrile, ester or carboxylic anhydride) are promoted by basic biosourced catalysts.

 basiq catalyst

 Z '

 Z biosourced

 + Gf R '

 R

Z, Z ¹ = H, alkyl, aryl, nitro, aldehyde, ketone, nitrile, carboyl ester

 Gf = functional group aldehyde, ketone, nitrile, carboyl ester, acid anhydride

Examples where Z and / or Z 'are keto groups or carboxylic esters, and

Ketonic or aldehyde groups illustrate these possibilities by intra- and intermolecular routes.

 * Intramolecular: intramolecular aldolization reactions are feasible whatever the catalyst used and the natural species from which it originates. They allow access to key molecules in the cosmetics industry, such as dihydrojasmone.

dihydrojasmone - operating conditions

 2,5-undecadione (0.5 mol) is diluted in a mixture of water and ethanol (80/20 mL). 500 mg of plantain hydroxides prepared by alkaline hydrolysis of the corresponding chlorides (CATA3) or from CAT A5. The solution is refluxed 16h, then extracted with ether. A follow-up of the reaction by GC MS shows the complete formation of the dihydrojasmone.

 The catalyst is recycled by filtration, washing with water, with ethanol and acetone and drying for 4 hours at 120 ° C. * intermolecular: intermolecular aldolization reactions are also possible.

 They are illustrated by the Claisen-Schmidt reaction allowing rapid access to styrylketones. These compounds are synthetic intermediates of pyrazonilic derivatives of medical interest or eduicorants. The advantage of the proposed method is to avoid the competing reaction of Carnizzaro. The quantitative synthesis of chaicone reflects this possibility. The set of catalysts proposed is possible; CAT A3, however, has the best catalytic activity.

 chaicone

Operating conditions:

0.1 mole of benzaldehyde and 0.1 mole of acetophenone are diluted in 20 ml of absolute ethanol. 500 mg of catalyst consisting of a co-milled mixture of 200 mg of rumex hydroxide (CATA3) and of basic alumina are added to the reaction medium. After stirring for 2 h at reflux, the reaction medium is cooled with an ice-water bath. The precipitated solid is filtered and recrystallized from ethanol. Extraction of the aqueous phase with hexane makes it possible to obtain a quantitative yield. The product is characterized by its melting point (F °: 57 ~ 59 ° C), by IR (v C = 0: 1665 cm ^-1 , C = C: 1608 cm- ^s ) and its purity is verified by GC MS . The cross-aldol condensation reaction can be extended to multifunctional aromatic aldehydes and ketones. Examples of industrial interest leading to synthetic flavors, compounds used in certain cosmetic creams or analgesics. Their synthesis is carried out from vanillin, corresponding ketones and basic catalysts developed. This is for example the green synthesis

Knoevenagel reactions are also very effective thanks to this new type of biosourced catalysis. This possibility is proved by the reaction between a β-ketoester and the masked aldehyde function of an aldose. The hemiacetal balance is easily shifted to the aldehyde form; the adduct undergoes in situ a dehydration reaction. The removal product is then subjected to an intramolecular Michael reaction.

All these transformations take place one-pot and can be extended to many substrates: the β-ketoester can be replaced by a β-dione; the aldose may be a hexose, a pentose, or a deoxyaidosis.

R = H, alkyl, OH, CH ₂ OH R '= alkyl, aryl Example: 405 mg of D-xylose are diluted in 15 ml of ethanol, then 1.2 equivalents of pentanedione (332.2 μΐ) and 326 mg of hydrated CAT A5 derived from Bouzigues oysters (80.5% of CaO, 0.75 equivalent of calcium.) Are added. The reaction mixture is heated for 5 h at 50 ° C. The formed calcium acetate is filtered and the medium concentrated. The reaction is quantitative and may be followed by TLC (DCM / eOH: 9/1, Rf 0.3). The diastereomeric ratio is evaluated by GC MS after silylation; it is greater than 90/10. - Reaction of carbonyl olefin

Carbonylolefination reactions are one of the most important methods of C = C double bond creation. Calcium-rich biosourced catalysts are very good catalysts for this type of reaction. This result is exemplified by Wittig-Horner's reaction. The reaction is stereoselective: the olefin E is preferentially formed.

The carbonylolefination reaction can also be performed on the hemiacetal function of an aldose. In this case, the carbonylolefination-Michael dehydration sequence leads to a C-glycoside of interest.

- operating conditions

10 mmol of diethyl phosphonoacetate and 10 mmol of benzaldehyde are diluted in a mixture of water and ethanol (10 mL / 10 mL). 50 mg of lithothamne are added to the reaction medium. After stirring for 12 hours, 20 ml of hexane are added. After extraction, drying, filtration and evaporation, the organic solution is concentrated in vacuo. > 99.9% of ethyl cinnamate are obtained.

If the catalyst is an unsupported hydroxide derived from a species rich in calcium oxalate such as rumex, prolonged agitation allows the hydrolysis of ethyl cinnamate formed in situ cinnamic salt.

Claims

1. Use as a catalyst of materials of organic origin containing alkali or alkaline earth metals, preferably calcium and substantially free of transition metals, metalloids and post-transition metals for the implementation of synthesis reactions organic material involving said catalyst.

2. Use according to claim 1 characterized in that the materials of organic origin come from a plant or a part of a plant, preferably a plant or part of a plant, an algae or a plant. a portion of alga containing an alkali or alkaline earth metal content, preferably calcium (Ca), preferably in excess of 50000 ppm by weight, and substantially free of transition metals, metalloids and post-transition, preferably containing less than 20000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd), Copper (Cu), palladium (Pd) and said materials having optionally undergone a heat treatment, for the implementation of organic synthesis reactions involving said catalyst.

3. Use according to claim 1 characterized in that the materials of organic origin are marine shells or shells of non-marine molluscs, said shells containing a high level of alkali or alkaline earth metal, preferably calcium (Ca) , preferably in the form of calcium carbonate, in an amount preferably greater than 80%, more preferably greater than 90% by weight, said shells having optionally undergone grinding and / or heat treatment for the implementation of synthesis reactions organic agent involving said basic catalyst.

4. Use, according to claim 1 or 2, as a basic catalyst of an extract of a plant or part of a plant of an alga or part of alga having a high level of alkali metal or alkaline -terreux preferably calcium (Ca), in amount preferably greater than 50000 ppm by weight and containing less than 10000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd), Copper (Cu), palladium (Pd) or mate shells or non-marine mollusc shells containing a high level of alkali metal or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, in amount preferably greater than 80%, more preferably greater than 90% by weight, after drying and / or grinding and / or heat treatment and / or chemical, said catalyst being in the form of calcium oxide, calcium salt preferably of carbonate, oxalate, or hydroxide of alkali or alkaline earth metal, preferably calcium (Ca), for the implementation of organic synthesis reactions involving said basic catalyst.

5. Use according to claim 1, 2 or 4 as a basic catalyst of an extract of a plant or part of a plant of an alga or part of alga having a high level of calcium (Ca) in an amount preferably greater than 50000 ppm by weight, and containing less than 5000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd) , copper (Cu), palladium (Pd) or marine shells or shells of non-marine molluscs containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium, in an amount preferably greater than 80%, more preferably greater than 90% by weight, optionally after drying and / or grinding and heat treatment and / or chemical said catalyst being in the form of calcium oxide, calcium salt chosen oxalate, carbonate, phosphates such as phytate, simple carboxylates such as citrate, or osiodic carboxylates such as uronates of the alginate or polygalacturonates or calcium hydroxide type for carrying out organic synthesis reactions involving said basic catalyst.

6. Use according to claim 1, 2, 4 or 5 as a catalyst of an extract of a plant or part of a plant of an alga or part of alga having a high level of calcium (Ca ), in an amount preferably greater than 50000 ppm and containing less than 5000 ppm of metals selected from zinc (Zn), nickel (Ni), Manganese (Mn) lead (Pb), cadmium (Cd), copper (Cu), palladium (Pd) by weight prepared by drying and / or grinding and by heat treatment and / or chemical said catalyst being in the form of salt such as carbonate, or calcium oxalate, in the form of calcium oxide or calcium hydroxide, for the implementation of organic synthesis reactions involving said basic catalyst.

7. Use according to claim 1, 3, 4 or 5 as a catalyst for marine shells or shells of non-marine molluscs containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, in an amount preferably greater than 80%, more preferably greater than 90% by weight, after optionally grinding and / or heat treatment and / or chemical said catalyst being in the form of calcium oxide, calcium salt chosen among oxalate, carbonate, simple carboxylates such as citrate, or osiodic carboxylates such as uronates of alginate or polygalacturonates or calcium hydroxide type for the implementation of organic synthesis reactions involving said basic catalyst .

8. Use according to one of claims 1 to 7 characterized in that the possible chemical treatment (s) to which the plant or part of a plant extract, the marine shells or non-marine shell shells are subjected is either a hydration reaction with water of the oxides obtained by heat treatment is a reaction with an inorganic or organic acid, preferably hydrochloric acid followed by treatment with a strong base, preferably sodium hydroxide at a pH greater than 12 oxides obtained by heat treatment or salts obtained by drying and / or grinding.

9. Use according to one of claims 1, 2,4, 5, 6 and 8 characterized in that the plant having a high level of alkali metal or alkaline earth preferably calcium (Ca), in preferably greater amount at 50000 ppm by weight, in salt form such that carbonate or calcium oxalate is a common plant naturally rich in calcium carbonate or oxalate, preferably calcium oxalate and containing less than 5000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd), Copper (Cu), Palladium (Pd) or Algae chosen from calcifying algae or non-calcifying algae, preferably calcifying algae.

10. Use according to one of claims 1, 2,4, 5, 6, 8 and 9 characterized in that the plant having a high level of calcium (Ca), in an amount preferably greater than 50000 ppm by weight, under salt form such as calcium oxalate is a plant selected from:

^■ common plants and especially plants rich in calcium oxalates chosen from Liliaceae (such as dieffenbachia,); Araceae (such as spotted arum); Amaryllidaceae (such as narcissus); the Chenopodiaceae (such as lamb's-quarters, atriplex, quinoa); Lemnaceae (such as duckweed); Berberidaceae (such as mahonias); Polygonaceae (such as rhubarb, all rumex, knotweed); Plantaginaceae (such as large plantain); the Pontederiaceae. (such as Pontederia cordata); Onagraceae (such as Jussie creeping); Portulacaceae (such as common purslane); the Agavaceae (such as Yucca); Moraceae (such as Iroko)

^■ the calcifying algae selected from

^■ green algae such as Halimeda (aragonite); Udotea

^■ brown algae such as Padina

^■ red algae such as Liagoraceae

 (Galaxaui'a Dichotomaria); Corallinaceae: (Amphiroa, Jania) (rhodoliths); Lithothamniurn,

^■ non-calcifying algae chosen from

^■ brown algae such as those of the family Alariaceae including Undaria pinnatifida (or sea fern), Alaria esculenta, Alaria marginata, Undaria dis tans, Laminaria digita, Laminaria saccharina

^■ red algae such as those of the family

 Palmariales including almaria palmata, those of the family Gigartinaceae including Chondrus crispus, those of the family Bangiophyceae,

^■ green algae such as those of the family of ulvaceae

especially Ulva lactuca.

11. Use according to claim 10 characterized in that the plant having a high level of calcium (Ca), in an amount preferably greater than 50000 ppm by weight, in salt form such as calcium oxalate or calcium carbonate is a plant chosen from:

 Chenopodiaceae, preferably Lamb's-quarters

 the Plantaginaceae preferably the big plantain

 the Portulacaceae the common purslane

 calcifying algae, preferably Lithothamnium.

12. Use according to one of claims 10 and 11 characterized in that the plant having a high level of calcium (Ca), preferably in excess of 50000 ppm by weight, in salt form such as calcium oxalate is a plant chosen from lamb's-quarters, large plantains, common purslanes or the algae called Lithothamnium.

13. Use according to claim 1,3,4, 7 or 8 characterized in that the materials of organic origin are marine shells such as shells, oysters, mussels, scallops, crepidulae, skeletons. , shells and other shells of non-marine molluscs such as snails, containing a high level of alkali or alkaline-earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, preferably in excess of 80 %, more preferably greater than 90% by weight for the implementation of organic synthesis reactions involving said basic catalyst.

14. Process for preparing a catalyst consisting of at least one alkaline or alkaline earth metal, preferably calcium (Ca), characterized in that it comprises the following steps:

a) dehydration, preferably at room temperature or in an oven at a temperature of the order of 70 ° of the biomass comprising the leaves, stems and / or roots of a plant or a plant or plant extract; an alga or part of an alga having a level of alkali or alkaline earth metal, preferably calcium (Ca), in an amount greater than 50000 ppm by weight in salt form such as carbonate or oxalate and substantially free of transition metals, metalloids and post-transition metals, preferably containing less than 20000 ppm of metals selected from Zinc (Zn) , ie Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd), Copper (Cu), Palladium (Pd) and / or b) Crushing the dry biomass of a plant or an extract of a plant, an algae or a portion of alga obtained, if appropriate, after dehydration according to stage a)

 or

 (c) Crushing shells or fragments of shells of animal origin and, or

 d) Heat treatment of the biomass obtained in steps a) or b) in a furnace preferably in one or more steps preferably in one step at a temperature of the order of 400 ° C to 600 ° C, preferably 1 500 ° C for several hours, preferably for about 7 hours to obtain an alkali or alkaline earth metal salt, preferably calcium carbonate.

 Or

 e) heat treatment of the mass obtained in steps a) or b) or c) in a furnace preferably in one or more steps preferably in one step at about 1000 ° for several hours, preferably for about 7 hours to obtain a alkaline or alkaline earth metal oxide, preferably calcium oxide

and, if desired, the alkali metal or alkaline earth salts preferably calcium (Ca) or the oxides obtained respectively in stages d), and e) are subject to

 f) Or, for the oxides obtained in stage e) at a follow-up hydration preferably of a decantation, an evaporation and a drying at a temperature of the order of 80 ° C.

(g) Alternatively, the salts, preferably the calcium carbonate obtained in stage (d), are treated with an inorganic or organic acid, preferably hydrochloric acid, followed by treatment with a strong base, preferably sodium hydroxide. pH greater than 12, and if desired the alkali or alkaline-earth metal salts, preferably calcium (Ca), obtained in stage d) and the alkali or alkaline earth metal hydroxides, preferably calcium (Ca), obtained in stages f) or g) are mixed together preferably by co-grinding with a support such as alumina, for example basic alumina, or hydrotalcite to obtain a supported catalyst.

15. A process for preparing a catalyst comprising a metallic agent consisting of at least one alkali metal or alkaline earth metal, preferably calcium (Ca), characterized in that it comprises the following stages: a) dehydration, preferably at room temperature or in an oven at a temperature of the order of 70 ° of the biomass comprising the leaves, stems and / or roots of a plant or a plant extract or an alga or an part of alga having an alkali metal or alkaline earth metal content, preferably calcium (Ca), in an amount greater than 50000 ppm by weight in salt form such as carbonate or oxalate and substantially free of transition metals, of metalloids and posttransition metals, preferably containing less than 20000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd), Copper (Cu), palladium (Pd) and / or b) grinding of biomas se, including the leaves, stems and / or roots of a plant or part of a plant, algae or part of seaweed possibly obtained after dehydration according to stage a),

 and, if desired,

 c) ultrasonic activation or light heating at a temperature of the order of 60 ° C followed by removal of the plant part preferably on a sinter of high porosity of the ground mixture obtained in steps a) or b) and a centrifugation or filtration

and if desired, d) treatment of salts such as an alkali metal or alkaline earth carbonate or oxalate, preferably calcium (Ca), obtained in steps a) b) or c) with an inorganic or organic acid, preferably hydrochloric acid followed by treatment with a strong base, preferably sodium hydroxide at a pH greater than 12, followed preferably by centrifugation or by filtration of the precipitated solid

 and if desired

 e) thermal treatment of the biomass obtained in step a) or the ground mixture obtained in step b) in a furnace preferably in one or more steps preferably in one step at a temperature ranging from about 400 ° to about 1100 ° during several hours, preferably for about 7 hours

and, if desired, the alkali or alkaline earth metal oxides, preferably calcium (Ca), obtained in step e) are subject to

 f) Or to a hydration followed preferably of a decantation, an evaporation and a drying at a temperature of the order of 80 ° C g) Or treated by a mineral or organic acid preferably the hydrochloric acid followed by treatment with a strong base, preferably sodium hydroxide at a pH greater than 12, followed preferably by centrifugation or filtration of the precipitated solid, and if desired,

h) salts such as an alkali metal or alkaline earth metal carbonate or oxalate, preferably calcium (Ca), obtained in steps a) b) or c) alkaline or alkaline earth metal oxides, preferably calcium (Ca), obtained in stage e) and the alkali or alkaline earth metal hydroxides, preferably calcium (Ca), obtained in stages d), f) or g) are mixed, preferably by co-grinding with a support such as alumina, for example basic alumina, silica, zeolites, for example montmorillonite, or hydrotalcite to obtain a supported catalyst.

16. A process for preparing a catalyst comprising a metallic agent consisting of at least one alkali metal or alkaline earth metal, preferably calcium (Ca), characterized in that it comprises the following steps:

 a) Grinding of marine shells or shells of non-marine molluscs containing a significant level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, in an amount preferably greater than 80% more preferably greater than 90% by weight

 and or

 b) heat treatment of marine shells or shells of non-marine molluscs containing a high level of alkali or alkaline earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, preferably in excess of 80 %, more preferably greater than 90% by weight or the ground biomass obtained in stage a), in a furnace preferably in one or more steps preferably in one step at about 1000 to 1100 ° for several hours, preferably for about 7 hours

 and if desired

 c) ultrasonic activation or light heating at a temperature of the order of 60 ° C followed by removal of the plant part preferably on a sinter of high porosity of the ground mixture obtained in steps a) or b) and a centrifugation or filtration

 and if desired,

d) treatment of salts such as an oxalate, an alkali metal or alkaline earth metal carbonate, preferably calcium (Ca), obtained in steps a) b) or c) with an inorganic or organic acid, preferably the acid hydrochloric acid followed by treatment with a strong base, preferably sodium hydroxide at a pH greater than 12, followed preferably by centrifugation or filtration of the precipitated solid and, if desired, the alkali metal oxides or alkali metal oxides. earth, preferably calcium (Ca), obtained in stage b) are subject to e) Well to hydration followed preferably of decantation, evaporation and drying at a temperature of the order of 80 ° C f) Or treated with an inorganic or organic acid preferably hydrochloric acid followed by treatment with a strong base, preferably sodium hydroxide at a pH greater than 12, followed preferably by centrifugation or by filtration of the precipitated solid

 And, if desired,

 g) salts such as an alkali metal or alkaline earth metal carbonate, preferably calcium (Ca), obtained in steps a) b) or c) alkali or alkaline earth metal oxides, preferably calcium (Ca) , obtained in stage b) and the alkali metal or alkaline earth metal hydroxides, preferably calcium (Ca), obtained in stages d), f) or g) are mixed, preferably by co-grinding with a support such as alumina, for example basic alumina, silica, zeolites, for example montmorillonite, or hydrotalcite to obtain a supported catalyst.

17. The method of claim 14 for preparing a composition comprising a metal agent consisting of at least one alkali metal or alkaline earth metal, preferably calcium (Ca), characterized in that it comprises the following steps:

 Dehydration, preferably at room temperature or in an oven at a temperature of about 70 ° of the biomass comprising the leaves, stems and / or roots of a plant or plant extract or of an algae or a portion of alga having a high level of alkali or alkaline earth metal, preferably calcium (Ca), in an amount preferably greater than 50000 ppm by weight in the form of a salt such as a carbonate or a oxalate and substantially free of transition metals, metalloids and post-transition metals, preferably containing less than 20,000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead ( Pb), cadmium (Cd) copper (Cu), palladium (Pd)

and or b) Crushing of the dry biomass of a plant or a plant extract, an algae or a part of seaweed obtained, if appropriate, after dehydration according to stage a)

 And if desired

 f) Ultrasonic activation or light heating followed by removal of the plant part preferably on a frit of high porosity of the ground mixture obtained in stage a) or b) and centrifugation or filtration and, if desired salts, such as an alkali metal or alkaline earth carbonate or oxalate, preferably calcium (Ca), obtained in steps a), b) or c) are subjected to:

 g) a treatment with an inorganic or organic acid, preferably hydrochloric acid followed by treatment with a strong base, preferably sodium hydroxide at a pH greater than 12,

 and, if desired,

 h) salts such as an alkali metal or alkaline earth carbonate or oxalate, preferably calcium (Ca), obtained in steps a) b) or c) and alkali or alkaline earth metal hydroxides preferably calcium (Ca), obtained in stage d) are mixed, preferably by co-grinding with a support such as alumina, for example basic alumina, zeolites for example montmorillonite, silica or hydrotalcite to obtain a supported catalyst.

18. The method of claim 14 for preparing a composition comprising a metal agent consisting of at least one alkali metal or alkaline earth metal, preferably calcium (Ca) from the leaves, stems and / or roots of a plant or an extract of a plant or an alga or part of an alga having a high level of alkaline or alkaline earth metal, preferably calcium (Ca), in an amount preferably greater than 50000 ppm in weight in salt form such as carbonate or oxalate and substantially free of transition metals, metalloids and post-transition metals, preferably containing less than 20,000 ppm of metals selected from zinc (Zn), nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd) characterized in that it comprises, before the heat treatment of the mass obtained in steps a) or b) a step of extraction of chlorophyll with an organic solvent, preferably acetone, ethanol or isopropanol.

19. Method according to one of claims 14 or 16 characterized in that the plant having a high level of calcium (Ca), in an amount preferably greater than 5000 ppm by weight, in salt form such as calcium oxalate is a plant chosen from:

^■ Common Plants, in particular plants rich in calcium oxalates chosen from Liliaceae (such as dieffenbachia, Araceae (such as spotted arum), Amaryllidaceae (such as daffodils), Chenopodiaceae (such as lamb's-quarters, at iplex, quinoa). Lemnaceae (such as duckweed), Berberidaceae (such as mahonias), Polygonaceae (such as rhubarb, all rumex, knotweed), Plantaginaceae (such as grand plantain), Pontederiaceae. Pontederia cordat), Onagraceae (such as Jussie creeping), Portulacaceae (such as common purslane), Agavaceae (such as Yucca), Moraceae (such as Iroko)

^■ calcifying algae selected from

^■ green algae such as Halimeda (aragonite); Udotea

^■ brown algae such as Padina

^■ red algae such as Liagoraceae

 (Galaxaura / Dichotomaria); Corallinaceae: (Amphiroa, Jania) (rhodoliths); Lithothamnium.

20. Use according to one of claims 1 to 11 of a composition containing at least one basic metal catalyst comprising an extract having optionally undergone heat treatment of a plant or part of a plant, an algae or a plant. a portion of alga having a high level of alkali or alkaline earth metal, preferably calcium (Ca), in an amount preferably greater than 50000 ppm by weight and substantially free of transition metals, metalloids and posttransition, preferably containing less than 20,000 ppm of metals selected from Zinc (Zn), Nickel (Ni), Manganese (Mn) Lead (Pb), Cadmium (Cd) or sea shells or shellfish shells non-marine containing a significant amount of metal alkaline or alkaline-earth metal, preferably calcium (Ca), preferably in the form of calcium carbonate, in an amount preferably greater than 80%, more preferably greater than 90% by weight for carrying out organic synthesis reactions catalytic functional transformation involving said basic catalyst characterized in that said organic synthesis reactions are selected from isomerization, chemoselective hydrolysis, controlled esterification, transesterification, alkylation, elimination, carbon-carbon bond formations such as aidolization, C-glycosidation, carbonylolefination reactions such as the Wittig-Horner reaction, transesterification, acylation, epimerization, condensation, cyclization reactions, of di-, tri- _? polymerization, conjugated addition or not.

21. Use according to claim 20 of a composition containing at least one basic metal catalyst for the implementation of organic synthesis reactions of functional transformations by catalysis involving said basic catalyst, characterized in that said organic synthesis reactions are chosen from hydrolysis reactions and more particularly chemoselective hydrolyses of acid-derived functions, transesterification reactions and intramolecular and intermolecular or related aldolization reactions.

22. Use according to claim 20 of a composition containing at least one basic metal catalyst for carrying out organic synthesis reactions of functional transformations by catalysis involving said basic catalyst, characterized in that said organic synthesis reactions are chosen from reactions of preparation of α, β-ethylenic carbonyl derivatives by isomerization, cross-aldolisation reactions using variously functionalized aldehydes such as vanillin or masked in hemiacetal form such as the aldoses, the monoesterification of dicarboxylic acids, the mild hydrolysis of multifunctional esters, transesterification of carboxylic esters.

23. Use according to one of claims 21 or 22 characterized in that in the composition containing at least one basic metal catalyst for the implementation of organic synthesis reactions involving said basic catalyst, the concentration of alkali metal or alkaline earth metal, preferably calcium (Ca) is between 5,000 and 200,000 mg.kg- ¹ for calcium and between 3,000 and 200,000 mg.kg ^"J for the magnesium contained in the catalysts derived from the leaves, stems and / or roots of a plant or part of a plant or algae or part of the alga having a rate important alkali metal or alkaline earth metal.