Plant extracts with anti-radical type action

[0001] The invention relates to the cosmetics field, particularly to the use of plant extracts in dermo-cosmetics, and its object is the use of certain medicinal herbs from French Guyana for the preparation of cosmetic or dermo-pharmaceutical products for the skin, mucous membrane and/or the epithelium or body appendages (hair, nails etc).

[0002] The Creole and Palikur peoples of French Guyana use numerous local plants in their traditional medicine. These plants and their therapeutic use are described particularly in the work entitled: “Pharmacopées traditionelles en Guyane: Créoles. Palikur, Wayapi” by Grenand P., Moretti C. and Jacquemin H., published by Orstom in 1987.

[0003] The authors of this invention have however discovered that extracts of certain plants of the above-mentioned type have various biological and biochemical actions linked with very high cutaneous tolerance, which enables them to be used directly in compositions for cosmetic use and particularly in dermo-cosmetics.

[0004] The plants chosen by the inventors therefore enable extracts to be obtained, all of which unexpectedly and surprisingly have a stronger anti-radical-type action but also an inhibiting action on tyrosinase (de-pigmenting), on tyrosinase activators (pigmenting), an anti-UVA and anti-UVB action, an action protecting catalase from UVA, and an anti-elastase, anti-collagenase, anti-gylcation and/or lypolytic action (for slimming).

[0005] The main object of the invention is therefore to use at least one extract of a plant of a botanical genus belonging to the group formed by Clidemia, Inga, Sabicea, Astrocaryum, Siparuna, Eperua, Byrsonima, Priva, Coutoubea or Goupia as an active ingredient, particularly with an anti-radical action, in the preparation of a cosmetic or dermo-pharmaceutical product for external, topical use on the skin, mucous membrane and/or epithelium or body appendages.

[0006] The following particular species may advantageously be selected from the above-mentioned genera:

[0007]

Clidemia hirta, Clidemia dentata

[0008]

Inga bourgoni, Inga pezizifera, Inga alata, Inga alba, Inga capitata, Inga meissneriana

[0009]

Sabicea cinerea, Sabicea glabrescens, Sabicera velutina, Sabicea villosa, Sabicea hirsuta

[0010]

Eperua falcata

[0011]

Byrsonima verbascifolia, Byrsonima crassifolia, Byrsonima chrysophylla, Byrsonima coriacea

[0012]

Astrocaryum vulgare, Astrocaryum murumuru, Astrocaryum chambira, Astrocaryum jauari, Astrocaryum macrocalyx

[0013]

Priva lappulacea

[0014]

Coutoubea spicata, Coutoubea ramosa

[0015]

Siparuna guianensis, Siparuna emarginata

[0016]

Goupia glabra

[0017] In a preferred embodiment of the invention however, giving extracts with a qualitatively and quantitatively optimised action particularly in respect of the anti-radical-type action, the active ingredient comprises at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Astrocaryum vulgare, Siparuna guianensis, Eperua falcata, Byrsonima verbascifolia, Priva lappulacea, Coutoubea spicata and Goupia glabra.

[0018] Owing to their many forms of action these extracts are advantageously used alone or combined together or with other active compounds in products designed mainly to control ageing skin, hyper-pigmentation of the skin, patches of pigment, loss of skin elasticity, wrinkles, irritation and inflammation (treatment of sensitive skin types), irritation caused by environmental pollution and/or sunshine and/or for slimming formulae.

[0019] The parts of the plants used to prepare and obtain the above-mentioned extracts are chosen from roots, cortices (roots, stalks and/or trunk of plants) leaves and foliated stalks, fruit, grains and/or blossoms.

[0020] When the parts of the appropriate plants have been gathered and dried they are subjected to an extraction process. The solvent used may advantageously be selected from the group formed by water, alcohols, ketones, esters, types of ether, chlorine-containing solvents or polyhydric alcohols, or mixtures of at least two of the above-mentioned miscible solvents.

[0021] In a special embodiment of the present invention the extract or extracts is/are obtained by an extraction process based on wave radiation, for example microwaves or ultrasound.

[0022] The extracts involved in the invention may alternatively be obtained by extraction of supercritical CO2, alone or mixed with a secondary solvent.

[0023] In a special embodiment of the present invention the plant extract(s) comprise(s) one or more separated fractions, purified particularly by chromatography and based on one or more extracts of said plants obtained by one of the aforementioned extraction processes.

[0024] To illustrate the invention, though without restricting its scope, various processes which can be carried out to prepare the above-mentioned plant extracts will now be described.

[0025] In the following examples the parts of the plants used are only given as an indication. The extracts involved in the invention can be obtained from any accessible parts of the aforementioned plants.

EXAMPLE 1

[0026] Cortices of Epurea falcata trunk are crushed then mashed finely by a blade-type pulping machine.

[0027] Three litres of distilled water are put into a reactor with an agitator then the following operations are successively carried out, comprising:

[0028] adding 300 g of pulped cortex to the reactor

[0029] extracting with agitation for an hour while boiling

[0030] cooling to ambient temperature

[0031] removing the insoluble materials by centrifuging or filtering

[0032] filtering the materials floating on the surface to a porosity of about 0.45 μm

[0033] collecting the filtrate

[0034] extracting the residue with 2 litres of distilled water under the same operating conditions and proceeding as described above

[0035] after determining the content of dry material relative to the aqueous extracts obtained, adding substance of the malto dextrin type to obtain ⅔ added substance to ⅓ extracted dry material

[0036] de-watering the solution obtained, by spraying or another method known to a person skilled in the art (dehydrating, freeze drying—lyophilisation, drying in a drying chamber etc).

[0037] The total yield of dry extract from this process is 15% by weight relative to the cortices.

EXAMPLE 2

[0038] Cortices of Inga bourgoni trunk are crushed then mashed finely by a blade-type pulping machine.

[0039] Three litres of 50% ethyl alcohol (ethanol) are put into a reactor with an agitator then the following operations are successively carried out, comprising:

[0040] adding 300 g of pulped cortex to the reactor

[0041] extracting with agitation for an hour and with (reflux) heating

[0042] cooling to ambient temperature

[0043] removing the insoluble materials by filtering

[0044] filtering the materials floating on the surface to a porosity of about 0.45 μm

[0045] collecting the filtrate

[0046] extracting the residue with 1.5 litre of 50% ethanol under the same operating conditions then proceeding as described above

[0047] evaporating the alcohol phase of both filtrates under vacuum

[0048] after centrifuging and determining the content of dry material, if necessary making the addition to the aqueous phases obtained in the same proportions as mentioned in Example 1

[0049] if necessary de-watering (dehydrating) the solution obtained, by conventional methods.

[0050] The total yield of dry extract from this process is 13.8% by weight relative to the cortices.

EXAMPLE 3

[0051] Cortices of the roots of Byrsonima verbascifolia are crushed then mashed finely by a blade-type pulping machine.

[0052] Three litres of 80% methyl alcohol (methanol) are put into a reactor with an agitator then the following operations are successively carried out, comprising:

[0053] adding 300 g of pulped cortex to the reactor

[0054] extracting with agitation for an hour and with (reflux) heating

[0055] cooling to ambient temperature

[0056] filtering off the insoluble materials

[0057] filtering the materials floating on the surface to a porosity of about 0.45 μm

[0058] collecting the filtrate

[0059] extracting the residue with 1.5 litre of 80% methanol under the same operating conditions then proceeding as described above

[0060] evaporating the methanol phase of both filtrates under vacuum

[0061] after centrifuging and determining the content of dry material, making the addition to the aqueous phase obtained in the same proportions as described in Example 1

[0062] if necessary de-watering the solution by conventional methods.

[0063] The total yield of extract obtained by this method is 17.4% by weight relative to the cortices.

EXAMPLE 4

[0064] Roots of Astrocaryum vulgare are crushed then finely pulped.

[0065] Three litres of absolute ethanol are put into a reactor with an agitator then the following operations are successively carried out, comprising:

[0066] adding 300 g of crushed Astrocaryum vulgare roots to the reactor

[0067] extracting with agitation for an hour and with (reflux) heating

[0068] cooling to ambient temperature

[0069] filtering off the insoluble materials

[0070] filtering the materials floating on the surface to a porosity of about 0.45 μm

[0071] collecting the filtrate corresponding to Extract 1

[0072] extracting the residue with 3 litres of ethanol under the same operating conditions then proceeding as described above to obtain Extract 2

[0073] evaporating the ethane phase of both filtrates under vacuum at 40° C.

[0074] removing the traces of solvent by drying the extracts in a ventilated drying oven at 40-50° C.

[0075] 7.15 g E1 extract and 1.47 g E2 extract are thus obtained and are finally mixed, representing a total yield of extract of 2.87% by weight relative to the roots.

[0076] The following table contains a list of all the plants and extracts with which the inventors worked, as an indication.

1% yield (2Plant partssuccessivePlantextractedType of extractextractions)AppearanceClidemia hirtaLeavesAqueous extract20.9Brown powderInga bourgoniCorticesAqueous extract9.7Wine-red powderEthanol E 50%13.8Wine-red powderEthanol extract11.7Wine-red powderSabicea cinereaFoliatedAqueous extract16.4Brown powderstalksEthanol E 50%25.5Brown powderEthanol extract18.7Green pasteAstrocaryumRootsAqueous extract5.3Brown powdervulgareEthanol E 50%5.6Brown powderEthanol extract2.8Brown-orangepasteSiparunaLeavesAqueous extract16.1Brown powderguianensisMethanol E 80%21.9Brown powderEthanol extract22.6Green pasteEperua falcataCorticesAqueous extract15Brown powderMethanol E 80%17.6Brown powderEthanol extract16.7Brown pasteByrsonimaRootAqueous extract10.8Brown powderverbascifoliacorticesMethanol E.80%17.4Brown powderEthanol extract15.7Brown pastePrivaFoliatedAqueous extract24.0Brown powderlappulaceastalksMethanol E 80%14.5Brown powderEthanol extract13.9Brown pasteGoupia glabraLeavesAqueous extract30.0Brown-orangeMethanol E 80%30.4powderYellowish powderCoutoubea spicataStalks +earsAqueous extract18.5Brown powderMethanol E 80%18.8Brown powderEthanol extract18.0Brown-green paste

[0077] It was possible for the biological and biochemical properties and actions of the plant extracts studied, which may be used directly in products of cosmetic importance, to be determined and measured by tests known to a person skilled in the art. The principles of the tests will be briefly discussed below and the results will be set out in the corresponding tables.

[0078] 1) Anti-radical-type Action

[0079] The oxidative anti-stress properties were evaluated by “in tubo” and “in vitro” tests.

[0080] The group of in tubo tests includes both the initial radical-type forms of oxygen and the reactive forms introduced in vivo: radical hydroxyl (HO° and anion superoxide (O{overscore (2°)}).

[0081] 1) “Chemical” Tests in Tubo

[0082] a) Anti-DPPH Test

[0083] DPPH (diphenylpicryl hydrazyl)is a free, stable, violet-coloured radical which, in its leuco derivative, is modified by substances which capture free radicals (neutralising effect, also described as a “scavenger effect”).

[0084] The result is given as percent inhibition of DPPH° in radical form relative to the control material without extract.

[0085] b) Anti-HO° Test with Salicylic Acid (Fenton Reaction)

[0086] The HO° (formed by H2O2 with Fe++ and EDTA present) hydroxylate the salicylic acid, which then forms a reddish compound.

[0087] The optical density at 490 nm corresponds to the hydroxylated salicylic acid content.

[0088] An anti-radical substance reacts with the HO° radicals and reduces the formation of this red compound.

[0089] The results are given as percent inhibition of the hydroxylation content (average of 2 tests).

[0090] c) Anti-HO° Test with Deoxyribose (Fenton Reaction)

[0091] The HO° (formed by H2O2 with Fe++ and EDTA present) oxidise the deoxyribose to aldehyde derivatives which are then metered by thiobarbiturate acid.

[0092] The thiobarbiturate acid is condensed with the aldehydes to form a pink compound (DO at 532 nm).

[0093] The Fenton reaction is also carried out without EDTA in order to measure the ability to complex iron; the deoxyribose is then oxidised by HO°.

[0094] The results are given as percent inhibition (an average of 2 tests).

[0095] 2) “Biochemical” in Tubo Tests=Anti-anion Superoxide O{overscore (2°)} Tests

[0096] Xanthine oxidase is an enzyme which is introduced during oxidative stress and catabolises the purine bases (adenine and guanine) to uric acid and {overscore (2°)}.

[0097] {overscore (2°)} is dismutated spontaneously (or by SOD=superoxide dismutase) to H2O2 and O2.

[0098] a) Anti-{overscore (2°)} Action: Method with Luminol

[0099] {overscore (2°)} can be recognised in terms of luminescence by Luminol.

[0100] An enzyme system (hypoxanthine/xanthine oxidase) forms the superoxide anions {overscore (2°)} which react with Luminol to form an intermediate compound. When stabilised this compound emits luminescence which is picked up by a photomultiplier.

[0101] A substance with an anti-radical action absorbs or destroys the anion {overscore (2°)}, thereby reducing the formation of luminescence.

[0102] b) Anti-{overscore (2°)} and H2O2 Action: Method with Luminol in the Presence of Microperoxidase

[0103] An enzyme system (hypoxanthine/xanthine oxidase) forms the superoxide anions {overscore (2°)} which are gradually dismutated to {overscore (2°)} and H2O2.

[0104] H2O2 and {overscore (2°)} react with the microperoxidase (M) to form O21 (singlet oxygen) which degrades Luminol (Lum), forming a luminescent compound, the light emission from which is picked up by a photomultiplier.

[0105] An anti-radical substance absorbs either H2O2 or {overscore (2°)} or O21, thereby reducing the formation of luminescence.

[0106] c) Anti-{overscore (2°)} Action: Method with NBT (Tetrazole Salt)

[0107] An enzyme system (hypoxanthine/xanthine oxidase) forms superoxide anions {overscore (2°)} which react with the NBT to form a red composition, formazan.

[0108] An anti-radical substance absorbs or destroys {overscore (2°)}, thereby reducing the formation of formazan.

[0109] The results of these three tests a), b) and c) are given as percent inhibition (average of 2 tests).

[0110] The results of above-mentioned tests 1) and 2) are set out in the following table:

2ARLFenton test (% 1)HX + XOD test(%1)Salicylic(%1)PlantType of exactDPPHacidDeoxyriboseLUMLUM + MNTBClidemiaAqueous extract914070995153hirtaInga bourgoniAqueous extract94401009864Ethanol E 50%94271009871Ethanol extract95741009983SabiceaAqueous extract904739998941cinereaEthanol E 50%9439501009962Ethanol extract93511009850AstrocaryumAqueous extract76982723vulgareEthanol E 50%931009874Ethanol extract93485910010081SiparunaAqueous extract92996747guianensisMethanol E 80%94471009971Ethanol extract3849999654EperuaAqueous extract911008549falcataMethanol E 80%91999461Ethanol extract946410010089ByrsonimaAqueous extract958010010083verbascifoliaMethanol E 80%958410010075Ethanol extract947510010080PrivaAqueous extract95461007035lappulaceaMethanol E 80%10051451009745Ethanol extract93371009644Goupia glabraAqueous extract9649321009434Methanol E 80%89613110090CoutoubeaAqueous extract92799941spicataMethanol E 80%938110089Ethanol extract92729950Lum: Luminol; Lurn + M: Luminol + microperoxidase

[0111] II) Anti-UVA Cell Protection on Human Fibroblasts in “in vitro” Survival

[0112] A) Metering of the Salted-out MDA (Morliére P. and Colleagues: “UV-A Lipid Peroxydation in Cultured Human Fibroblasts”, Biochim. Biophys. Acta 1084, 3: 261-269,1991)

[0113] 1) The Theory

[0114] The UV-A penetrate into the dermis, where they set up an oxidative stress indicated particularly by lipoperoxidation of the cytoplasmic membranes.

[0115] Lipoperoxides are fragmented into malonal dialdehyde, which will crosslink/connect many biological molecules, for example proteins (enzyme inhibition) and nuclein bases (mutagenesis).

[0116] 2) The Procedure

[0117] The fibroblasts are injected into a culture medium defined by calf's foetus serum.

[0118] The plant extract (in the culture medium defined by 2% serum) is added 72 hours after injection.

[0119] After 48 hours' incubation at 37° C. and CO2=5% the culture medium is replaced by a saline solution and the fibroblasts are irradiated with a dose of UV-A (15 J/cm2).

[0120] When irradiation is over the MDA (malonal dialdehyde) rate in the saline solution floating on the surface is metered and the protein rate in the fibroblasts is measured.

[0121] MDA is metered by the reaction on thiobarbiturate acid, and proteins by the so-called Bradford method.

[0122] B) Protecting the Action of the Catalase Enzyme from UVA

[0123] 1) The Theory

[0124] UVA penetrates into the dermis where it sets up an oxidative stress, causing a lessening of the action of many enzymes including catalase.

[0125] Catalase is an enzyme which enables the H2O2 produced spontaneously by oxidation of substrates such as glucose or hypoxanthine to be removed.

[0126] H2O2 has to be removed quickly, otherwise it forms very toxic hydroxyl radicals (HO°) if iron is present.

[0127] 2) The Procedure

[0128] (by L H Johansson and L A H Borg in “A spectrophotometric method for determination of catalase activity in small tissue samples”, Anal. Biochem. 174, 331-336, 1988).

[0129] Fibroblasts are injected into a culture medium defined by calf's foetus serum.

[0130] The plant extract (dissolved in a defined culture medium containing 2% serum at a concentration of 0.01 to 0.05% by wt/vol) is added 72 hours after injection.

[0131] After 48 hours' incubation at 37° C. and CO2=5% the culture medium is replaced by a saline solution and the fibroblasts are irradiated with a dose of UV-A (5 J/cm2).

[0132] When irradiation is over the rate of the active catalase is metered by a spectrophotometric method and its activity is related to the protein rate measured in the fibroblasts.

[0133] The action of the plant extract is given as a percent increase in catalase activity relative to the irradiated control material in the absence of any plant extract (two tests on average).

[0134] III) Evidence of the Anti-UVB Cell Protection Effect on Human Keratin Cells in “in vitro” Survival

[0135] 1) The Theory

[0136] UV-B causes slight inflammation (erythema, oedema) by activating an enzyme, phospholipase A2.

[0137] This enzyme removes the arachidonic acid from the phospholipids of the plasmic membrane. Arachidonic acid is the precursor of prostaglandins, including E2 prostaglandins (=PGE2), which are formed by cyclooxygenase.

[0138] 2) The Procedure

[0139] A431 keratin cells are injected into a culture medium defined by calf's foetus serum. After 72 hours' incubation at 37° C. and CO2=5% the culture medium is replaced by a saline solution containing the plant extract to be tested. The keratin cells are immediately irradiated with a dose of UV-B (30 mJ/cm2) and incubated for 24 hours at 37° C., then the PGE2 and LDH rates in the culture medium floating on the surface are measured.

[0140] The number of adhering keratin cells is determined by a particle counter (after trypsination) and the PGE2 rate by an ELISA test.

[0141] The LDH (lactate dehydrogenase) rate is also determined by an enzyme reaction. LDH is a cytoplasmic enzyme which marks cell disorders.

[0142] The activity of the plant extract is tested and given as the percent inhibition of the two markers relative to the values reached with the control materials (2 tests on average, each in duplicate).

[0143] IV) “Anti-protease” Activity

[0144] The proteases which have been separated from the neutrophil polymorphonuclear substance during a slight inflammation or by fibroblasts exposed to UV-A radiation cause decomposition of the proteins which structure the extracellular matrix of the dermis.

[0145] Two types of protease were tested by enzyme reactions in tubo.

[0146] 1) Anti-elastase test (Bieth J., “Elastase: structure, function and pathological role”, Front Matrix Biol. 6: 1-82, Karger, 1978).

[0147] PNN segregate an elastase which is active on elastins (serine protease), proteoglycans and collagens.

[0148] The in tubo tests are carried out on an elastase from the pancreas (serine protease) using two types of substrate: a synthetic, chromogenic one (SS test) and a natural substrate, namely elastin combined with Congo red (Rc test).

[0149] The incubations take 30 minutes at ambient temperature or 2 hours at 37° C. and the colouring effects are in each case measured at 410 and 520 nm.

[0150] The inhibition proof mass which is tested as a comparison is α-1 antitrypsin.

[0151] 2) Anti-collagenase in tubo test (Van Wart and colleagues, “A continuous spectrophotometric assay for Clostridium histolyticum collagenase”, Anal. Biochem., 113, 356-365, 1981).

[0152] Collagenase is segregated by PNN during a slight inflammation and by the “old” or irradiated fibroblasts.

[0153] The tests are carried out with a clostridium hystoliticum collagenase and a synthetic chromogenic substrate, FALGPA.

[0154] Incubation takes 30 minutes at ambient temperature and the optical density is measured at 324 nm.

[0155] The results are given as percent inhibition of the enzyme relative to the control material without activator.

[0156] The inhibition control material tested as a comparison is cysteine.

[0157] The results of test series II) III) and IV) are listed in the following table:

3Catalase %increase inUV-Aactivity/Elastase(%1)radiated controlUV-B (%)(%)CollagenasePlantType of extractMDAMaterialPGE2LDHRcSS(%)ClidemiaAqueous extract2367926793hirtaInga bourgoniAqueous extract7178927234100Ethanol E 50%7058859138100Ethanol extract10010051SabiceaAqueous extract74951006883cinereaEthanol E 50%86407560100Ethanol extract7881871004727AstrocaryumAqueous extract917897915vulgareEthanol E 50%8268792956100Ethanol extract7579831007591SiparunaAqueous extract7960862936guianensisMethanol E 80%72555075786299Ethanol extract21EperuaAqueous extract7910010036falcataMethanol E 80%669910085Ethanol extract5988934972ByrsonimaAqueous extract6323709210068100verbascifoliaMethanol E 80%6626648910186100Ethanol extract4224507310068100PrivaAqueous extract262127lappulaceaMethanol E 80%Ethanol extract7099Goupia glabraAqueous extractMethanol E 80%CoutoubeaAqueous extractspicataMethanol E 80%Ethanol extract47MDA: malonal dialdehyde, PGE2: prostaglandin E2, LDH: lactate dehydrogenase, %1: percent inhibition relative to control material.

[0158] V) Inhibition of Melanogenesis

[0159] 1) Inhibition of Tyrosinase “in Tubo”

[0160] Tyrosinase is the key enzyme in the synthesis of the melanin in the melanocytes of the human skin.

[0161] This enzyme catalyses the first two stages in the conversion of tyrosine to melanin, i.e. oxidation of melanin to DOPA (dihydroxyphenylalanine) and subsequently to dopachrome.

[0162] Dopachrome is a coloured compound which is quantified at 475 nm by spectrophotometry.

[0163] The activity of the enzyme used in tubo (obtained from fungi) is determined as 20 seconds by the kinetics of the reaction.

[0164] The proof mass substance is hydroquinone (C150=0.025% wt/vol).

[0165] The results are expressed as percent inhibition relative to the control material.

[0166] 2) Inhibition of Melanogenesis on B16 Melanocytes in the “in vitro” Culture

[0167] Inhibition of melanogenesis is assessed by spectrophotometric dosing of the melanin produced by melanocytes (B16 line), incubated “in vitro” in the presence of the plant extract to be tested.

[0168] The B16 melanocytes are cultivated in a defined growth medium and incubated for 3 days at 37° C., CO2=5%.

[0169] The plant extracts are dissolved in a medium which activates melanogenesis and put into contact with the B16 for 3 days at 37° C.

[0170] The rate of salted-out melanin in the medium floating on the surface is quantified by spectrophotometry at 475 nm.

[0171] The rate of intra-cellular melanin is quantified by spectrophotometry at 475 nm in the homogenised B16 cells, which have been dissolved in a mixture of NaOH 1N+10% (v/v) DMSO.

[0172] The protein rate in the homogenised B16 cells is quantified by the so-called Bradford method.

[0173] The comparative substances are hydroquinone and arbutin.

[0174] VI. Evidence of Activity Inhibiting Non-enzymatic in Tubo Glycation (“Anti-glycation Activity)

[0175] (DEYL and colleagues: “Increased glycation and pigmentation of collagen in aged and young parabiotic rats and mice”, Mechanisms of ageing and development, 55, 39-47, 1990/MONNIER and colleagues: “Accelerated age-related browning of human collagen in diabetes mellitus”, Proc. Natl. Acad. Sci., USA: 81 583-587, 1984)

[0176] Non-enzymatic glycation of proteins is a crucial process in the ageing of human tissue.

[0177] This reaction, discovered by Maillard, explains the reticulation of extracellular matrices and base membranes which are mainly responsible for pathologies observed in diabetics.

[0178] In addition, Schiff's bases catalyse the production of reactive forms of oxygen, which worsen the effects of non-enzymatic glycation.

[0179] The in tubo tests are carried out on I-type collagen incubated for 21 days at 45° C. in the presence of 1% (p/v) glucose.

[0180] The rate of the Schiff's bases is assessed by fluorimetry at 430 nm (excitation at 350 nm) in the substances floating on the surface (fs) and in the centrifuging deposits (fgc). The result is given as percent inhibition relative to the control material without plant extract.

[0181] VII) Activation of Lipolysis on Human Adipocytes in “in vitro” Survival

[0182] Lipolysis is removal of triglycerides (or TG) stored in the adipocytes by an enzyme, triglyceride lipase (or TGL), causing the TG to be split into free fatty acid and glycerol, which are eliminated in the bloodstream.

[0183] The fatty acids can then be absorbed by muscle cells to produce energy.

[0184] The in vitro test is carried out as described below:

[0185] Activation of lipolysis is metered by spectrophotometric metering of the rate of glycerin salted out by adipocytes, incubated “in vitro” with the substance to be tested present.

[0186] The adipocytes are liberated by enzymatic digestion of subcutaneous human tissue by the so-called Rodbell method (Rodbell M., “Metabolism of isolated fat cells”, The journal of biological chemistry, vol. 239, no. 2, pages 375 to 380, 1964).

[0187] The plant extracts are dissolved in a defined medium which is put into contact with the adipocytes for 90 minutes at 37° C.

[0188] The rate of salted-out glycerin is quantified by spectrophotometry in a medium which floats on the surface by the method of Carpéné C. and colleagues (J. Pharmacol., vol. 12, no. 2, pages 219-224, 1981).

[0189] The rate of liberated glycerin is given relative to the rate of all lipids metered by turbidimetry. The result is given as a percent increase relative to the control material without plant extract.

[0190] The comparative substances are theophylline and isoprenaline.

[0191] The results of test series V), VI) and VII) are summarised in the following table:

4Anti-glycationB16 MelaninType ofTyrosinase(%)Mel.LipolysisPlantExtractC150CA50fsfgcDoseIndexextra% increaseClidemiaAqueous E.0.313750hirtaIngaAqueous E.0.060100760.053.968bourgoniEthanol E 50%0.0700.033.580Ethanol E0.0100.021.410SabiceaAqueous E.2150cinereaEthanol E 50%0.0900.011.649Ethanol E.0.0600.031.810AstrocaryumAqueous E.vulgareEthanol E 50%0.63Ethanol E.0.23SiparunaAqueous E.guianensisMethanol E 80%Ethanol E.EperuaAqueous E.9746falcataMethanol E 80%0.3830Ethanol E.0.0800.011.593ByrsonimaAqueous E.0.0900.021.772verb.Methanol E 80%0.0500.022.591Ethanol E.0.0100.032.558PrivaAqueous E.0.35lappulaceaMethanol E 80%0.13Ethanol E.0.060GoupiaAqueous E.0.037glabraMethanol E 80%CoutoubeaAqueous E.0.64spicataMethanol E 80%0.39Ethanol E.0.27In the above table: C150: concentration of active substances by weight/volume giving 50% inhibition CA50: concentration of active substances by weight/volume giving 50% activation Dose: concentration of active substances tested by weight/volume Index (B16 melanin): protein rate/rate of intracellular melanin Mel. extra: rate of extracellular melanin (salted out in the substance floating on the surface) as percent inhibition.

[0192] In evaluating the results of the above test tables the inventors worked out various preferred embodiments of the invention.

[0193] To obtain a cosmetic or dermo-pharmaceutical composition giving an increased anti-elastase action as well as an anti-radical-type action, the active ingredient contained in said composition and passing on these properties is advantageously formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Astrocaryum vulgare, Siparuna guianensis, Eperua falcata, Byrsonima verbascifolia and Priva lappulacea.

[0194] To obtain a cosmetic or dermo-pharmaceutical composition giving an increased anti-collagenase action as well as an anti-radical-type action, the active ingredient contained in said composition and passing on these properties is advantageously formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Astrocaryum vulgare, Siparuna guianensis, Eperua falcata, Byrsonima verbascifolia and Priva lappulacea.

[0195] To obtain a cosmetic or dermo-pharmaceutical composition giving an increased de-pigmenting action as well as an anti-radical-type action, the active ingredient contained in said composition and passing on these properties is advantageously formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Eperua falcata, Byrsonima verbascifolia, Priva lappulacea, Astrocaryum vulgare and Coutoubea spicata.

[0196] To obtain a cosmetic or dermo-pharmaceutical composition giving an important anti-UVB action as well as an anti-radical-type action, the active ingredient contained in said composition and passing on these properties is advantageously formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Astrocaryum vulgare, Siparuna guianensis, Eperua falcata, Byrsonima verbascifolia and Priva lappulacea.

[0197] To obtain a cosmetic or dermo-pharmaceutical composition giving an important anti-UVA action as well as an anti-radical-type action, the active ingredient contained in said composition and passing on these properties is advantageously formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Astrocaryum vulgare, Siparuna guianensis, Eperua falcata, Byrsonima verbascifolia and Priva lappulacea.

[0198] To obtain a cosmetic or dermo-pharmaceutical composition giving an action protecting catalase from UVA as well as an anti-radical-type action, the active ingredient contained in said composition and passing on these properties is advantageously formed by at least one extract of a plant selected from the group formed by Sabicea cinerea, Siparuna guianensis and Byrsonima verbascifolia.

[0199] To obtain a cosmetic or dermo-pharmaceutical composition giving a strong anti-glycation action as well as an anti-radical-type action, the active ingredient contained in said composition and passing on these properties is advantageously formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea and Eperua falcata.

[0200] To obtain a cosmetic or dermo-pharmaceutical composition giving an important pigmenting action as well as an anti-radical-type action, the active ingredient contained in said composition and passing on these properties is advantageously formed by an extract of the Goupia glabra plant.

[0201] To obtain a cosmetic or dermo-pharmaceutical composition giving a considerable slimming (lipolytic) action as well as an anti-radical-type action, the active ingredient contained in said composition and passing on these properties is advantageously formed by an extract of the Eperua falcata plant.

[0202] However the active ingredient is preferably formed by an extract or a mixture of extracts obtained from one or more plants selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Astrocaryum vulgare, Siparuna guianensis, Eperua falcata, Byrsonima verbascifolia and Priva lappulacea.

[0203] The object of the present invention also concerns a cosmetic or dermo-pharmaceutical composition for topical, external use on the skin, mucous membrane and/or the epithelium or body appendages, characterised in that it contains a plant extract as the active ingredient giving an anti-radical-type action in particular, alone or with at least one other added ingredient, the botanical genus of the plant belonging to the group formed by the Clidemia, Inga, Sabicea, Astrocaryum, Siparuna, Eperua, Byrsonima, Priva, Couloubea and Groupia genera, and that a plant in the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Astrocaryum vulgare, Siparuna guianensis, Eperua falcata, Byrsonima verbascifolia, Priva lappulacea, Coutoubea spicata and Goupia glabra is preferably selected.

[0204] According to the other additional properties relating to the anti-radical-type action which the cosmetic or dermo-pharmaceutical composition may need to provide, the group of plants which may be selected from the above-mentioned ones will contain various representatives according to the action of each of them disclosed in the tables showing the results of the tests described above.

[0205] Thus in a first embodiment of the invention the cosmetic or dermo-pharmaceutical composition may contain an active ingredient with an anti-UVA, anti-UVB and anti-collagenase action, which is formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Astrocaryum vulgare, Siparuna quianensis, Eperua falcata and Byrsonima verbascifolia.

[0206] In a second embodiment of the invention the cosmetic or dermo-pharmaceutical composition may contain an active ingredient with an anti-UVA, anti-UVB, anti-collagenase and anti-elastane action, which is formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Astrocaryum vulgare, Siparuna guianensis, Eperua falcata and Byrsonima verbascifolia.

[0207] In a third embodiment of the invention the cosmetic or dermo-pharmaceutical composition may contain an active ingredient with an anti-UVA, anti-UVB, anti-collagenase and anti-glycation action, which is formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea and Eperua falcata.

[0208] In a fourth embodiment of the invention the cosmetic or dermo-pharmaceutical composition may contain an active ingredient with an anti-UVA, anti-UVB, anti-collagenase, anti-elastane and de-pigmenting action, which is formed by at least one extract of a plant selected from the group formed by Clidemia hirta, Inga bourgoni, Sabicea cinerea, Eperua falcata and Byrsonima verbascifolia.

[0209] In a fifth embodiment of the invention the cosmetic or dermo-pharmaceutical composition may contain an active ingredient with a pigmenting action, which is formed by an extract from the Goupia glabra plant.

[0210] In a sixth embodiment of the invention the cosmetic or dermo-pharmaceutical composition may contain an active ingredient with a slimming action, which is formed by an extract from the Eperua falcata plant.

[0211] The cosmetic composition advantageously contains as its active ingredient—alone or combined with other active ingredients—between 0.001% and 20% by weight, preferably between 0.1% and 3% by weight, of an extract or mixture of extracts from a plant or plants defined and obtained in the above-mentioned manner.

[0212] The extract or mixture of extracts forming an active ingredient may be used in any galenic form possible in cosmetics, particularly in a galenic form chosen from oil in water emulsions, water in oil emulsions, face lotions, cosmetic milk, gels, hydrogels, cremes, pomades, soaps, pellets, spraying materials, hair lotion and shampoos.

[0213] The extract or mixture of extracts may also be added to one or more cosmetic vectors, particularly one or more vectors selected from the group formed by liposomes, macrocapsules, microcapsules, nanocapsules, macro-particles, microparticles and nanoparticles.

[0214] Various products or cosmetic preparations containing a plant extract as described above will now be described, as examples to which the practical use of the invention is not limited.

EMXAMPLE 1

[0215] A cosmetic product in the form of a skin bleaching cream may for example be of the following composition by weight:

5Fraction A:Glycerin stearate and Ceteareth-2015.0% Paraffin oil3.0%Ascorbyl palmitate3.0%Dimethicon3.0%Cetyl alcohol0.5%PEG 30 glycerol isostearate2.0%Fraction B:Water72.2% Methyl parabene0.2%Imidazolinidyl urea0.3%Ethanol extract of Inga bourgoni0.5%Fraction CPerfume0.3%

[0216] The procedure for preparing this cream consists of melting the Fraction A constituents with agitation at 75° C., preparing Fraction B at 75° C. then pouring Fraction B into Fraction A with turbine agitation, cooling with planetary agitation then adding to Fraction C.

EXAMPLE 2

[0217] A cosmetic product in the form of an anti-blotch emulsion for the hands, to treat cutaneous pigment marks, may for example be of the following composition by weight.

[0218] In accordance with the invention the product could alternatively have multiple actions, particularly anti-radical, anti-elastase and anti-collagenase.

6Fraction A:Glycerin stearate and PEG 100 stearate6.0%Olein alcohol1.5%Glycerin stearate2.0%Steareth 22.0%Karite butter3.0%Dimethicon4.0%Caprylic capric triglyceride8.0%Propyl parabene0.1%Tocopherol acetate0.1%Fraction B:Water60.8% Elastab 388 (Laboratoires Serobiologiques)2.5%Byrsonima verbascifolia extract (80% methanol)1.5%Ethanol Astrocaryum vulgare extract1.5%Propylene glycol5.0%Fraction C:Polyacrylamide, isoparaffin and Laureth 72.0%

[0219] The procedure for making this emulsion consists of preparing Fractions A and B separately at 75° C., adding Fraction A to Fraction B with turbine agitation at 75° C., cooling to 50° C. then adding Fraction C and lastly cooling the final mixture to ambient temperature.

EXAMPLE 3

[0220] A cosmetic product in the form of an anti-wrinkle day cream and a multiple-action anti-ageing cream may for example be of the following composition by weight:

7Fraction A:Glycerin stearate14.0% Octyl dodecanol16.0% Dibutyl adipate6.0%Ceteareth 121.5%Ceteareth 201.5%Fraction B:Propylene glycol5.0Aqueous extract of Inga bourgoni3.25% Extract of Sabicea cinerea (50% ethanol)1.0%Ethanol extract of Eperua falcata0.75% Elastab 4112 (Laboratoires Serobiologiques)0.4%Water50.6% Fraction C:Perfume0.3%

[0221] The procedure for making the cream comprises preparing Fractions A and B separately at 80° C. with agitation, adding Fraction A to Fraction B with turbine agitation, cooling the mixture to 45° C. then adding Fraction C, and lastly bringing the final mixture back to ambient temperature.

[0222] The invention is not of course restricted to the embodiments described and illustrated in the accompanying drawings. Modifications are possible, particularly in the composition of the various elements or through replacement by industrial equivalents, without thereby going beyond the scope of the invention.

	Number	Date	Country
Parent	09857445	Jun 2001	US
Child	10307977	Dec 2002	US

Plant extracts with anti-radical type action

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