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DR ANTHONY MELVIN CRASTO, WORLDDRUGTRACKER

(±)-Integrifolin, Compound from plants keeps human cancer cells from multipying

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Jun 202016
 

 

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CAS 89647-87-0

MFC15 H18 O4, MW 262.30
Azuleno[4,​5-​b]​furan-​2(3H)​-​one, decahydro-​4,​8-​dihydroxy-​3,​6,​9-​tris(methylene)​-​, (3aR,​4R,​6aR,​8S,​9aR,​9bR)​-
  • Azuleno[4,5-b]furan-2(3H)-one, decahydro-4,8-dihydroxy-3,6,9-tris(methylene)-, [3aR-(3aα,4β,6aα,8β,9aα,9bβ)]-
  • (3aR,4R,6aR,8S,9aR,9bR)-Decahydro-4,8-dihydroxy-3,6,9-tris(methylene)azuleno[4,5-b]furan-2(3H)-one
  • 8-epi-Deacylcynaropicrin
  • 8β-Hydroxyzaluzanin C
  • Integrifolin (guaianolide)

STR1Integrifolin

 

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PATENT

WO 2011085979

Paper

Two New Amino Acid-Sesquiterpene Lactone Conjugates from Ixeris dentata

 

BLOG POST FROM CHEMISTRY VIEWS, WILEY

thumbnail image: Total Synthesis of (±)-IntegrifolinSTR1STR1STR1

(±)-Integrifolin

Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim

Total Synthesis of (±)-Integrifolin

Compound from plants keeps human cancer cells from multipying

Read more at Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim

Weight control is an important concern of human beings, both for medical (pharmaceutical and/or nutraceutical) as well as non-therapeutic, e.g. cosmetic, reasons. More importantly, excessive accumulation of body fat (i.e. obesity (= adiposity), especially with excessive fat in the ventral region and surrounding the viscera) can be dangerous and has been linked to health problems such as type II diabetes, hypertension, heart disease, atherosclerosis (where more than two of the preceding disorders are present, the condition is often called “Metabolic Syndrome” or “syndrome X”), hyperlipidemia, coronary heart disease, stroke, breast and colon cancer, sleep apnoea, gallbladder disease, reproductive disorders such as polycystic ovarian syndrome, gastroesophageal reflux disease, increased incidence of complications of general anesthesia, fatty liver, gout or thromboembolism (see, e.g., Kopelman, Nature 404: 635-43 (2000)). Obesity reduces life-span and carries a serious risk of the co-morbidities listed above, as well disorders such as infections, varicose veins,

acanthosis nigricans, eczema, exercise intolerance, insulin resistance, hypertension hypercholesterolemia, cholelithiasis, orthopedic injury, and thromboembolic disease (Rissanen et al, Br. Med. J. 301 : 835-7 (1990)). Obesity is one of the main factors in the development of cardiovascular diseases. As a side effect the levels of cholesterol, blood pressure, blood sugar and uric acid in obese people are usually higher than those of persons of normal weight. The morbidity from coronary heart disease among the overweight people is increased as well. Among the people aged 40-50, mortality will rise about 1% when body weight increases by 0.5 kg and the death rate will increase 74% when body weight exceeds 25% of the standard. The prevalence of obesity in the United States has more than doubled since the turn of the last century (whole population) and more than tripled within the last 30 years among children aged from 6 to 11. This problem more and more becomes a disease risk also in Europe. In Germany, particularly many people have been found to suffer from overweight recently, already 25% of the young people, children and adolescents there are affected by obesity and related disorders. Furthermore, being overweight is considered by the majority of the Western population as unattractive.

Overweight and obesity result from an imbalance between the calories consumed and the calories used by the body. When the calories consumed exceed the calories burned, the body is in positive energy balance and over time weight gain will occur. The excess calories are stored in the fat cells. When the calories burned exceed the calories consumed, the body is in negative energy balance and over time weight loss will occur.

Determinants of obesity include social factors, psychological factors, genetic factors, developmental factors and decreased physical activity. Some components of a comprehensive weight loss programs include medical assessment, behavioural and dietary modification, nutrition education, mental and cognitive restructuring, increased physical activity, and long term follow-up.

An increasing interest by consumers in the maintenance or reduction of their body weight can be found. This leads to a demand for products useful for these purposes. Preferred are such food products which can conveniently be consumed as part of the daily diet, for example meal replacer products, such as meal replacer bars and beverages. These are usually designed for use as a single-serving food product to replace one or two meals a day.

An issue is that often a saturating effect is missed when such products are consumed, resulting in hunger feelings only a relatively short time after consummation or even in the lack of a saturation feeling already directly after consummation.

Summing up, there remains a need for new safe and effective compositions for promoting weight loss and/or loss of body fat in subjects such as humans. The problem to be solved by the present invention is therefore to find compositions or compounds useful in the treatment of obesity; and/or for improving the total cholesterol HDIJLDL ratio.

Phytochemistry provides a large pool of compounds and compositions to be looked at whether they are able to solve this problem.

The present invention provides methods and compositions useful in the control, treatment and prevention of obesity and obesity-related conditions, disorders, and diseases; and/or and/or for improving the total cholesterol HDL/LDL ratio.

Rosinski, G., et al., Endocrinological Frontiers in Phyiological Insect Ecology, Wroclow Technical University Press, Wroclow 1989, describe that certain tricyclic sequiterpene lactones, such as grossheimin and repin, showed inhibition of larval growth and antifeeding activity in Mealworm (Tenebrio σιοΐϊίοή. Grossheimin shows no anti-feeding but little decrease of absorption of digested food constituents and a little decrease in efficiency in digesting. Repin exhibit low effects at all. Both compounds show no effect on lipid levels in blood.

Shimoda, H., et al, Bioinorganic & Medicinal Chemistry Letters 13 (2003), 223-228, describe that methanolic extracts from Artichoke (Cynara sclolymus L.) with cynaropicrin, aguerin B and grossheimin as components and certain sesquiterpene glycosides suppress serum triglyceride elevation in olive oil-loaded mice. Some of these compounds exhibit a moderate short term (2 hours after olive oil administration) anti-hyperlipidemic activity presented as a lowering of the serum triglyceride (serum TG) concentrations, the long term (6 hours) show in the case of cynaropicrin and aguerine B an increase of the serum TG. Furthermore the authors present data of the gastric emptying (GE) of a methanolic ectract of artichoke. They determine a significantly inhibited GE. However, as shown below, this mechanism is not an explanation for the anti obesity effect shown in the present invention (see Example 1 ).

Fritzsche, J., et al., Eur. Food Res. Technol. 215, 149-157 (2002) describe the effect of certain isolated artichoke leaflet extract components with cholesterol lowering potential. Ahn, E.M-., et al, Arch Pharm. res. 29(1 1 ), 937-941 , 2006, shows ACAT inhibitory activity for two sesquiterpene lactones. KR 20040070985 also shows an effect of certain sesquiterpene lactone derivatives on cholesterol biosynthesis involved enzymes. Gebhard, R., Phytother. Res. 16, 368-372 (2002) and J. Pharmacol. Exp. Ther. 286(3), 1 122-1 128 (1998), shows

enforcement of cholesterol biosynthesis inhibition in HepG2 cells by artichoke extracts. WO 2007/006391 also claims reduction in cholesterol by certain Cynara scolymus variety extracts.

Other reported activities of tricyclic sesquiterpene lactones are antioxidant activity (European Food Research & Technology (2002), 215(2): 149-157), inhibitors of NF kb (Food Style 21 (2007), 1 1 (6): 54-56; JP 2006-206532), serum triglyceride increase-inhibitory effect (Kagaku Kogyo (2006), 57(10): 740-745), hypoglycaemic effect (J. Trad. Med. (2003), 20(2): 57-61), bitter taste (DE 2654184). Any beneficial effects are included in this invention by reference.

None of the documents suggest that a control and treatment of obesity and body fat in warmblooded animals might be possible.

http://www.chemistryviews.org/details/ezine/9412451/Total_Synthesis_of_-Integrifolin.html?elq_mid=10181&elq_cid=1558306

Cynaropicrin, a tricyclic sesquiterpene lactone causes in vivo a strong weight loss. More surprisingly it was found that this effect is not correlated to a decrease in food intake. The weight balance is not affected by reduction of assimilation efficiency; the decrease of body fat and body weight is presumably caused by effects on energy metabolism. Surprisingly, it was found in addition that cynaropicrin also allows for improving the total cholesterol HDL7LDL ratio

Tricyclic sequiterpene lactones or known ingredients of plants of the subclass Asterides, especially from the family of Asteraceae, more specifically from species of the genera of the list consisting of Achilea, Acroptilon, Agranthus, Ainsliaea, Ajania, Amberboa, Andryala, Artemisia, Aster, Bisphopanthus, Brachylaena, Calea, Calycocorsus, Cartolepsis, Centaurea, Cheirolophus, Chrysanthemum, Cousinia, Crepis, Cynara, Eupatorium, Greenmaniella, Grossheimia, Hemistaptia, Ixeris, Jurinea, Lapsana, Lasiolaena, Liatris, Lychnophora, Macroclinidium, Mikania, Otanthus, Pleiotaxis, Prenanthes, Pseudostifftia, Ptilostemon,

Rhaponticum, Santolina, Saussurea, Serratula, Sonchus, Stevia, Taeckholmia, Tanacetum, Tricholepis, Vernonia, Volutarella, Zaluzania; even more specifically from species of the list consisting of Achillea clypeolata, Achillea collina, Acroptilon repens, Agrianthus pungens, Ainsliaea fragrans, Ajania fastigiata, Ajania fruticulosa, Amberboa lippi, Amberboa muricata, Amberboa ramose**, Amberboa tubuliflora and other Amberboa spp.*, Andryala integrifolia, Andryala pinnatifida, Artemisia absinthium, Artemisia cana, Artemisia douglasiana, Artemisia fastigiata, Artemisia franserioides, Artemisia montana, Artemisia sylvatica, Artemisia

tripartita, Aster auriculatus, Bishopanthus soliceps, Brachylaena nereifolia, Brachylaena perrieri, Calea jamaicensis, Calea solidaginea, Calycocorsus stipitatus, Cartolepsis intermedia, Centaurea babylonica, Centaurea bella, Centaurea canariensis*, Centaurea clementei, Centaurea conicum, Centaurea dealbata, Centaurea declinata, Centaurea glastifolia, Centaurea hermanii, Centaurea hyrcanica, Centaurea intermedia, Centaurea janeri, Centaurea kalscyi, Centaurea kandavanensis, Centaurea kotschyi, Centaurea linifolia, Centaurea macrocephala, Centaurea musimomum, Centaurea nicolai, Centaurea pabotii, Centaurea pseudosinaica, Centaurea repens, Centaurea salonitana, Centaurea scoparia, Centaurea sinaica, Centaurea solstitialis, Centaurea tweediei and other Centaurea spp. *, Cheirolophus uliginosus, Chrysanthemum boreale, Cousin ia canescens, Cousinia conifera, Cousinia picheriana, Cousinia piptocephala, Crepis capillaris, Crepis conyzifolia, Crepis crocea, Crepis japonica, Crepis pyrenaica, Crepis tectorum, Crepis virens, Crepis zacintha, Cynara alba, Cynara algarbiensis, Cynara auranitica, Cynara baetica, Cynara cardunculus, Cynara cornigera, Cynara cyrenaica, Cynara humilis, Cynara hystrix, Cynara syriaca, Cynara scolymus**, Cynara sibthorpiana and other Cynara spp.*, Eupatorium anomalum,

Eupatorium chinense, Eupatorium lindleyanum, Eupatorium mohrii, Eupatorium

rotundifolium, Eupatorium semialatum, Greenmaniella resinosa, Grossheimia

macrocephala** and other Grossheimia spp. *, Hemisteptia lyrata, Ixeris chinensis, Ixeris debilis, Ixeris dentata, Ixeris repens, Ixeris stolonifera, Jurinea carduiformis, Jurinea derderioides, Jurinea maxima, Lapsana capillaris, Lapsana communis, Lasiolaena morii, Lasiolaena santosii, Liatris chapmanii, Liatris gracilis, Liatris pycnostachya, Lychnophora blanchetii, Macroclinidium trilobum, Mikania hoehnei, Otanthus maritimus, Pleiotaxis rugosa, Prenanthes acerifolia, Pseudostifftia kingii, Ptilostemon diacanthus, Ptilostemon

gnaphaloides, Rhaponticum serratuloides, Santolina jamaicensis, Saussurea affinis,

Saussurea elegans, Saussurea involucrata, Saussurea laniceps, Saussurea neopulchella** and other Sauusurea spp. *, Serratula strangulata, Sonchus arborea, Stevia sanguinea, Taeckholmia arborea, Taeckholmia pinnata, Tanacetum fruticulosum, Tanacetum

parthenium, Tricholepis glaberrima** and other Tricholepsis spp. *, Vernonia arkansana, Vernonia nitidula, Vernonia noveboracensis, Vernonia profuga, Vernonia sublutea,

Volutarella divaricata, Zaiuzania resinosa; and can potentially be isolated from any part of the plants. Those genera and/or species marked with an asterisk (*) and especially those species marked with two asterisks (**) are especially preferred.

Appropriate plant material can be obtained from various sources, e.g. from:

Alfred Galke GmbH, Gittelde/Harz, Germany; Miiggenburg Pflanzliche Rohstoffe, Bad Bramstedt, Germany; Friedrich Nature Discovery, Euskirchen, Germany; VitaPlant AG, Uttwil, Switzerland; Amoros Nature SL, Hostalric, Spain.

(±)-Integrifolin

Banksia integrifolia

Coast Banksia

Family: Proteaceae

Banksia integrifolia is a tall shrub or small tree 6 – 16m tall. It is common in sandy coastal areas, but also grows in the forests of tablelands. The light grey bark is hard and rough.

Mature leaves 5 -10 cm long, are stiff, entire (untoothed), dull dark green above and hairy-white underneath. They are generally lanceolate. Younger leaves are irregularly toothed and shorter than the mature leaves. The species name ‘integrifolia’ means whole-leaved.

The pale yellow flower spikes of Banksia integrifolia range from 7-14cm long and 7cm wide. The bent styles emerge from individual flowers on the spike, straightening and spreading.

A short time after flowering, the seed pods protrude cleanly from the woody cone and open to shed black, papery, winged seeds.

Banksia integrifolia flowers from January to June.

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https://www.jstage.jst.go.jp/article/cpb1958/33/8/33_8_3361/_pdf

 

PAPER

http://onlinelibrary.wiley.com/doi/10.1002/chem.201601275/abstract

Total Synthesis of (±)-Integrifolin

  • DOI: 10.1002/chem.201601275

///////(±)-Integrifolin,  human cancer cells,  multipying

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