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Wikipedia

Pectin

January 01, 1970

Not to be confused with Pecten (biology), Pecten oculi, or Pecten (bivalve).

Pectin (Ancient Greek: πηκτικός pēktikós: "congealed" and "curdled") is a heteropolysaccharide, a structural acid contained in the primary lamella, in the middle lamella, and in the cell walls of terrestrial plants.[1] The principal chemical component of pectin is galacturonic acid (a sugar acid derived from galactose) which was isolated and described by Henri Braconnot in 1825.[2][3] Commercially produced pectin is a white-to-light-brown powder, produced from citrus fruits for use as an edible gelling agent, especially in jams and jellies, dessert fillings, medications, and sweets; and as a food stabiliser in fruit juices and milk drinks,[4] and as a source of dietary fiber.

Commercially produced powder of pectin, extracted from citrus fruits

Biology edit

Pectin is composed of complex polysaccharides that are present in the primary cell walls of a plant, and are abundant in the green parts of terrestrial plants.[5] Pectin is the principal component of the middle lamella, where it binds cells. Pectin is deposited by exocytosis into the cell wall via vesicles produced in the Golgi apparatus.[6] The amount, structure and chemical composition of pectin is different among plants, within a plant over time, and in various parts of a plant. Pectin is an important cell wall polysaccharide that allows primary cell wall extension and plant growth.[7] During fruit ripening, pectin is broken down by the enzymes pectinase and pectinesterase, in which process the fruit becomes softer as the middle lamellae break down and cells become separated from each other.[8] A similar process of cell separation caused by the breakdown of pectin occurs in the abscission zone of the petioles of deciduous plants at leaf fall.[citation needed]

Pectin is a natural part of the human diet, but does not contribute significantly to nutrition. The daily intake of pectin from fruits and vegetables can be estimated to be around 5 g if approximately 500 g of fruits and vegetables are consumed per day.

In human digestion, pectin binds to cholesterol in the gastrointestinal tract and slows glucose absorption by trapping carbohydrates. Pectin is thus a soluble dietary fiber. In non-obese diabetic (NOD) mice pectin has been shown to increase the incidence of autoimmune type 1 diabetes.[9]

A study found that after consumption of fruit the concentration of methanol in the human body increased by as much as an order of magnitude due to the degradation of natural pectin (which is esterified with methanol) in the colon.[10]

Pectin has been observed to have some function in repairing the DNA of some types of plant seeds, usually desert plants.[11] Pectinaceous surface pellicles, which are rich in pectin, create a mucilage layer that holds in dew that helps the cell repair its DNA.[12]

Consumption of pectin has been shown to slightly (3–7%) reduce blood LDL cholesterol levels. The effect depends upon the source of pectin; apple and citrus pectins were more effective than orange pulp fibre pectin.[13] The mechanism appears to be an increase of viscosity in the intestinal tract, leading to a reduced absorption of cholesterol from bile or food.[14] In the large intestine and colon, microorganisms degrade pectin and liberate short-chain fatty acids that have positive influence on health (prebiotic effect).[15]

Chemistry edit

 
Galacturonic acid

Pectins, also known as pectic polysaccharides, are rich in galacturonic acid. Several distinct polysaccharides have been identified and characterised within the pectic group. Homogalacturonans are linear chains of α-(1–4)-linked D-galacturonic acid.[16] Substituted galacturonans are characterised by the presence of saccharide appendant residues (such as D-xylose or D-apiose in the respective cases of xylogalacturonan and apiogalacturonan) branching from a backbone of D-galacturonic acid residues.[16][17] Rhamnogalacturonan I pectins (RG-I) contain a backbone of the repeating disaccharide: 4)-α-D-galacturonic acid-(1,2)-α-L-rhamnose-(1. From many of the rhamnose residues, sidechains of various neutral sugars branch off. The neutral sugars are mainly D-galactose, L-arabinose and D-xylose, with the types and proportions of neutral sugars varying with the origin of pectin.[16][17][18]

Another structural type of pectin is rhamnogalacturonan II (RG-II), which is a less frequent, complex, highly branched polysaccharide.[19] Rhamnogalacturonan II is classified by some authors within the group of substituted galacturonans since the rhamnogalacturonan II backbone is made exclusively of D-galacturonic acid units.[17]

Isolated pectin has a molecular weight of typically 60,000 to 130,000 g/mol, varying with origin and extraction conditions.[citation needed]

In nature, around 80 percent of carboxyl groups of galacturonic acid are esterified with methanol. This proportion is decreased to a varying degree during pectin extraction. Pectins are classified as high- versus low-methoxy pectins (short HM-pectins versus LM-pectins), with more or less than half of all the galacturonic acid esterified.[20] The ratio of esterified to non-esterified galacturonic acid determines the behaviour of pectin in food applications – HM-pectins can form a gel under acidic conditions in the presence of high sugar concentrations, while LM-pectins form gels by interaction with divalent cations, particularly Ca2+, according to the idealized 'egg box' model, in which ionic bridges are formed between calcium ions and the ionised carboxyl groups of the galacturonic acid.[21][22][20]

In high-methoxy pectins at soluble solids content above 60% and a pH value between 2.8 and 3.6, hydrogen bonds and hydrophobic interactions bind the individual pectin chains together. These bonds form as water is bound by sugar and forces pectin strands to stick together. These form a three-dimensional molecular net that creates the macromolecular gel. The gelling-mechanism is called a low-water-activity gel or sugar-acid-pectin gel.[citation needed]

While low-methoxy pectins need calcium to form a gel, they can do so at lower soluble solids and higher pH than high-methoxy pectins. Normally low-methoxy pectins form gels with a range of pH from 2.6 to 7.0 and with a soluble solids content between 10 and 70%.[citation needed]

The non-esterified galacturonic acid units can be either free acids (carboxyl groups) or salts with sodium, potassium, or calcium. The salts of partially esterified pectins are called pectinates, if the degree of esterification is below 5 percent the salts are called pectates, the insoluble acid form, pectic acid.[citation needed]

Some plants, such as sugar beet, potatoes and pears, contain pectins with acetylated galacturonic acid in addition to methyl esters. Acetylation prevents gel-formation but increases the stabilising and emulsifying effects of pectin.[citation needed]

Amidated pectin is a modified form of pectin. Here, some of the galacturonic acid is converted with ammonia to carboxylic acid amide. These pectins are more tolerant of varying calcium concentrations that occur in use.[23]

Thiolated pectin exhibits substantially improved gelling properties since this thiomer is able to crosslink via disulfide bond formation. These high gelling properties are advantageous for various pharmaceutical applications and applications in food industry.[24][25][26]

To prepare a pectin-gel, the ingredients are heated, dissolving the pectin. Upon cooling below gelling temperature, a gel starts to form. If gel formation is too strong, syneresis or a granular texture are the result, while weak gelling leads to excessively soft gels.[citation needed]

Amidated pectins behave like low-ester pectins but need less calcium and are more tolerant of excess calcium. Also, gels from amidated pectin are thermoreversible; they can be heated and after cooling solidify again, whereas conventional pectin-gels will afterwards remain liquid.[citation needed]

High-ester pectins set at higher temperatures than low-ester pectins. However, gelling reactions with calcium increase as the degree of esterification falls. Similarly, lower pH-values or higher soluble solids (normally sugars) increase gelling speeds. Suitable pectins can therefore be selected for jams and jellies, or for higher-sugar confectionery jellies.[citation needed]

Sources and production edit

Pears, apples, guavas, quince, plums, gooseberries, and oranges and other citrus fruits contain large amounts of pectin, while soft fruits, like cherries, grapes, and strawberries, contain small amounts of pectin.[citation needed]

Typical levels of pectin in fresh fruits and vegetables are:

The main raw materials for pectin production are dried citrus peels or apple pomace, both by-products of juice production. Pomace from sugar beets is also used to a small extent.[citation needed]

From these materials, pectin is extracted by adding hot dilute acid at pH values from 1.5 to 3.5. During several hours of extraction, the protopectin loses some of its branching and chain length and goes into solution. After filtering, the extract is concentrated in a vacuum and the pectin is then precipitated by adding ethanol or isopropanol. An old technique of precipitating pectin with aluminium salts is no longer used (apart from alcohols and polyvalent cations, pectin also precipitates with proteins and detergents).[citation needed]

Alcohol-precipitated pectin is then separated, washed, and dried. Treating the initial pectin with dilute acid leads to low-esterified pectins. When this process includes ammonium hydroxide (NH3(aq)), amidated pectins are obtained. After drying and milling, pectin is usually standardised[clarification needed] with sugar, and sometimes calcium salts or organic acids, to optimise performance in a particular application.[28]

Uses edit

The main use for pectin is as a gelling agent, thickening agent and stabiliser in food.[29]

In some countries, pectin is also available as a solution or an extract, or as a blended powder, for home jam making.[citation needed]

The classical application is giving the jelly-like consistency to jams or marmalades, which would otherwise be sweet juices.[30] Pectin also reduces syneresis in jams and marmalades and increases the gel strength of low-calorie jams. For household use, pectin is an ingredient in gelling sugar (also known as "jam sugar") where it is diluted to the right concentration with sugar and some citric acid to adjust pH.[citation needed]

For various food applications, different kinds of pectins can be distinguished by their properties, such as acidity, degree of esterification, relative number of methoxyl groups in the molecules, etc. For instance, the term "high methoxyl" refers to pectins that have a large proportion of the carboxyl groups in the pectin molecule that are esterified with methanol, compared to low methoxyl pectins:[30][31][32]

  • high methoxyl pectins are defined as those with a degree of esterification equal to or above 50, are typically used in traditional jam and jelly making;[33][34][29] such pectins require high sugar concentrations and acidic conditions to form gels, and provide a smooth texture and suitable to be used in bakery fillings and confectionery applications;[29][32][35]
  • low methoxyl pectins have a degree of esterification of less than 50,[32][29] can be either amidated or non-amidated: the percentage level of substitution of the amide group, defined as the degree of amidation, defines the efficacy of a pectin;[29] low methoxyl pectins can provide a range of textures and rheological properties, depending on the calcium concentration and the calcium reactivity of the pectin chosen[36]—amidated low methoxyl pectins are generally thermoreversible, meaning they can form gels that can melt and reform, whereas non-amidated low methoxyl pectins can form thermostable gels that withstand high temperatures;[36] these properties make low methoxyl pectins suitable for low sugar and sugar-free applications, dairy products, and stabilizing acidic protein drinks.[33][31][29]

For conventional jams and marmalades that contain above 60% sugar and soluble fruit solids, high-ester (high methoxyl) pectins are used. With low-ester (low methoxyl) pectins and amidated pectins, less sugar is needed, so that diet products can be made. Water extract of aiyu seeds is traditionally used in Taiwan to make aiyu jelly, where the extract gels without heating due to low-ester pectins from the seeds and the bivalent cations from the water.[20]

Pectin is used in confectionery jellies to give a good gel structure, a clean bite and to confer a good flavour release. Pectin can also be used to stabilise acidic protein drinks, such as drinking yogurt, to improve the mouth-feel and the pulp stability in juice based drinks and as a fat substitute in baked goods.[33][37]

Typical levels of pectin used as a food additive are between 0.5 and 1.0% – this is about the same amount of pectin as in fresh fruit.[38]

In medicine, pectin increases viscosity and volume of stool so that it is used against constipation and diarrhea. Until 2002, it was one of the main ingredients used in Kaopectate – a medication to combat diarrhea – along with kaolinite. It has been used in gentle heavy metal removal from biological systems.[39] Pectin is also used in throat lozenges as a demulcent.[citation needed]

In cosmetic products, pectin acts as a stabiliser. Pectin is also used in wound healing preparations and speciality medical adhesives, such as colostomy devices.[citation needed]

Sriamornsak[40] revealed that pectin could be used in various oral drug delivery platforms, e.g., controlled release systems, gastro-retentive systems, colon-specific delivery systems and mucoadhesive delivery systems, according to its intoxicity and low cost. It was found that pectin from different sources provides different gelling abilities, due to variations in molecular size and chemical composition. Like other natural polymers, a major problem with pectin is inconsistency in reproducibility between samples, which may result in poor reproducibility in drug delivery characteristics.[citation needed]

In ruminant nutrition, depending on the extent of lignification of the cell wall, pectin is up to 90% digestible by bacterial enzymes. Ruminant nutritionists recommend that the digestibility and energy concentration in forages be improved by increasing pectin concentration in the forage.

In cigars, pectin is considered an excellent substitute for vegetable glue and many cigar smokers and collectors use pectin for repairing damaged tobacco leaves on their cigars.

Yablokov et al., writing in Chernobyl: Consequences of the Catastrophe for People and the Environment, quote research conducted by the Ukrainian Center of Radiation Medicine and the Belarusian Institute of Radiation Medicine and Endocrinology, concluded, regarding pectin's radioprotective effects, that "adding pectin preparations to the food of inhabitants of the Chernobyl-contaminated regions promotes an effective excretion of incorporated radionuclides" such as cesium-137. The authors reported on the positive results of using pectin food additive preparations in a number of clinical studies conducted on children in severely polluted areas, with up to 50% improvement over control groups.[41] During the Second World War, Allied pilots were provided with maps printed on silk, for navigation in escape and evasion efforts. The printing process at first proved nearly impossible because the several layers of ink immediately ran, blurring outlines and rendering place names illegible until the inventor of the maps, Clayton Hutton, mixed a little pectin with the ink and at once the pectin coagulated the ink and prevented it from running, allowing small topographic features to be clearly visible.[42]

Legal status edit

At the Joint FAO/WHO Expert Committee Report on Food Additives and in the European Union, no numerical acceptable daily intake (ADI) has been set, as pectin is considered safe.[43]

The European Union (EU) has not set a daily intake limit for two types of pectin, known as E440(i) and Amidated Pectin E440(ii). The EU has established purity standards for these additives in the EU Commission Regulation (EU)/231/2012. Pectin can be used as needed in most food categories, a concept referred to as "quantum satis".[44] The European Food Safety Authority (EFSA) conducted a re-evaluation of Pectin E440(i) and Amidated Pectin E440(ii) in 2017. The EFSA concluded that the use of these food additives poses no safety concern for the general population. Furthermore, the agency stated that it is not necessary to establish a numerical value for the Acceptable Daily Intake (ADI).[45][46]

In the United States, pectin is generally recognised as safe for human consumption.[citation needed]

In the International Numbering System (INS), pectin has the number 440. In Europe, pectins are differentiated into the E numbers E440(i) for non-amidated pectins and E440(ii) for amidated pectins. There are specifications in all national and international legislation defining its quality and regulating its use.[citation needed]

History edit

Pectin was first isolated and described in 1825 by Henri Braconnot, though the action of pectin to make jams and marmalades was known long before. To obtain well-set jams from fruits that had little or only poor quality pectin, pectin-rich fruits or their extracts were mixed into the recipe.

During the Industrial Revolution, the makers of fruit preserves turned to producers of apple juice to obtain dried apple pomace that was cooked to extract pectin. Later, in the 1920s and 1930s, factories were built that commercially extracted pectin from dried apple pomace, and later citrus peel, in regions that produced apple juice in both the US and Europe.

Pectin was first sold as a liquid extract, but is now most often used as dried powder, which is easier than a liquid to store and handle.[47]

See also edit

References edit

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External links edit

  • Codex General Standard for Food Additives (GSFA) Online Database; A list of permitted uses of pectin, further link to the JECFA (...) specification of pectin.
  • Note: The link points to a "consleg"-version of the directive, that may not include the very latest changes. The Directive will be replaced by a new Regulation for food additives in the next few years.
  • Certo Health: Information on reported health benefits of apple pectin, (UK).

January 01, 1970
pectin, confused, with, pecten, biology, pecten, oculi, pecten, bivalve, ancient, greek, πηκτικός, pēktikós, congealed, curdled, heteropolysaccharide, structural, acid, contained, primary, lamella, middle, lamella, cell, walls, terrestrial, plants, principal, . Not to be confused with Pecten biology Pecten oculi or Pecten bivalve Pectin Ancient Greek phktikos pektikos congealed and curdled is a heteropolysaccharide a structural acid contained in the primary lamella in the middle lamella and in the cell walls of terrestrial plants 1 The principal chemical component of pectin is galacturonic acid a sugar acid derived from galactose which was isolated and described by Henri Braconnot in 1825 2 3 Commercially produced pectin is a white to light brown powder produced from citrus fruits for use as an edible gelling agent especially in jams and jellies dessert fillings medications and sweets and as a food stabiliser in fruit juices and milk drinks 4 and as a source of dietary fiber Commercially produced powder of pectin extracted from citrus fruits Contents 1 Biology 2 Chemistry 3 Sources and production 4 Uses 5 Legal status 6 History 7 See also 8 References 9 External linksBiology editPectin is composed of complex polysaccharides that are present in the primary cell walls of a plant and are abundant in the green parts of terrestrial plants 5 Pectin is the principal component of the middle lamella where it binds cells Pectin is deposited by exocytosis into the cell wall via vesicles produced in the Golgi apparatus 6 The amount structure and chemical composition of pectin is different among plants within a plant over time and in various parts of a plant Pectin is an important cell wall polysaccharide that allows primary cell wall extension and plant growth 7 During fruit ripening pectin is broken down by the enzymes pectinase and pectinesterase in which process the fruit becomes softer as the middle lamellae break down and cells become separated from each other 8 A similar process of cell separation caused by the breakdown of pectin occurs in the abscission zone of the petioles of deciduous plants at leaf fall citation needed Pectin is a natural part of the human diet but does not contribute significantly to nutrition The daily intake of pectin from fruits and vegetables can be estimated to be around 5 g if approximately 500 g of fruits and vegetables are consumed per day In human digestion pectin binds to cholesterol in the gastrointestinal tract and slows glucose absorption by trapping carbohydrates Pectin is thus a soluble dietary fiber In non obese diabetic NOD mice pectin has been shown to increase the incidence of autoimmune type 1 diabetes 9 A study found that after consumption of fruit the concentration of methanol in the human body increased by as much as an order of magnitude due to the degradation of natural pectin which is esterified with methanol in the colon 10 Pectin has been observed to have some function in repairing the DNA of some types of plant seeds usually desert plants 11 Pectinaceous surface pellicles which are rich in pectin create a mucilage layer that holds in dew that helps the cell repair its DNA 12 Consumption of pectin has been shown to slightly 3 7 reduce blood LDL cholesterol levels The effect depends upon the source of pectin apple and citrus pectins were more effective than orange pulp fibre pectin 13 The mechanism appears to be an increase of viscosity in the intestinal tract leading to a reduced absorption of cholesterol from bile or food 14 In the large intestine and colon microorganisms degrade pectin and liberate short chain fatty acids that have positive influence on health prebiotic effect 15 Chemistry edit nbsp Galacturonic acid Pectins also known as pectic polysaccharides are rich in galacturonic acid Several distinct polysaccharides have been identified and characterised within the pectic group Homogalacturonans are linear chains of a 1 4 linked D galacturonic acid 16 Substituted galacturonans are characterised by the presence of saccharide appendant residues such as D xylose or D apiose in the respective cases of xylogalacturonan and apiogalacturonan branching from a backbone of D galacturonic acid residues 16 17 Rhamnogalacturonan I pectins RG I contain a backbone of the repeating disaccharide 4 a D galacturonic acid 1 2 a L rhamnose 1 From many of the rhamnose residues sidechains of various neutral sugars branch off The neutral sugars are mainly D galactose L arabinose and D xylose with the types and proportions of neutral sugars varying with the origin of pectin 16 17 18 Another structural type of pectin is rhamnogalacturonan II RG II which is a less frequent complex highly branched polysaccharide 19 Rhamnogalacturonan II is classified by some authors within the group of substituted galacturonans since the rhamnogalacturonan II backbone is made exclusively of D galacturonic acid units 17 Isolated pectin has a molecular weight of typically 60 000 to 130 000 g mol varying with origin and extraction conditions citation needed In nature around 80 percent of carboxyl groups of galacturonic acid are esterified with methanol This proportion is decreased to a varying degree during pectin extraction Pectins are classified as high versus low methoxy pectins short HM pectins versus LM pectins with more or less than half of all the galacturonic acid esterified 20 The ratio of esterified to non esterified galacturonic acid determines the behaviour of pectin in food applications HM pectins can form a gel under acidic conditions in the presence of high sugar concentrations while LM pectins form gels by interaction with divalent cations particularly Ca2 according to the idealized egg box model in which ionic bridges are formed between calcium ions and the ionised carboxyl groups of the galacturonic acid 21 22 20 In high methoxy pectins at soluble solids content above 60 and a pH value between 2 8 and 3 6 hydrogen bonds and hydrophobic interactions bind the individual pectin chains together These bonds form as water is bound by sugar and forces pectin strands to stick together These form a three dimensional molecular net that creates the macromolecular gel The gelling mechanism is called a low water activity gel or sugar acid pectin gel citation needed While low methoxy pectins need calcium to form a gel they can do so at lower soluble solids and higher pH than high methoxy pectins Normally low methoxy pectins form gels with a range of pH from 2 6 to 7 0 and with a soluble solids content between 10 and 70 citation needed The non esterified galacturonic acid units can be either free acids carboxyl groups or salts with sodium potassium or calcium The salts of partially esterified pectins are called pectinates if the degree of esterification is below 5 percent the salts are called pectates the insoluble acid form pectic acid citation needed Some plants such as sugar beet potatoes and pears contain pectins with acetylated galacturonic acid in addition to methyl esters Acetylation prevents gel formation but increases the stabilising and emulsifying effects of pectin citation needed Amidated pectin is a modified form of pectin Here some of the galacturonic acid is converted with ammonia to carboxylic acid amide These pectins are more tolerant of varying calcium concentrations that occur in use 23 Thiolated pectin exhibits substantially improved gelling properties since this thiomer is able to crosslink via disulfide bond formation These high gelling properties are advantageous for various pharmaceutical applications and applications in food industry 24 25 26 To prepare a pectin gel the ingredients are heated dissolving the pectin Upon cooling below gelling temperature a gel starts to form If gel formation is too strong syneresis or a granular texture are the result while weak gelling leads to excessively soft gels citation needed Amidated pectins behave like low ester pectins but need less calcium and are more tolerant of excess calcium Also gels from amidated pectin are thermoreversible they can be heated and after cooling solidify again whereas conventional pectin gels will afterwards remain liquid citation needed High ester pectins set at higher temperatures than low ester pectins However gelling reactions with calcium increase as the degree of esterification falls Similarly lower pH values or higher soluble solids normally sugars increase gelling speeds Suitable pectins can therefore be selected for jams and jellies or for higher sugar confectionery jellies citation needed Sources and production editPears apples guavas quince plums gooseberries and oranges and other citrus fruits contain large amounts of pectin while soft fruits like cherries grapes and strawberries contain small amounts of pectin citation needed Typical levels of pectin in fresh fruits and vegetables are Apples 1 1 5 Apricots 1 Cherries 0 4 Oranges 0 5 3 5 Carrots 1 4 Citrus peels 30 Rose hips 15 27 The main raw materials for pectin production are dried citrus peels or apple pomace both by products of juice production Pomace from sugar beets is also used to a small extent citation needed From these materials pectin is extracted by adding hot dilute acid at pH values from 1 5 to 3 5 During several hours of extraction the protopectin loses some of its branching and chain length and goes into solution After filtering the extract is concentrated in a vacuum and the pectin is then precipitated by adding ethanol or isopropanol An old technique of precipitating pectin with aluminium salts is no longer used apart from alcohols and polyvalent cations pectin also precipitates with proteins and detergents citation needed Alcohol precipitated pectin is then separated washed and dried Treating the initial pectin with dilute acid leads to low esterified pectins When this process includes ammonium hydroxide NH3 aq amidated pectins are obtained After drying and milling pectin is usually standardised clarification needed with sugar and sometimes calcium salts or organic acids to optimise performance in a particular application 28 Uses editThe main use for pectin is as a gelling agent thickening agent and stabiliser in food 29 In some countries pectin is also available as a solution or an extract or as a blended powder for home jam making citation needed The classical application is giving the jelly like consistency to jams or marmalades which would otherwise be sweet juices 30 Pectin also reduces syneresis in jams and marmalades and increases the gel strength of low calorie jams For household use pectin is an ingredient in gelling sugar also known as jam sugar where it is diluted to the right concentration with sugar and some citric acid to adjust pH citation needed For various food applications different kinds of pectins can be distinguished by their properties such as acidity degree of esterification relative number of methoxyl groups in the molecules etc For instance the term high methoxyl refers to pectins that have a large proportion of the carboxyl groups in the pectin molecule that are esterified with methanol compared to low methoxyl pectins 30 31 32 high methoxyl pectins are defined as those with a degree of esterification equal to or above 50 are typically used in traditional jam and jelly making 33 34 29 such pectins require high sugar concentrations and acidic conditions to form gels and provide a smooth texture and suitable to be used in bakery fillings and confectionery applications 29 32 35 low methoxyl pectins have a degree of esterification of less than 50 32 29 can be either amidated or non amidated the percentage level of substitution of the amide group defined as the degree of amidation defines the efficacy of a pectin 29 low methoxyl pectins can provide a range of textures and rheological properties depending on the calcium concentration and the calcium reactivity of the pectin chosen 36 amidated low methoxyl pectins are generally thermoreversible meaning they can form gels that can melt and reform whereas non amidated low methoxyl pectins can form thermostable gels that withstand high temperatures 36 these properties make low methoxyl pectins suitable for low sugar and sugar free applications dairy products and stabilizing acidic protein drinks 33 31 29 For conventional jams and marmalades that contain above 60 sugar and soluble fruit solids high ester high methoxyl pectins are used With low ester low methoxyl pectins and amidated pectins less sugar is needed so that diet products can be made Water extract of aiyu seeds is traditionally used in Taiwan to make aiyu jelly where the extract gels without heating due to low ester pectins from the seeds and the bivalent cations from the water 20 Pectin is used in confectionery jellies to give a good gel structure a clean bite and to confer a good flavour release Pectin can also be used to stabilise acidic protein drinks such as drinking yogurt to improve the mouth feel and the pulp stability in juice based drinks and as a fat substitute in baked goods 33 37 Typical levels of pectin used as a food additive are between 0 5 and 1 0 this is about the same amount of pectin as in fresh fruit 38 In medicine pectin increases viscosity and volume of stool so that it is used against constipation and diarrhea Until 2002 it was one of the main ingredients used in Kaopectate a medication to combat diarrhea along with kaolinite It has been used in gentle heavy metal removal from biological systems 39 Pectin is also used in throat lozenges as a demulcent citation needed In cosmetic products pectin acts as a stabiliser Pectin is also used in wound healing preparations and speciality medical adhesives such as colostomy devices citation needed Sriamornsak 40 revealed that pectin could be used in various oral drug delivery platforms e g controlled release systems gastro retentive systems colon specific delivery systems and mucoadhesive delivery systems according to its intoxicity and low cost It was found that pectin from different sources provides different gelling abilities due to variations in molecular size and chemical composition Like other natural polymers a major problem with pectin is inconsistency in reproducibility between samples which may result in poor reproducibility in drug delivery characteristics citation needed In ruminant nutrition depending on the extent of lignification of the cell wall pectin is up to 90 digestible by bacterial enzymes Ruminant nutritionists recommend that the digestibility and energy concentration in forages be improved by increasing pectin concentration in the forage In cigars pectin is considered an excellent substitute for vegetable glue and many cigar smokers and collectors use pectin for repairing damaged tobacco leaves on their cigars Yablokov et al writing in Chernobyl Consequences of the Catastrophe for People and the Environment quote research conducted by the Ukrainian Center of Radiation Medicine and the Belarusian Institute of Radiation Medicine and Endocrinology concluded regarding pectin s radioprotective effects that adding pectin preparations to the food of inhabitants of the Chernobyl contaminated regions promotes an effective excretion of incorporated radionuclides such as cesium 137 The authors reported on the positive results of using pectin food additive preparations in a number of clinical studies conducted on children in severely polluted areas with up to 50 improvement over control groups 41 During the Second World War Allied pilots were provided with maps printed on silk for navigation in escape and evasion efforts The printing process at first proved nearly impossible because the several layers of ink immediately ran blurring outlines and rendering place names illegible until the inventor of the maps Clayton Hutton mixed a little pectin with the ink and at once the pectin coagulated the ink and prevented it from running allowing small topographic features to be clearly visible 42 Legal status editAt the Joint FAO WHO Expert Committee Report on Food Additives and in the European Union no numerical acceptable daily intake ADI has been set as pectin is considered safe 43 The European Union EU has not set a daily intake limit for two types of pectin known as E440 i and Amidated Pectin E440 ii The EU has established purity standards for these additives in the EU Commission Regulation EU 231 2012 Pectin can be used as needed in most food categories a concept referred to as quantum satis 44 The European Food Safety Authority EFSA conducted a re evaluation of Pectin E440 i and Amidated Pectin E440 ii in 2017 The EFSA concluded that the use of these food additives poses no safety concern for the general population Furthermore the agency stated that it is not necessary to establish a numerical value for the Acceptable Daily Intake ADI 45 46 In the United States pectin is generally recognised as safe for human consumption citation needed In the International Numbering System INS pectin has the number 440 In Europe pectins are differentiated into the E numbers E440 i for non amidated pectins and E440 ii for amidated pectins There are specifications in all national and international legislation defining its quality and regulating its use citation needed History editPectin was first isolated and described in 1825 by Henri Braconnot though the action of pectin to make jams and marmalades was known long before To obtain well set jams from fruits that had little or only poor quality pectin pectin rich fruits or their extracts were mixed into the recipe During the Industrial Revolution the makers of fruit preserves turned to producers of apple juice to obtain dried apple pomace that was cooked to extract pectin Later in the 1920s and 1930s factories were built that commercially extracted pectin from dried apple pomace and later citrus peel in regions that produced apple juice in both the US and Europe Pectin was first sold as a liquid extract but is now most often used as dried powder which is easier than a liquid to store and handle 47 See also edit nbsp Food portal Fruit snacksReferences edit phktikos Liddell Henry George Scott Robert A Greek English Lexicon at the Perseus Project Braconnot H 1825 Recherches sur un nouvel acide universellement repandu dans tous les vegetaux Investigations into a new acid spread throughout all plants Annales de chimie et de physique 28 2 173 178 From page 178 je propose le nompectique de phxtes coagulum I propose the name pectique from phxtes pectes coagulum coagulated material clot curd Keppler F Hamilton JT Brass M Rockmann T January 2006 Methane emissions from terrestrial plants under aerobic conditions Nature 439 7073 187 191 Bibcode 2006Natur 439 187K doi 10 1038 nature04420 PMID 16407949 S2CID 2870347 Gerlat P 15 November 2000 Beverage Stabilizers Food Product Design Magazine Archived from the original on 12 August 2022 Retrieved 24 January 2023 via Food Ingredients Online for the food ingredients industry Bidhendi AJ Chebli Y Geitmann A June 2020 Fluorescence visualization of cellulose and pectin in the primary plant cell wall Journal of Microscopy 278 3 164 181 doi 10 1111 jmi 12895 PMID 32270489 S2CID 215619998 Braidwood L Breuer C Sugimoto K January 2014 My body is a cage mechanisms and modulation of plant cell growth The New Phytologist 201 2 388 402 doi 10 1111 nph 12473 PMID 24033322 Bidhendi AJ Geitmann A January 2016 Relating the mechanics of the primary plant cell wall to morphogenesis PDF Journal of Experimental Botany 67 2 449 461 doi 10 1093 jxb erv535 PMID 26689854 Archived PDF from the original on 13 January 2018 Retrieved 30 May 2020 Grierson D Maunders MJ Slater A Ray J Bird CR Schuch W et al 1986 Gene expression during tomato ripening Philosophical Transactions of the Royal Society of London B 314 1166 399 410 Bibcode 1986RSPTB 314 399G doi 10 1098 rstb 1986 0061 Toivonen RK Emani R Munukka E Rintala A Laiho A Pietila S et al October 2014 Fermentable fibres condition colon microbiota and promote diabetogenesis in NOD mice Diabetologia 57 10 2183 2192 doi 10 1007 s00125 014 3325 6 PMID 25031069 Lindinger W Taucher J Jordan A Hansel A Vogel W August 1997 Endogenous production of methanol after the consumption of fruit Alcoholism Clinical and Experimental Research 21 5 939 943 doi 10 1111 j 1530 0277 1997 tb03862 x PMID 9267548 Huang Z Gutterman Y Osborne DJ 30 July 2004 Value of the mucilaginous pellicle to seeds of the sand stabilizing desert woody shrub Artemisia sphaerocephala Asteraceae Trees 18 6 669 676 Bibcode 2004Trees 18 669H doi 10 1007 s00468 004 0349 4 S2CID 37031814 Huang Z Boubriak I Osborne DJ Dong M Gutterman Y January 2008 Possible role of pectin containing mucilage and dew in repairing embryo DNA of seeds adapted to desert conditions Annals of Botany 101 2 277 283 doi 10 1093 aob mcm089 PMC 2711012 PMID 17495979 Brouns F Theuwissen E Adam A Bell M Berger A Mensink RP May 2012 Cholesterol lowering properties of different pectin types in mildly hyper cholesterolemic men and women European Journal of Clinical Nutrition 66 5 591 599 doi 10 1038 ejcn 2011 208 PMID 22190137 Sriamornsak P 2003 Chemistry of Pectin and its Pharmaceutical Uses A Review Silpakorn University International Journal 3 1 2 206 Archived from the original on 3 June 2012 Retrieved 23 August 2007 Gomez B Gullon B Remoroza C Schols HA Parajo JC Alonso JL October 2014 Purification characterization and prebiotic properties of pectic oligosaccharides from orange peel wastes Journal of Agricultural and Food Chemistry 62 40 9769 9782 doi 10 1021 jf503475b PMID 25207862 a b c Galacturonans Complex Carbohydrate Research Centre University of Georgia US Archived from the original on 15 August 2010 Retrieved 23 July 2010 a b c Buchanan BB Gruissem W Jones RL 2000 Biochemistry and Molecular Biology of Plants Rockville MD USA American Society of Plant Biologists ISBN 978 0 943088 37 2 Archived from the original on 26 March 2020 Retrieved 23 July 2010 RG I Ccrc uga edu Archived from the original on 4 October 2009 Retrieved 16 July 2012 Rhamnogalacturonan II www ccrc uga edu Archived from the original on 3 October 2009 Retrieved 16 July 2012 a b c Liang RH Chen J Liu W Liu CM Yu W Yuan M et al January 2012 Extraction characterization and spontaneous gel forming property of pectin from creeping fig Ficus pumila Linn seeds Carbohydrate Polymers 87 1 76 83 doi 10 1016 j carbpol 2011 07 013 PMID 34663033 Durand D Bertrand C Clark AH Lips A February 1990 Calcium induced gelation of low methoxy pectin solutions thermodynamic and rheological considerations International Journal of Biological Macromolecules 12 1 14 18 doi 10 1016 0141 8130 90 90076 M PMID 2083236 Migliori M Gabriele D Checchetti A Battipede B 2010 Compatibility analysis of pectin at different esterification degree from intrinsic viscosity data of diluted ternary solutions Reactive and Functional Polymers 70 10 863 867 doi 10 1016 j reactfunctpolym 2010 07 011 Belitz HD Grosch W Schieberle P April 2004 Food Chemistry Berlin Springer Majzoob S Atyabi F Dorkoosh F Kafedjiiski K Loretz B Bernkop Schnurch A December 2006 Pectin cysteine conjugate synthesis and in vitro evaluation of its potential for drug delivery The Journal of Pharmacy and Pharmacology 58 12 1601 1610 doi 10 1211 jpp 58 12 0006 PMID 17331323 S2CID 24127477 Perera G Hombach J Bernkop Schnurch A March 2010 Hydrophobic thiolation of pectin with 4 aminothiophenol synthesis and in vitro characterization AAPS PharmSciTech 11 1 174 180 doi 10 1208 s12249 009 9370 7 PMC 2850493 PMID 20101485 S2CID 25025639 Chen J Cui Y Zhang S Ma Y Yang F March 2023 Compound treatment of thiolated citrus high methoxyl pectin and sodium phosphate dibasic anhydrous improved gluten network structure Food Chemistry 404 Pt B 134770 doi 10 1016 j foodchem 2022 134770 PMID 36332584 S2CID 253214393 Wichtl M January 2004 Monograph Rosae Pseudofrutus Rose Hips Herbal Drugs and Phytopharmaceuticals a handbook for practice on a scientific basis 3rd expanded and completely rev ed Stuttgart Boca Raton FL Medpharm CRC Press p 520 ISBN 978 0 8493 1961 7 G Eisenbrand P Schreier ROMPP Lexikon Lebensmittelchemie Thieme Stuttgart Mai 2006 a b c d e f Han J 13 June 2020 What is Pectin E440 Sources Types Uses and Benefits Archived from the original on 27 September 2023 Retrieved 7 April 2024 a b Surolia R Singh A 2024 Pectin Structure Specification Production Applications and various Emerging Sources A Review Sustainable Food Systems Volume II World Sustainability Series pp 267 282 doi 10 1007 978 3 031 46046 3 13 ISBN 978 3 031 46045 6 a b Kontogiorgos V ed 2020 Pectin Technological and Physiological Properties doi 10 1007 978 3 030 53421 9 ISBN 978 3 030 53420 2 a b c Endress H 17 August 2011 Pectins Production Properties and Applications Renewable Resources for Functional Polymers and Biomaterials pp 210 260 doi 10 1039 9781849733519 00210 ISBN 978 1 84973 245 1 a b c UniPECTINE PDF Archived PDF from the original on 7 April 2024 Retrieved 7 April 2024 Yang Y Anderson CT 2 October 2020 Biosynthesis Localisation and Function of Pectins in Plants Pectin Technological and Physiological Properties pp 1 15 doi 10 1007 978 3 030 53421 9 1 ISBN 978 3 030 53421 9 Sultana N December 2023 Biological Properties and Biomedical Applications of Pectin and Pectin Based Composites A Review Molecules 28 24 7974 doi 10 3390 molecules28247974 PMC 10745545 PMID 38138464 a b Said NS Olawuyi IF Lee WY September 2023 Pectin Hydrogels Gel Forming Behaviors Mechanisms and Food Applications Gels 9 9 732 doi 10 3390 gels9090732 PMC 10530747 PMID 37754413 May CD 1990 Industrial pectins Sources production and applications Carbohydrate Polymers 12 1 79 99 doi 10 1016 0144 8617 90 90105 2 Thakur BR Singh RK Handa AK February 1997 Chemistry and uses of pectin a review Critical Reviews in Food Science and Nutrition 37 1 47 73 doi 10 1080 10408399709527767 PMID 9067088 Zhao ZY Liang L Fan X Yu Z Hotchkiss AT Wilk BJ et al 2008 The role of modified citrus pectin as an effective chelator of lead in children hospitalized with toxic lead levels Alternative Therapies in Health and Medicine 14 4 34 38 PMID 18616067 Sriamornsak P August 2011 Application of pectin in oral drug delivery Expert Opinion on Drug Delivery 8 8 1009 1023 doi 10 1517 17425247 2011 584867 PMID 21564000 S2CID 25595142 Nesterenko VB Nesterenko AV November 2009 13 Decorporation of Chernobyl radionuclides Annals of the New York Academy of Sciences 1181 1 303 310 Bibcode 2009NYASA1181 303N doi 10 1111 j 1749 6632 2009 04838 x ISBN 978 1 57331 757 3 PMID 20002057 history of wwii british cloth escape maps www escape maps com Archived from the original on 25 June 2019 Retrieved 29 June 2019 Joint FAO WHO Expert Committee on Food Additives Chemical Risks in Food Who int Report Archived from the original on 8 July 2004 Retrieved 16 July 2012 Commission Regulation EU No 1130 2011 of 11 November 2011 amending Annex III to Regulation EC No 1333 2008 of the European Parliament and of the Council on food additives by establishing a Union list of food additives approved for use in food additives food enzymes food flavourings and nutrients Text with EEA relevance Archived from the original on 11 December 2023 Retrieved 7 April 2024 Mortensen A Aguilar F Crebelli R Di Domenico A Dusemund B Frutos MJ et al 6 July 2017 Re evaluation of pectin E 440i and amidated pectin E 440ii as food additives EFSA Journal 15 7 e04866 doi 10 2903 j efsa 2017 4866 PMC 7010145 PMID 32625540 Archived from the original on 21 January 2022 Retrieved 7 April 2024 EFSA Panel on Food Additives and Flavourings FAF 29 January 2021 Opinion on the re evaluation of pectin E 440i and amidated pectin E 440ii as food additives in foods for infants below 16 weeks of age and follow up of their re evaluation as food additives for uses in foods for all population groups EFSA EFSA Journal European Food Safety Authority 19 1 e06387 doi 10 2903 j efsa 2021 6387 hdl 11368 2979399 PMC 7845505 PMID 33537069 Archived from the original on 21 January 2022 Retrieved 7 April 2024 International Pectin Producers Association Archived from the original on 11 February 2022 Retrieved 13 June 2007 External links editCodex General Standard for Food Additives GSFA Online Database A list of permitted uses of pectin further link to the JECFA specification of pectin European parliament and council directive No 95 2 EC of 20 February 1995 on food additives other than colours and sweeteners EU Directive that lists the foods pectin may be used in Note The link points to a consleg version of the directive that may not include the very latest changes The Directive will be replaced by a new Regulation for food additives in the next few years Certo Health Information on reported health benefits of apple pectin UK Retrieved from https en wikipedia org w index php title Pectin amp oldid 1220317497, wikipedia, wiki, book, books, library,

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