Technological Application of Tannin-Based Extracts
Abstract
:1. Introduction
2. Major Sources of Tannins for Technological Applications
3. Efficient Extraction Procedures for Technological Application of Tannins: Rapid and Economic
3.1. Solid/Liquid Extraction
3.2. Supercritical Extraction
3.3. Pressurized Water Extraction
3.4. Microwave-Assisted Extraction
3.5. Ultrasound-Assisted Extraction
3.6. Comparison of Extraction Systems
4. Technological Applications
4.1. Coagulants: Environmental Application
4.2. Adhesives: Wood, Tires, Concrete
4.3. Ore Flotation Agents
4.4. Fabric Manufacture
4.4.1. Leather Industry
4.4.2. Dyeing Industry of Natural Fibres: Cotton, Wool, Silk
4.5. Food Additives
4.6. Medical, Pharmaceutical, and Veterinary Applications
4.6.1. Antioxidant
4.6.2. Antimicrobial
4.6.3. Anthelmintic
4.6.4. Antiviral
4.6.5. Anti-Inflammatory
5. Conclusions
Author Contributions
Funding
Conflicts of Interest
References
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Sample Availability: No samples have been used for the performance of this review. |
Species | Tissue | Type | Method | Concentration (mg/g dw) | Reference |
---|---|---|---|---|---|
Carya illinoinensis | Nut | H and C | HPLC | 0.22 ± 0.11 H; 4.66 ± 2.28 C | [2,16] |
Kernel (K) and nutshell (N) | C | Vanillin-HCl | 0.4–5.3 C (K); 0.5–876 C (N) | [17] | |
Juglans regia | Nut | H and C | HPLC | 0.05 ± 0.01 H; 0.06 ± 0.03 C | [2,16] |
Ribes nigrum | Juice and extracts | H and C | ST | 0.04 ± 0.01 H; 1.14 ± 0.50 C | [2,26] |
Fragaria sp. | Fruit | H and C | HPLC | 0.77 ± 0.006 H; 0.99 ± 0.08 C | [2,16] |
Rubus fruticosus | Fruit | H and C | HPLC | 2.10 ± 0.60 H; 0.25 ± 0.20 C | [2,16] |
Rubus occidentalis | Fruit | H and C | HPLC | 2.43 ± 0.83 H; 0.38 ± 0.35 C | [2,16] |
Punica granatum | Fruit, seeds, juice (J) | H | HPLC | 0.12 ± 0.06 H; 7–1169 mg/L (J) | [2,27] |
Psidium spp. | Fruit | H | HPLC, ST | 2.35–55.5 H | [2,28,29] |
Mangifera indica | Fruit | H and C | ST | 0.55–0.95 H | [2,30] |
Prunus dulcis | Fruit | H | HPLC | 0.27 ± 0.07 H; 1.62 ± 0.95 C | [2,31] |
Desmodium ovalifolium | Leaves and twigs | C | RDABA | 57–273 C | [19,20] |
Gliricidia sepium | Leaves | C | RDABA | 25–186 C | [19,20] |
Manihot esculenta | Leaves and stems | C | RDABA | 26–169 C | [19,20] |
Arachis pintoi | Leaves and twigs | C | RDABA | 40–186 C | [19,20] |
Castanea sativa | Fruits and bark | H and C | HPLC | 0.7–89 H; 0.0001–167 H and C | [2,21,22] |
Terminalia sp. | Fruits | H and C | HPLC | 126–822 H and C | [23] |
Quercus | Wood | H | HPLC, GC | 19.26–47.26 H Q. robur; 11.55–30.88 H Q. petraea; 8.18 ± 0.18 H Q. alba. | [24,25] |
Betula spp. | Leaves | H and C | HPLC | 0.72–60.67 HT; 47–103C | [32,33] |
Pinus sylvestris | Needles | C | HPLC | 70–80 C | [34] |
Eucalyptus globulus | Leaves | H and C | HPLC | 93.57 H + Phloroglucinol | [35] |
Acacia sp. | Leaves | H and C | ST | 185 H and C A. angustissima; 84 H and C A. drepanolobium, 256 H and C A. nilotica; 98 H and C A. polyacantha; 217 H and C A. tortilisand; 226 H and C A. Senegal | [36] |
A. mearnsii | Bark | C | Butanol-HCl | 235 C | [37] |
HPLC | 108 C | ||||
Caesalpinia spinosa | Pod | H and C | Butanol-HCl | 4.6 C | [37] |
HPLC | 647 H | ||||
Schinopsis lorentzii | Heartwood | C | Butanol-HCl | 123 C | [37] |
HPLC | 164 C |
Method | Conditions | Source | Recovery (mg/g) | Relative Cost (L, M, H) | Reference |
---|---|---|---|---|---|
SLE | 1% NaOH (aq) | Castanea dentata peels | 4.071 | L | [40] |
1% Na2SO3 (aq) | 0.609 | L | |||
1.5% EtOH (aq) | Pinus pinaster barks | 62.8 CME | L | [41] | |
66% EtOH (aq) | Grape by-products | 12.3 g/L | L | [42] | |
40% EtOH (aq) | Acorn | 80% | L | [52] | |
Ionic liquid A | Acacia catechu | 85% | M/H | [44] | |
Ionic liquid B 0.5 M | Grape skin | 60.1 | M/H | [53] | |
SFE | CO2 + EtOH 70%; 40 °C; 10 MPa | Picea abies bark | 26.38 | H | [45] |
CO2 + MeOH 40%; 80 °C; 65 MPa | Grape seeds | 770 | H | [46] | |
CO2 + EtOH; 50 °C; 18.80 MPa | Camellia sinensis leaves | 499.90 | H | [54] | |
CO2 + EtOH 10%; 50 °C; 10 MPa | Pinus pinaster wood | 75.61 | H | [55] | |
CO2, 50 °C, 30 MPa | Punica granatum leaves | 340 | H | [56] | |
PWE | H2O; 50 °C; 150 MPa | Pistacia vera by-products | 70.90 | H | [49] |
H2O; RT; 250 MPa | Viola × wittrockiana | 93.86 | H | [57] | |
H2O; 100 °C; 2 MPa | Larch wood | 381.90 | H | [51] | |
H2O; 100 °C; 10,34 MPa | Grape pomace | 52.90 | H | [50] | |
H2O; 140 °C; 4 MPa | Lavatera thuringiaca | 72.23 GAE | H | [58] | |
ME | EtOH 70%; 125 W | Grape seeds | 528 | H | [59] |
MeOH 60% | Grape by-products | 22.27 mg/L | H | [60] | |
EtOH 45%; 340 W | Ceratonia siliqua kibbles | 4.11 | H | [61] | |
H2O; 150 W | Acacia mollissima barks | 47.64 | H | [62] | |
EtOH; 150 W | 30.29 | ||||
EtOH (aq); 400 W | Galla chinensis | 528.5 | H | [43] | |
EtOH 96%; | Lavatera thuringiaca | 71.15 GAE | H | [58] | |
UE | MeOH 90%; 140 W | Quercus sp. | 127 | L | [63] |
EtOH 44%; 500 W | Grape by-products | 86.67 | L | [64] | |
dH2O; 301 W | Phyllanthus amarus | 27.23 | L | [65] | |
EtOH (aq); 1200 W | Galla chinensis | 491.20 | L | [43] | |
EtOH (aq) + ME; 1200 W | 543.50 | ||||
Ionic liquid B 2.5 M + ME; 1200 W | 630.2 | ||||
EtOH 96%; 216 W | Lavatera thuringiaca | 71.78 GAE | L | [58] |
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Fraga-Corral, M.; García-Oliveira, P.; Pereira, A.G.; Lourenço-Lopes, C.; Jimenez-Lopez, C.; Prieto, M.A.; Simal-Gandara, J. Technological Application of Tannin-Based Extracts. Molecules 2020, 25, 614. https://doi.org/10.3390/molecules25030614
Fraga-Corral M, García-Oliveira P, Pereira AG, Lourenço-Lopes C, Jimenez-Lopez C, Prieto MA, Simal-Gandara J. Technological Application of Tannin-Based Extracts. Molecules. 2020; 25(3):614. https://doi.org/10.3390/molecules25030614
Chicago/Turabian StyleFraga-Corral, Maria, Paula García-Oliveira, Antia G. Pereira, Catarina Lourenço-Lopes, Cecilia Jimenez-Lopez, Miguel Angel Prieto, and Jesus Simal-Gandara. 2020. "Technological Application of Tannin-Based Extracts" Molecules 25, no. 3: 614. https://doi.org/10.3390/molecules25030614
APA StyleFraga-Corral, M., García-Oliveira, P., Pereira, A. G., Lourenço-Lopes, C., Jimenez-Lopez, C., Prieto, M. A., & Simal-Gandara, J. (2020). Technological Application of Tannin-Based Extracts. Molecules, 25(3), 614. https://doi.org/10.3390/molecules25030614