A Systematic Review of Biosynthesized Metallic Nanoparticles as a Promising Anti-Cancer-Strategy
Abstract
:Simple Summary
Abstract
1. Cancer: A Global Public Health Issue
2. Genome Instability: A Basic Mechanism in Cancer Development
3. Green Synthesized Metallic NPs: An Insight
4. NPs for Cancer Therapy
5. The Fate of Cancer Cells Exposed to NPs
6. Anti-Cancer Activities of Biosynthesized Metallic NPs
6.1. Applications of Biosynthesized Silver NPs (AgNPs) as Anti-Cancer Therapeutics
6.2. Applications of Biosynthesized Gold NPs (AuNPs) as Anti-Cancer Therapeutics
6.3. Applications of Biosynthesized Zinc and Zinc Oxide NPs (Zn/ZnO-NPs) as Anti-Cancer Therapeutics
6.4. Applications of Biosynthesized Copper/Copper Oxide NPs (Cu/CuO-NPs) as Anti-Cancer Therapeutics
7. Nano-Toxicity, the Concern/Bottleneck
8. Conclusions and Future Prospects
Author Contributions
Funding
Conflicts of Interest
References
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Plant | Plant Part Used | Morphology/Size (nm) | Exposure Time | Cancer Type/Cell Line | IC50 Value | Ref. |
---|---|---|---|---|---|---|
Moringa olifera | Stem bark | Spherical/38–40 | 24 h | Cervical Cancer/HeLa | Dose dependent | [78] |
Sargassum vulgare | Whole plant | Spherical/10 | 3 h | Cervical Cancer/HeLa | Dose dependent | [79] |
Melia azedarach | Leaf | Spherical, cubical/78 | 10 min | Cervical Cancer/HeLa | 300μg/mL (LD50) | [80] |
Podophyllum hexandrum | Leaf | Spherical/14 | 30–150 min | Cervical Cancer/HeLa | 20 μg/mL | [81] |
Syzygium cumini | Leaf | Spherical/<40 | 6 h | Cervical Cancer/HeLa | Dose dependent | [82] |
Azadiracht a indica | Leaf | Hexagonal, triangular/2–18 | - | Cervical cancer/Siha | ≤4.25 μg/mL | [77] |
Acorous calamus | Rhizome | Spherical/31.86 | 20 h | Cervical cancer/Siha | Dose dependent | [83] |
Calotropis gigantea | Latex | Spherical/5–30 | 24 h | Cervical cancer/Siha | Dose dependent | [84] |
Heliotropium indicum | Leaf | Spherical/80–120 | 2 h | Cervical cancer/Siha | 20 μg/mL | [85] |
Cymodocea serrulata | Whole plant | Spherical/17–29 | 2 h | Cervical cancer/Siha | 107.7 (GI50) | [86] |
Ulva lactuca (algae) | Whole plant | Spherical/56 | 10 min | Colon Cancer/HT29 | 49 μg/mL | [87] |
Commelina nudiflora L. | Whole plant | Spherical, triangular/24–80 | 24 h | Colon Cancer/HCT-116 | 100 μg/mL | [88] |
Citrullus colocynthis | Leaf | Spherical/13.37 | 24 h | Colon Cancer/HCT-116 | >30 μg/mL | [89] |
Citrullus colocynthis | Seeds | Spherical/16.57 | 24 h | Colon Cancer/HCT-116 | >30 μg/mL | [89] |
Citrullus colocynthis | Fruit | Spherical/19.26 | 24 h | Colon Cancer/HCT-116 | 21.2 μg/mL | [89] |
Vitex negundo | Leaf | Spherical/22 | 4 h | Colon Cancer/HCT 15 | 20 μg/mL | [90] |
Rosa indica | Petal | Spherical/23.52–60.83 | 1 h | Colon Cancer/HCT 15 | 30 μg/mL | [91] |
Artemisia princeps | Leaf | Spherical/20 | 15 min | Lung cancer/A549 | Time dependent | [92] |
Gossypium hirsutum | Leaf | Spherical/13–40 | 3 min | Lung cancer/A549 | 40 μg/mL | [93] |
Origanum vulgare | Leaf | Spherical/136 ± 10.09 | Temp. dependent | Lung cancer/A549 | 100 μg/mL (LD50) | [94] |
Rosa damascene | Petal | Spherical/15–27 | 0–25 min | Lung cancer/A549 | 80 μg/mL | [95] |
Syzygium aromaticum | Fruit | Spherical/5–20 | 20 min | Lung cancer/A549 | 70 μg/mL | [96] |
Acorous calamus | Rhizome | Spherical/31.86 | 20 h | Lung cancer/A549 | Dose dependent | [77] |
Cymodocea serrulate | Leaf | Spherical/29.28 | 1 h | Lung cancer/A549 | 100 μg/mL (LD50) | [97] |
Olax scandens | Leaf | Spherical/30–60 | 2 h | Lung cancer/A549 | Dose dependent | [98] |
Scoparia dulcis | Leaf | Spherical/15–25 | 1 h | Lung cancer/A549 | Dose dependent | [99] |
Artemisia marschalliana | Shoots | Spherical/5–50 | 5 min | Gastric cancer/AGS | 21.05 μg/mL | [100] |
Taxus yunnanensis | Callus | Spherical/6.4–27.2 | 10 min | Intestinal cancer/SMMC-7721 | 27.75 μg/mL | [101] |
Cucurbita maxima | Petal | Spherical, cuboidal/76 | 5–60 min | Epidermoid cancer/A431 | 82.39 μg/mL | [102] |
Acorus calamus | Rhizome | Spherical, cuboidal/59 | 5–60 min | Epidermoid cancer/A431 | 78.58 μg/mL | [102] |
Alternanthera sessilis | Shoots/Aerial parts | Spherical/10–30 | 6 h | Breast cancer/MCF-7 | 3.04 μg/mL | [103] |
Andrographis echioides | Leaf | Pentagonal, cubic, hexagonal/68.06 | 12 h | Breast cancer/MCF-7 | 31.5 μg/mL | [104] |
Butea monosperma | Leaf | Spherical/20–80 | 2 h | Breast cancer/MCF-7 | Dose dependent | [105] |
Citrullus colocynthis | Roots | Spherical/7.39 | 24 h | Breast cancer/MCF-7 | 2.4 μg/mL | [89] |
Citrullus colocynthis | Fruit | Spherical/19.26 | 24 h | Breast cancer/MCF-7 | >30 μg/mL | [89] |
Citrullus colocynthis | Leaf | Spherical/13.37 | 24 h | Breast cancer/MCF-7 | >30 μg/mL | [89] |
Citrullus colocynthis | Seeds | Spherical/16.57 | 24 h | Breast cancer/MCF-7 | >30 μg/mL | [89] |
Erythrina indica | Root | Spherical/20–118 | Overnight | Breast cancer/MCF-7 | - | [98] |
Olax scandens | Leaf | Spherical/30–60 | 2 h | Breast cancer/MCF-7 | Dose dependent | [106] |
Piper longum | Fruit | Spherical/46 | 24 h | Breast cancer/MCF-7 | 67 μg/mL | [107] |
Rheum emodi | Root | Spherical/27.5 | 24 h | Breast cancer/MCF-7 | Dose dependent | [108] |
Syzygium cumini | Flower | Spherical/40 | 6 h | Breast cancer/MCF-7 | Dose dependent | [82] |
Taxus baccata | Needles | Spherical/56 | 10 min | Breast cancer/MCF-7 | 37 μg/mL | [109] |
Syzygium aromaticum | Fruit | Spherical/5–20 | 20 min | Breast cancer/MCF-7 | 70 μg/mL | [96] |
Ulva lactuca | Whole plant | Spherical/56 | 10 min | Breast cancer/MCF-7 | 37 μg/mL | [109] |
Achillea biebersteinii | Flower | Spherical, pentagonal/12 | 3 h | Breast cancer/MCF-7 | 20 μg/mL | [110] |
Azadirachta indica | Leaf | Spherical/<40 | 6 h | Breast cancer/MCF-7 | Dose dependent | [82] |
Melia dubia | Leaf | Irregular/7.3 | 15 min | Breast cancer/MCF-7 | 31.2 μg/mL | [111] |
Sesbania grandiflora | Leaf | Spherical/22 | 24 h | Breast cancer/MCF-7 | 20 μg/mL | [112] |
Citrullus colocynthi s | Callus | Spherical/31 | 24 h | Laryngeal Cancer/Hep-2 | 3.42 μg/mL | [113] |
Suaeda monoica | Leaf | Spherical/31 | 5 h | Laryngeal Cancer/Hep-2 | 500 nM, AgNPs conc. | [114] |
Ulva lactuca (algae) | Whole plant | Spherical/56 | 10 min | Laryngeal Cancer/Hep-2 | 12.5 μg/mL | [109] |
Rubus glaucus Benth | Root | Quasi-spherical/12–50 | 48 h | Hepatic cancer/Hep-G2 | Dose dependent | [115] |
Citrullus colocynthis | Root | Spherical/7.39 | 24 h | Hepatic cancer/Hep-G2 | 17.2 μg/mL | [116] |
Citrullus colocynthis | Fruit | Spherical/19.26 | 24 h | Hepatic cancer/Hep-G2 | 22.4 μg/mL | [116] |
Citrullus colocynthis | Leaf | Spherical/13.37 | 24 h | Hepatic cancer/Hep-G2 | 10.02 μg/mL | [116] |
Sargassum vulgare | Whole plant | Spherical/10 | 3 h | Leukemia cancer/HL-60 | Dose dependent | [79] |
Dimocarpus longan | Peel | Spherical/8–22 | 2 h | Leukemia cancer/H1299 | 5.33 μg/mL | [117] |
Azadirachta indica | Leaf | Spherical/< 40 | 6 h | Kidney cancer/Hek-293 | Dose dependent | [82] |
Plant | Plant Part Used | Morphology/Size (nm) | Exposure Time | Cancer Type/Cell Line Used | IC50 Value | Ref. |
---|---|---|---|---|---|---|
Azadirachta indica | Leaf | Spherical, triangular, hexagonal | 48 h | Cervical cancer/HeLa | No toxicity | [133] |
Genipa americana L. | Fruit | Spherical/30.4 ± 14.9 | 48 h | Cervical cancer/HeLa | No toxicity | [134] |
Dracocephalum kotschyi | Leaf | Spherical/11 | 24 h, 48 h, 72 h | Cervical cancer/HeLa | 152.16 µg/mL | [135] |
Zataria multiflora | Leaf | Pentagon, triangular/10–50 | 48 h | Cervical cancer/HeLa | 100 µg/m | [132] |
Areca catechu | Nut | Spherical/22.2 | 24 h | Cervical cancer/HeLa | 25.17 µg/mL | [136] |
Mimosa pudica | Leaf | Spherical/12 | 24 h, 48 h | Breast cancer/MCF-7 | 6 µg/mL | [121] |
Musa paradisiaca (banana) | Stem | Spherical/30 | 24 h | Breast cancer/MCF-7 | Low toxicity | [122] |
Antigonon letopus Hook. and Arn. | Aerial part | Spherical, triangular/13–28 | 48 h | Breast cancer/MCF-7 | 257.8 μg/mL | [123] |
Corallina officinalis | Aqueous Extract | Spherical/14.6 | NA | Breast Cancer/MCF-7 | NA | [125] |
Phoenix dactylifera | flower | Near spherical/95 | 24 h | Breast Cancer/MCF-7 | 4.76 μg/mL | [126] |
Vites vinefera | Aqueous Extract | Spherical/20–45 | 24 h | Breast Cancer/HBL- 100 | NA | [127] |
Acalypha indica | Leaf | Spherical/20–30 | 30 min | Breast Cancer/MDA- MB-231 | NA | [124] |
Alternanthera bettzickiana | Leaf | Spherical and aggregated/80–120 | 10 min | Lung Cancer/A549 | NA | [128] |
Sesuvium portulacastrum | Leaf | Mostly Spherical/35–40 | 0–8 h | Lung Cancer/A549 | 14 μg/mL | [129] |
Star anise (Illicium verum) | Pod | Hexagonal, triangular/20–150 | 48 h | Lung cancer/A549 | Low toxicity | [130] |
Star anise (Illicium verum) | Pod | Hexagonal, triangular/20–50 | 48 h | Lung cancer/A549 | Low toxicity at 200 nM | [130] |
Musa paradisiaca (banana) | Stem | Spherical/30 | 24 h | Kidney cancer/HEK293 | >80 nM | [122] |
Ficus religiosa | Bark | Spherical/20–30 | 24 h | Kidney cancer/HEK 293 | No toxicity | [138] |
Hibiscus sabdariffa | Leaf, stem | Near spherical/10–60 | 48 h | Kidney cancer/HEK 293 | 2 ng/mL | [137] |
Couroupita guianensis | Flower | Polydispersed, spherical, triangular, tetragonal/7–48 | 5 min | Leukaemia/HL-60 | NA | [139] |
Cajanus cajan | Seed coat | Spherical/9–41 | 24 h | Liver cancer/HepG2 | 6 µg/mL | [140] |
Plant | Plant Part Used | Morphology/Size (nm) | Exposure Time | Cancer Type/Cell Line | IC50 Value | Ref. |
---|---|---|---|---|---|---|
Abutilon indicum | Leaf | Spherical/35.2 ± 2.3 | 2–3 h | Lung cancer/Calu-6 | 9.34 ± 0.4 μg/mL | [143] |
Calotropis gigantea | Leaf | Spherical/30–35 | 3 h | Lung cancer/Calu-6 | 11.6 ± 0.9 μg/mL | [144] |
Laurus nobilis | Leaf | Hexagonal/47.27 | 4 h | Lung cancer/A549 | 11.3 ± 0.9 μg/mL | [142] |
Cannabis sativa | Leaf | Hexagonal/40 ± 1.5 | 3 h | Lung cancer/A549 | 18.3 ± 1.3 μg/mL | [145] |
Calotropis procera | Leaf | Spherical/5–40 | 4 h | Lung cancer/A549 | 15.2 ± 1.6 μg/mL | [146] |
Withania Somnifera | Leaf | Hexagonal/51.34 | 2–3 h | Leukemia/WEHI-3 | 12.4 ± 1.6 μg/mL | [147] |
Sargassum muticum | Leaf | Spherical/22.5 ± 3.5 | 3–4 h | Leukemia/WEHI-3 | 2.25 ± 0.4 μg/mL | [148] |
Tabernaemontana divaricate | Leaf | Spherical/36 ± 5 | 3 h | Breast cancer/MCF-7 | 30.6 μg/mL | [149] |
Tabernaemontana divaricate | Leaf | Spherical/36 ± 5 | 4 h | Breast cancer/MCF-7 | 30.6 μg/mL | [150] |
Tabernaemontana | Leaf | Spherical/36 ± 5 | 3–4 h | Breast cancer/MCF-7 | 30 μg/mL | [151] |
Borassus flabellifer | Leaf | Spherical/55 | 3 h | Breast cancer/MCF-7 | 0.125 μg/mL | [152] |
Embelia ribes | Root | Spherical/130–150 | 2 h | Breast cancer/MCF-7 | 9.62 ± 1.9 μg/mL | [153] |
Saccharum officinarum | Juice | Spherical/19 ± 2.3 | 4 h | Breast cancer/MCF-7 | 16.7 ± 0.5 μg/mL | [106] |
Anabaena variabilis | Phyco-bili pigment | Spherical/42 ± 3 | 5–6 h | Breast cancer/MCF-7 | 16.5 1.6 μg/mL | [154] |
Atropa belladonna | Leaf | Hexagonal/34 ± 3.2 | 2 h | Breast cancer/MCF-7 | 12 ±0.9 μg/mL | [160] |
Plant | Plant Part Used | Morphology/Size (nm) | Exposure Time | CancerType/Cell Line | IC50 Value | Ref. |
---|---|---|---|---|---|---|
Azadirachta indica | Leaf | Spherical/12 | 1 h | Cervical Cancer/HeLa | 0.89 μg/mL | [164] |
Phaseolus vulgaris | Seed | Spherical/26.6 | 7–8 h | Cervical Cancer/HeLa | NA | [163] |
Calotropis procera L. | Latex | Spherical/5–30 | 24 h | Cervical Cancer/HeLa | No toxicity | [168] |
Azadirachta indica | Leaf | Spherical/12 | 1 h | Breast cancer/MCF-7 | 27.4, 45.3, 37μg/mL | [164] |
Olea europaea | - | Spherical/20–50 | 24 h | Breast cancer/AMJ-13 | 1.47 μg/mL | [166] |
Acalypha indica | Leaf | Spherical/26–30 | 48 h | Breast cancer/MCF-7 | 56.16 μg/mL | [165] |
Ficus religiosa | Leaf | Spherical/577 | 24 h | Lung cancer/A549 | 200 μg/mL | [167] |
Calotropis procera L. | Latex | Spherical/55 | 24 h | Lung cancer/A549 | No toxicity | [168] |
Azadirachta indica | Leaf | Spherical//12 | 1 h | Lung cancer/A549 | 26.7, 21.6,μg/mL | [164] |
Olea europaea | - | Spherical/20–50 | 24 h | Ovarian cancer/SKOV-3 | 2.27 μg/mL | [166] |
Broccoli | Whole plant | Spherical/∼4.8 | 2 h | prostate cancer/PC-3 | No toxicity | [169] |
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Andleeb, A.; Andleeb, A.; Asghar, S.; Zaman, G.; Tariq, M.; Mehmood, A.; Nadeem, M.; Hano, C.; Lorenzo, J.M.; Abbasi, B.H. A Systematic Review of Biosynthesized Metallic Nanoparticles as a Promising Anti-Cancer-Strategy. Cancers 2021, 13, 2818. https://doi.org/10.3390/cancers13112818
Andleeb A, Andleeb A, Asghar S, Zaman G, Tariq M, Mehmood A, Nadeem M, Hano C, Lorenzo JM, Abbasi BH. A Systematic Review of Biosynthesized Metallic Nanoparticles as a Promising Anti-Cancer-Strategy. Cancers. 2021; 13(11):2818. https://doi.org/10.3390/cancers13112818
Chicago/Turabian StyleAndleeb, Anisa, Aneeta Andleeb, Salman Asghar, Gouhar Zaman, Muhammad Tariq, Azra Mehmood, Muhammad Nadeem, Christophe Hano, Jose M. Lorenzo, and Bilal Haider Abbasi. 2021. "A Systematic Review of Biosynthesized Metallic Nanoparticles as a Promising Anti-Cancer-Strategy" Cancers 13, no. 11: 2818. https://doi.org/10.3390/cancers13112818
APA StyleAndleeb, A., Andleeb, A., Asghar, S., Zaman, G., Tariq, M., Mehmood, A., Nadeem, M., Hano, C., Lorenzo, J. M., & Abbasi, B. H. (2021). A Systematic Review of Biosynthesized Metallic Nanoparticles as a Promising Anti-Cancer-Strategy. Cancers, 13(11), 2818. https://doi.org/10.3390/cancers13112818