Current Trends in the Pharmacotherapy of Cataracts
Abstract
:1. Introduction
1.1. Classification, Signs and Symptoms of Cataracts
1.2. Lens Anatomy and Physiology
1.3. Lens Transparency
2. Antioxidant Systems in the Lens
2.1. Non-Enzymatic Antioxidants
2.2. Enzymatic Antioxidants
3. Molecular Mechanisms of Cataract Formation
4. Treatments Strategies for Cataracts
4.1. Current Cataract Treatments
4.2. Potential Pharmacological Treatments for Cataracts
4.2.1. Antioxidants
4.2.2. Non-Steroidal Anti-Inflammatory Drugs (NSAIDs)
4.2.3. Miscellaneous Drugs
5. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
Abbreviations
ACE | Angiotensin converting enzyme |
ATPase | Adenosine triphosphatase |
BSO | Buthionine sulfoximine |
CAT | Catalase |
CNS | Central nervous system |
Cu | Copper |
EC | Extracellular |
EGCG | Epigallocatechin-3-gallate |
GSH | Glutathione |
GSH-Px | Glutathione peroxidase |
GSPE | Grape seed proanthocyanidin extract |
GSH-Rx | Glutathione reductase |
GSSG | Glutathione disulfide |
GST | Glutathione-S-Transferase |
K+ | Potassium cation |
Mn-SOD | Mitochondrial-superoxide dismutase |
Na+ | Sodium cation |
Na+-K+-ATPase | sodium-potassium adenosine triphosphatase |
NADPH | Nicotinamide adenine dinucleotide phosphate |
NSAIDs | Non-steroidal anti-inflammatory drugs |
SOD | Superoxide dismutase |
TGF-β | Transforming growth factor beta |
UV | Ultraviolet |
UVA | Ultraviolet A |
UVB | Ultraviolet B |
Zn | Zinc |
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Type of Cataracts | Causes | Vulnerable Population |
---|---|---|
Congenital and developmental | Heredity, gestational maldevelopment of lens, maternal malnutrition, infection, drugs, radiation, fetal/infantile factors-anoxia, metabolic disorders, birth trauma, malnutrition, congenital anomalies, idiopathic | It may occur since birth or from infancy to adolescence |
Age-related | Senescent changes, dehydration, systemic diseases, smoking, oxidative stress, and lack of essential dietary elements | Elderly persons, mostly those over the age of 50 years |
Traumatic | Some physical damage to the eye lens capsule, penetration of foreign object | People working in hazardous conditions such as welders and those in glass furnaces |
Complicated | Complications of some chronic inflammatory and degenerative eye diseases | Patients of skin diseases, allergy, uveitis, glaucoma, diabetes, emphysema, asthma |
Metabolic | Metabolic disorders—diabetes mellitus, galactosemia | Persons deficient in certain enzymes and hormones |
Toxic | Certain toxicants and drugs- Steroids, NSAID’s | People on steroid therapy and toxic drugs |
Radiation and electrical | Infra-red rays, x-rays, ultra-violet rays, and powerful electric current | Persons who encounter excess sunlight, artificial radiations, high voltage |
Protein | Size (Da) | Residues | ΔG (kJ/mol) | Gene | Chromosomal Location |
---|---|---|---|---|---|
αA | 19 909 | 173 | 27 | CRYAA | 21q22.3 |
αB | 20 159 | 175 | 21 | CRYAB | 11q23.1 |
βA1 | 23 191 | 198 | – | CRYBA1 | 17q11.2 |
βA2 | 21 964 | 196 | – | CRYBA2 | 2q35 |
βA3 | 25 150 | 215 | 58 | CRYBA1 | 17q11.2 |
βA4 | 22 243 | 195 | – | CRYBA4 | 22q12.1 |
βB1 | 27 892 | 251 | 67 | CRYBB1 | 22q12.1 |
βB2 | 23 249 | 204 | 49 | CRYBB2 | 22q11.23 |
βB3 | 24 230 | 211 | – | CRYBB3 | 22q11.23 |
γC | 20 747 | 173 | 36 | CRYGC | 2q33.3 |
γD | 20 607 | 173 | 69.4 | CRYGD | 2q33.3 |
γS | 20 875 | 177 | 43.9 | CRYGS | 3q27.3 |
Class | Drugs Tested | Cataract Stimuli | Tissue | Pharmacological Action | Ref |
---|---|---|---|---|---|
Antioxidants | GSH | H2O2 (10 mM) | Goat lenses | Increased lenticular antioxidant defense enzymes and decreased malondialdehyde levels | [87] |
Ascorbic acid and GSH | Incubation in riboflavin and exposure to sunlight | Bovine lens soluble proteins | Reduced structural crosslinking and proteolytic instability of lens crystallins | [88] | |
Alpha-tocopherol, lutein and zeaxanthin | H2O2 (100 µM) | Human lens epithelial cells | Alpha-tocopherol, lutein and zeaxanthin protected lens protein, lipid, and DNA from oxidative damage. Unlike α-tocopherol, lutein and zeaxanthin did not mitigate GSH depletion. | [89] | |
Vitamin C or vitamin E | Buthionine sulfoximine (25–200 µM) treatment followed by H2O2 (0–800 µM) | Rabbit lens epithelial cells | Pretreatment with vitamin C (25–50 µM) or vitamin E (5–40 µM), restored the resistance of GSH-depleted cells to H2O2 upholding GSH in its reduced form. | [90] | |
Alpha- tocopherol | Glucose (55 mM) | Goat lenses | Increased water-soluble protein content and Na+-K+-ATPase activity while reducing malondialdehyde levels. | [91] | |
Aminothiol WR-1065 and anetholedithiolethione (20 µM) | X-ray irradiation (10 Gy at rate of 2 Gy/min) | Bovine lens epithelial cells | Increased GSH levels and cell viability accompanied by decreased HO fluorescence and lower proportion of cells with apoptotic morphology. | [93] | |
Alpha lipoic acid | H2O2 (0.2 mM) | Adult Sprague-Dawley rat lenses | Inhibited lens’ epithelial cell apoptosis and activated lenticular anti-oxidative enzymes. | [99] | |
Ketoacids and amino acid antioxidants | Pyruvate, alpha ketoglutarate, oxaloacetate | H2O2 (10 mM) | Goat lenses | Pyruvate (10 mM), alpha ketoglutarate (20 mM) and oxaloacetate (20 mM) decreased lenticular malondialdehyde while augmenting GSH-Px activity. | [104] |
Pyruvate | H2O2 (10 mM) | Goat lenses | Increased lenticular antioxidant defense enzymes and decreased malondialdehyde levels | [87] | |
Pyruvate | H2O2 (2 mM) | Sprague-Dawley rat lenses | Decreased water insoluble proteins (urea soluble) level and prevented loss of gamma crystallin fraction. | [105] | |
Ketoacids and amino acids | H2O2 (1 mM) | Goat lens | All amino acids (1 mM) protected against GSH depletion except l-tyrosine and l-phenylalanine. All amino acids prevented oxidative stress-induced lens protein aggregation except L aspartic acid. | [107] | |
N-acetylcysteine amide | Exposure to hyperoxia- | Rabbit lenses | Increased GSH and water-soluble protein content. However, it lowered Na+, K+-ATPase, and CAT activity. | [112] | |
N-acetylcysteine amide | Dexamethasone (5 µM) | Sprague-Dawley rat lenses | Elevated GSH/GSSG ratio and limiting lipid peroxidation | [113] | |
Acetyl-l-carnitine | Sodium Selenite (100 µM) | Wistar rat lenses | Augmented CAT and GSH-Px activity while reducing malondialdehyde levels. | [116] | |
Propolis | Glucose (55 mM) | Rat lens epithelial cells | Propolis (5 and 50 μg/mL) attenuated both the glucose (55 mM)-induced elevation in the expression of reactive oxygen species and elevation in cell viability | [117] | |
Plant-derived compounds and Herbal remedies | Quercetin | Glucose (55 mM) | Goat lenses | Increased water-soluble protein content and Na+-K+-ATPase activity while reducing malondialdehyde levels. | [91] |
Chrysin, a flavonoid present in honey | Sodium selenite (100 µM/mL) | Wistar rat lenses | Chrysin (200 µM/mL) prevented cataractogenesis. Increased activity of calpain and lenticular preferred calpain (Lp82), as well as mRNA transcript levels of genes that encode m-calpain and Lp82. Lowered calcium transporter proteins and lenticular apoptotic-cascade proteins along with mRNA transcripts of the genes. | [120] | |
Epigallocatechin-3-gallate (EGCG), a polyphenol derived from green tea | H2O2 | Human γ-crystallin | EGCG attenuated and reversed peroxide-induced aggregation of αA(66–80), a peptide fragment derived from αA-crystallin peptide | [122] | |
Green tea (Camellia sinensis) leaves extract | Sodium selenite (100 µM) | Wistar rat lenses | Preserved SOD, GSH-Px, and CAT activities | [123] | |
Drevogenin D, a triterpenoid aglycone from Dregeavolubilis | Sodium selenite (100 µM) | Rat lenses | Increased activity of SOD, CAT, GSH-Px, and GSH-Rx. It augmented the level of reduced GSH and protein sulfhydryl, while it reduced lipid peroxidation. | [127] | |
Aqueous extract of Trigonellafoenum-graecum (Fenugreek) | Sodium selenite (100 µM) | Wistar rat lenses | Restored GSH and activities of SOD, GSH-Px and GST while decreasing malondialdehyde levels. | [131] | |
A herbal preparation—Triphala (composed of Emblica officinalis, Terminalia chebula, and Terminalia belerica) | Sodium selenite (100 µM) | Wistar rat lenses | Restored GSH content and activities of SOD, CAT, GSH-Px and GST while malondialdehyde levels were decreased. | [132] | |
Ethanol extract of Moringa oliefera | Glucose (55 mM) | Goat lenses | Extracts (200 µg/mL and 500 µg/mL) reduced malondialdehyde levels and increased lenticular CAT, GSH, total and soluble protein. | [136] | |
Hydro-ethanolic leaf extract of Abutilon indicum | Glucose (55 mM) | Goat lenses | Extract (500 µg/mL) reduced malondialdehyde level and increased total protein content and SOD activity. | [140] | |
Ethanol extract of Zingiberofficinale | Glucose (55 mM) | Goat lenses | Extract (100, 300, and 500 ng/mL) increased protein (total and water-soluble proteins) content and Na+-K+-ATPase activity while reducing malondialdehyde levels. | [141] | |
Aqueous extract of Seabuckthorn (Hippophaerhamnoides L.) leaves | H2O2 (0.5 mM) | Goat lenses | Reinstated the level of SOD and GSH while reducing malondialdehyde levels | [144] | |
Aqueous leaf extract of Abiespindrow | H2O2 | Goat lenses | Extracts (5, 10, 15, and 20 mg/mL) increased SOD, GSH, total protein content while lowering malondialdehyde levels proportionally with increase in concentration. | [147] | |
Fruit extract of Luffa cylindrica | H2O2 (0.5 mM) | Goat lenses | Increased SOD, GSH, and total protein content while lowering malondialdehyde content. | [151] | |
Ocimum sanctum | Sodium selenite (100 µM) | Wistar rat lenses | Increased SOD, GSH-Px, GST, and CAT. | [153] |
Drug | Cataract Stimuli | Animal Model | Mode of Application | Pharmacological Action | Ref | |
---|---|---|---|---|---|---|
Antioxidants | Vitamin C (Ascorbic acid) | Sodium selenite (20 μmol/kg) | White New Zealand rabbits | Subcutaneous injection | Decreased cataractogenesis by 40% | [162] |
Sodium selenite, 100 µL of 20 μmol/kg | Sprague–Dawley rats | Subcutaneous injection | Subcutaneous 0.1 mL of vitamin C (0.3 mM) injection on 8th day postpartum increased concentration of total protein and soluble protein. Comparable electrophoretic pattern of lens proteins to untreated. | [163] | ||
10% dietary galactose | Guinea pigs | Dietary | Intensified the loss of Na+-K+ ATPase activity in the lens capsule-epithelium caused by galactose feeding. Oxidized GSH was not detectable in the lens capsule epithelia. Hexose monophosphate shunt activity was not elevated in lenses of pigs during the first hour of culture after euthanasia | [164] | ||
Sodium selenite (20 μmol/kg) | Sprague–Dawley rats | Dietary | Ascorbic acid attenuated onset of cataract and loss in chaperone activity. | [165] | ||
Vitamin E | Sodium selenite (20 μmol/kg) | Sprague–Dawley rats | Subcutaneous injection | Vitamin E attenuated selenite-induced onset of cataract and the corresponding loss in chaperone activity. | [165] | |
Prednisolone acetate | Brown–Norway rats | Eye drops | Vitamin E attenuated steroid-induced cataract formation probably due to its antioxidant effect and on the stability of the lens fiber membrane. | [167] | ||
Ultraviolet B (UVB) radiation | Albino Sprague–Dawley rats | Dietary | Vitamin E attenuated intensity UVB-induced opacity and enhanced lenticular GSH content. | [169] | ||
Streptozotocin (55 mg/kg) | Wistar rats | Dietary | Vitamin E delayed onset of advanced cataracts | [171] | ||
Vitamin E- and selenium | SDZ ICT 322 (selective 5-HT3 antagonist) | Wistar rats | Dietary | Deficiency of vitamin E and selenium accelerated onset of cataracts and enhanced lipid peroxidation | [168] | |
Alpha-lipoic acid | Fructose | Sprague–Dawley albino rats | Gavage | Retarded onset and progression of cataract. Increased CAT, SOD, GSH-Px, GSH and total protein. It also increased activity of Ca2+ ATPase activity while it reduced malondialdehyde and Ca2+. | [172] | |
l-buthionine(S,R)-sulfoximine | Sprague–Dawley rats | Intraperitoneal injection | Increased lenticular GSH, ascorbate, and vitamin E. | [173] | ||
Stobadine | Streptozotocin (55 mg/kg) | Wistar rats | Dietary | Reduced plasma malondialdehyde and replenished lenticular Sulfhydryl groups. | [171] | |
Melatonin (4 mg/Kg) | Buthionine sulfoximine (3 mmol/kg) | New born rats | Intraperitoneal injection | Inhibited cataract formation in rats evidenced with increased total GSH possibly due to its free radical property or stimulated GSH production. | [178] | |
Minerals and trace elements | Zinc sulfate | Sodium selenite | Rabbits | Eye drops | Retard opacities progression and lowered opacity score. | [183] |
Ebselen | Sodium selenite (30 nmol/kg) | Sprague–Dawley rat s | Subcutaneous injection | Increased GSH levels while it lowered malondialdehyde levels and total nitrite level. | [187] | |
Ketoacids and amino acids | Sodium pyruvate | streptozotocin (55 mg/kg) | Sprague–Dawley rats | Dietary | Decreased levels of glycated proteins, sorbitol, malondialdehyde while it increased activity of the cation pump. | [188] |
Pyruvate | Sodium selenite (0.5 µmoles) | Sprague–Dawley rats | Intraperitoneal injection | It prevented cataractogenesis and its level was increased in the aqueous humor. | [105] | |
l-cysteine | Sodium selenite, 100 µL of 20 μmol/kg | Sprague–Dawley rats | Subcutaneous injection | Subcutaneous 0.1 mL of l-cysteine (0.05 μmol) on 8th day postpartum increased concentration of total protein and soluble protein. Comparable electrophoretic pattern of lens proteins to untreated. | [158] | |
N-acetylcysteine | Sodium selenite subcutaneously (30 nmol/g). | Sprague–Dawley rat | Intraperitoneal injection | Reduced cataract formation by 71.4%. Increased lenticular and serum GSH while reducing lenticular protein carbonyl and lenticular and serum malondialdehyde level. | [189] | |
Triamcinolone acetonide (1 mg) | Wistar–Albino rats | Intraperitoneal injection | Increased lenticular GSH and GSH-Px while it reduced the level of protein carbonyl and malondialdehyde. | [190] | ||
N-acetylcysteine amide and GSH ethyl ester | Streptozotocin (65 mg/kg) | Sprague–Dawley rats | Eye drops | Inhibited cataract progression at an early after which activity declined. Did not increase GSH-Px and CAT. Increased glycation levels and thiols. | [191] | |
N-acetylcysteine amide | l-buthionine-(S,R)-sulfoximine | Wistar rats | Intraperitoneal injection | Replenished GSH levels of replenished and limited protein carbonylation, lipid peroxidation, and redox system components. | [193] | |
Sodium selenite | Wistar rats | Intraperitoneal injection | Reversed cataract grade. Increased GSH level, thioltransferase activity, m-calpain activity, and m-calpain levels while it reduced malondialdehyde level, GSH-Px enzyme activity, and calcium levels | [192] | ||
Sodium selenite | Wistar rats | Eye drops | Reversed cataract grade. Increased GSH level, thioltransferase activity, m-calpain activity, and m-calpain levels while it reduced malondialdehyde level, GSH-Px enzyme activity, and calcium levels | [192] | ||
Acetyl-l-carnitine | Sodium selenite | Wistar rats | Intraperitoneal injection | Increased GSH content as well as GST and GSH-Px activity while it lowered malondialdehyde level. It also increased staining intensity of isozyme bands for SOD and GSH-Px. | [194] | |
Plant-derived compounds and herbal remedies | water-insoluble antioxidants (lutein, zeaxanthin hesperetin, quercetin, anthocyanin, β-carotene, and α-tocopherol) and water-soluble antioxidants (ascorbic acid, cyanidin) | Sodium selenite (20 μmol/Kg) | Sprague Dawley rats | Subcutaneous injection | Maintained activity of chaperone activity in water soluble lens proteins. | [165] |
Rutin | Sodium selenite (19 µmol/kg) | Wistar rats | Intraperitoneal injection | Inhibited lipid peroxidation and increased activity of SOD, CAT, GSH-Px, and, GST. | [197] | |
Hesperetin (flavonoid) | Sodium selenite (20 μmol/Kg) | Sprague–Dawley rats | Subcutaneous injection | Increased expression of the of filensin (94 and 50 kDa forms). Interestingly, these forms of filensin Increased lenticular GSH and ascorbic acid levels. | [200] | |
Hesperetin (flavonoid) and derivatives | Sodium selenite (20 μmol/Kg) | Sprague–Dawley rats | Subcutaneous injection | Mitigated decreased lens chaperone activity and α-crystallin water solubility. | [201,202] | |
Ellagic acid | Sodium selenite (19 µmol/kg) | Wistar rats | Intraperitoneal injection | Lenticular and erythrocytic GSH were increased while it reduced lenticular malondialdehyde and calcium content. | [206] | |
Green tea (Camellia sinensis) | Sodium selenite (0.25 µmol/Kg) | Wistar rats | Intraperitoneal injection | Decreased cataractogenesis by 66.67% | [207] | |
Green or black tea extracts | Sodium selenite (2.2 mg/kg) | Wistar rats | Subcutaneous injection | Scavenged reactive oxygen species and prevented oxidative cross-linking of proteins and single strand breakage of DNA. | [207] | |
Streptozotocin (65 mg/Kg) | Sprague–Dawley rats | Drinking water | Hypoglycemic effect retreaded cataract formation. | [208] | ||
Caffeine | Ultra-violate-B radiation | Sprague–Dawley rats | Eye drops | Reduced caspase-3 and lens sensitivity to ultra-violate-B by 1.23 times. | [211] | |
Sodium selenite (15 µmol/kg) | Sprague–Dawley rats | Gastric intubation | Reduced lenticular level of malondialdehyde, total nitric oxide, Ca+-ATPase, tumor necrosis factor-α, interleukin-1β, SOD, while it increased lenticular total protein, reduced GSH, and CAT. | [212] | ||
Caffeine and pyrocatechol | Sodium selenite (20 μmol/Kg) | Sprague–Dawley rats | Subcutaneous injection | Maintained activity of chaperone activity in water soluble lens proteins. | [165] | |
β-carotene | Sodium selenite (20 μmol/Kg) | Sprague–Dawley rats | Subcutaneous injection | Maintained activity of chaperone activity in water soluble lens proteins. | [165] | |
Lycopene | Dietary 30% galactose | Wistar rats | Intraperitoneal injection | Reduced selenite induced cataract by 89% and reduced onset and progression of galactose induced cataract was observed with oral feeding of lycopene. Only 35% of the eyes developed mature cataract as opposed to 100% in the control group | [217] | |
Dietary 30% galactose | Wistar rats | Intraperitoneal injection | Reduced selenite induced cataract by 89% and reduced onset and progression of galactose induced cataract were observed with oral feeding of lycopene. Only 35% of the eyes developed mature cataract as opposed to 100% in the control group | [217] | ||
Curcumin | Galactose (30%) | Sprague–Dawley rats | Dietary | Augmented GSH while it reduced malondialdehyde levels. It also inhibited advanced glycation end product formation and protein aggregation. | [218] | |
Sodium selenite (30 µM/Kg) | Wistar rats | Subcutaneous injection | Increased activity of SOD and CAT while it reduced malondialdehyde levels and xanthine oxidase activity. | [219] | ||
Sodium selenite (15 µM/Kg) | Wistar rats | Intraperitoneal injection | Reduced malondialdehyde levels while it increased SOD, GSH-Px, GST, and CAT activity. | [220] | ||
Streptozotocin (35 mg/Kg) | WNIN rats | Dietary | Reduced malondialdehyde levels, increased reduced GSH, protein carbonyl content and activities of peroxide dismutase, GSH-Px, and glucose-6-phosphate dehydrogenase | [221] | ||
Turmeric | Streptozotocin (35 mg/kg) | Wistar–NIN rats | Dietary | Reduced lipid peroxidation and protein carbonyl content while it increased GSH and antioxidant enzyme activities. | [221] | |
Resveratrol | Sodium selenite (30 nmol/g) | Spraque–Dawley rats | Subcutaneous injection | Increased lenticular and erythrocytic GSH and lowered malondialdehyde levels. | [225] | |
Heliotropiumindicum extract | Sodium selenite (15 µmol/kg) | Sprague–Dawley rats | Oral | Preserved epithelial and lens fiber integrity, aquaporin 0, alpha A and B crystallins, total lens proteins, and lenticular GSH levels. It also showed free radicals scavenging activity and inhibited lipid peroxidation. | [228] | |
Hydroalchoholic extract of Echium amoenum | Sodium selenite (30 nmol/kg) | White rats | Intraperitoneal injection | Improved cataract grade and optical clarity of lenses. | [230] | |
H636 grape seed proanthocyanidin extract | Sodium selenite (30 nmol/g) | Spraque–Dawley rats | Oral | Increased lenticular GSH content and reduced malondialdehyde. | [233] | |
Cassia tora Linn. leaves | Sodium selenite (4 μg/g) | Spraque–Dawley rats | Oral | Reduced oxidative stress index, prevented structural crystallin loss, and increased total peroxide level. | ||
Vaccinium corymbosum leaf decoction (chlorogenic acid, quercetin, rutin, isoquercetin and hyperoside) | Sodium selenite (20 µmole/Kg) | White rats | Intraperitoneal injection | Prevented oxidative attack and calpain activation, protein loss and aggregation. | [236] | |
Emilia sonchifolia (flavonoid fraction) | Sodium selenite (4 mg/kg) | Rat | Intraperitoneal injection | Increased GSH, activities of SOD and CAT while thiobarbituric acid reacting substances were reduced. | ||
Brassica oleracea var. italica (flavonoid fraction) | Sodium selenite (4 mg/kg) | Sprague–Dawley rats | Intraperitoneal injection | Increase SOD, CAT, GSH, Ca2+ ATPase while it reduced, calcium, calpains and lipid peroxidation product-thiobarbituric acid reacting substances | [241] | |
Lupeol, a flavonoid from the plant, Vernonia cinereal plant | Sodium selenite (25 μg/g) | Sprague–Dawley rats | Oral | Reduced lipid peroxidation and protein oxidation. Upheld activity of. Lenticular SOD, CAT, GSH-Px, GSH-Rx, GST, and GSH content. | [243] | |
Methanolic extract of Allium sativum | Streptozotocin (34 mg/kg body weight) | Wistar rats | Forced gut- feeding | Delay in onset of cataracts; Restoration of lenticular GSH, GSH-Px and SOD activities | [245] | |
Aqueous extract of Allium cepa | Sodium selenite (30 nmol/g body weight) | Wistar albino rats | Eye drops | The allium aqueous extract of garlic preserved optical clarity; Allium-treated lenses exhibited higher total antioxidants and higher GSH-Px and SOD activities | [246] | |
Pinus densiflora bark extract | Sodium selenite (18 μmol/kg) | Sprague–Dawley rats | Gastric intubation | Increased water-soluble protein and GSH content, SOD, GSH-Px, and CAT activity while it lowered water-insoluble protein, malondialdehyde, and Ca2+-ATPase. It inhibited m-calpain-induced proteolysis and apoptosis. | [249] | |
Ocimum sanctum | Sodium selenite (25 µmole/kg) | Wistar rats | Intraperitoneal injection | Prevented lens protein insolubilization. | [153] | |
Crocus sativus stigmas (saffron) extra | Sodium selenite (20 µmol/kg) | Wistar rats | Intraperitoneal injection | Increased activities of SOD, GSH-Px, CAT and GSH content. Halted lipid peroxidation, protein oxidation, and proteolysis and insolubilization of water-soluble proteins. | [251] | |
Propolis | d-galactose (15% or 25%) | Sprague–Dawley albino rats | Oral (dietary) | Reduced reactive oxygen species and improved epithelial cell viability. | [117] | |
An aqueous extract of Pterocarpus marsupium Linn bark and alcoholic extract of Trigonellafoenum-graecum Linn seeds | Alloxan 120 mg/Kg | Rats | Gastric tube | Showed antihyperglycemic effect and reduced opacity index. | [253] | |
Ginkgo biloba | Total-cranium irradiation (5 Gy) | Sprague–Dawley rats | Oral | Increase the activities of SOD and GSH-Px while it reduced and significantly decreased malonaldehyde content. | [256] | |
A herbal preparation-Triphala (Emblica officinalis, Terminalia chebula, and Terminalia belerica) | Sodium selenite (100 µM) | Wistar rat lenses | Intraperitoneal injection | Delayed onset and progression of cataracts | [132] |
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Heruye, S.H.; Maffofou Nkenyi, L.N.; Singh, N.U.; Yalzadeh, D.; Ngele, K.K.; Njie-Mbye, Y.-F.; Ohia, S.E.; Opere, C.A. Current Trends in the Pharmacotherapy of Cataracts. Pharmaceuticals 2020, 13, 15. https://doi.org/10.3390/ph13010015
Heruye SH, Maffofou Nkenyi LN, Singh NU, Yalzadeh D, Ngele KK, Njie-Mbye Y-F, Ohia SE, Opere CA. Current Trends in the Pharmacotherapy of Cataracts. Pharmaceuticals. 2020; 13(1):15. https://doi.org/10.3390/ph13010015
Chicago/Turabian StyleHeruye, Segewkal H., Leonce N. Maffofou Nkenyi, Neetu U. Singh, Dariush Yalzadeh, Kalu K. Ngele, Ya-Fatou Njie-Mbye, Sunny E. Ohia, and Catherine A. Opere. 2020. "Current Trends in the Pharmacotherapy of Cataracts" Pharmaceuticals 13, no. 1: 15. https://doi.org/10.3390/ph13010015
APA StyleHeruye, S. H., Maffofou Nkenyi, L. N., Singh, N. U., Yalzadeh, D., Ngele, K. K., Njie-Mbye, Y. -F., Ohia, S. E., & Opere, C. A. (2020). Current Trends in the Pharmacotherapy of Cataracts. Pharmaceuticals, 13(1), 15. https://doi.org/10.3390/ph13010015