Cyclodextrin Inclusion Complexes for Improved Drug Bioavailability and Activity: Synthetic and Analytical Aspects
Abstract
:1. Introduction
2. Cyclodextrins for Increased Bioavailability
3. Cyclodextrins for Improved Drug Solubility
4. Cyclodextrins for Improved Drug Stability
5. Cyclodextrins for Solving Formulation Problems
6. Cyclodextrins for Targeted Drug Delivery
6.1. Introduction: Cyclodextrin-Derived Nanoparticles and the EPR Effect
6.2. Cyclodextrin-Based Nanoparticles for Combined Photothermal/Chemotherapy
7. Cyclodextrins for Increasing the Bioavailability of Diet Components
8. Cyclodextrin Nanofibers
9. Functionalization of Cyclodextrins: Synthetic Aspects
9.1. Introduction
- (a)
- Straightforward selective modification of the desired positions. This is chemically challenging due to the competition between the hydroxyl groups at positions 2, 3, and 6 of the glucopyranose.
- (b)
- Protection–deprotection strategies which involve taking advantage of the different reactivity of the hydroxyl groups toward protection and deprotection conditions. Deprotected hydroxyl groups can then undergo the desired modifications.
- (c)
- Non-selective modification of hydroxyl groups to provide a mixture of derivatives that is then purified to isolate the desired one. This method generates a large number of undesired by-products, requires tedious purifications, and is not chemically efficient.
9.2. Selective Modification of the Primary Rim
9.2.1. Monosubstitution at C6-OH
9.2.2. Disubstitution at C6-OH
9.2.3. Other C6-OH Substitution Patterns
9.3. Selective Modification of the Secondary Rim
9.3.1. Monosubstitution at C2-OH
9.3.2. Disubstitution at C2-OH
9.3.3. Persubstitution at C2-OH
9.3.4. Monosubstitution at C3-OH
9.3.5. Di- and Trisubstitution at C3-OH
9.3.6. Persubstitution at C3-OH
9.4. Persubstitution of the Primary and Secondary Rims
9.5. Cyclodextrin-Based Polymers
9.5.1. Radical Polymerization Reactions
9.5.2. Ring-Opening Polymerization (ROP)
9.5.3. CuAAC-Based Polymerization
9.6. Cyclodextrin-Embedded Covalently Crosslinked Networks
10. Analytical Aspects
10.1. Introduction
10.2. Analytical Techniques for Studying Inclusion Complexes in the Solid State
10.2.1. X-ray Diffraction
10.2.2. Thermal Analytical Techniques
10.2.3. Electron Microscopy
10.2.4. Spectroscopic Techniques
10.3. Analytical Techniques for Studying Inclusion Complexes in Solution
10.3.1. UV-Vis Absorption Spectroscopy
10.3.2. Fluorescence Spectroscopy
10.3.3. Nuclear Magnetic Resonance Spectrometry (NMR)
10.3.4. Separation Techniques
10.3.5. Other Techniques
10.4. Analytical Techniques for Determining Drug Loading and Encapsulation Efficiency
11. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Data Availability Statement
Conflicts of Interest
References
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CD | Cavity Diameter (Å) | Outer Diameter (Å) | Cavity Volume (Å3) | Height (Å) | Molecular Weight (g/mol) | Aqueous Solubility (mg/mL) |
---|---|---|---|---|---|---|
α | 4.7–5.3 | 14.6 | 174 | 7.9 | 973 | 145 |
β | 6.0–6.5 | 15.4 | 262 | 7.9 | 1135 | 18.5 |
γ | 7.5–8.3 | 17.5 | 427 | 7.9 | 1297 | 232 |
Drug | Bioactivity | Cyclodextrin/Polymer | Improvement/Enhancement | Ref. |
---|---|---|---|---|
Atorvastatin | Anti-hyperlipidemic drug that interferes in cholesterol biosynthesis | β-CD-based nanosponges cross-linked with carbonyl diimidazole | Improved solubilization and dissolution rate; enhanced oral bioavailability | [68] |
Boswellic acids | Triterpenic acids with anti-inflammatory activity | Complexes with β-CD and HPβ-CD | Drug release and oral bioavailability enhancement due to the increase in the solubility | [30] |
Camptothecin | Alkaloid with anticancer activity | HPβ-CD; 6-O-capro-β-CD; and polymeric nanoparticles of these CDs with poly-ε-caprolactone and poly (lactide-co-glycolide) | Enhanced anti-tumor activity due to the stabilization of the active form (lactone) | [52] |
Camptothecin, Luotonin A | Alkaloids with anticancer activity | Complexes with β-CD and HPβ-CD | Enhanced solubility and stability. Improvement in anti-tumor activity with luotonin A reaching camptothecin-like activity | [50] |
Carbamazepine | Treatment of epilepsy and neuropathic pain | Inclusion complexes with β-CD, HPβ-CD, and γ-CD | Improved equilibrium solubility, in vitro dissolution rates, and oral bioavailability | [69] |
Curcumin | Natural hydrophobic polyphenolic compound with a variety of pharmacological activities | γ-CD complex | Increase in plasma levels of curcumin; significant increase in oral bioavailability | [70,71] |
Cyclosporin | Peptide isolated from fungus acting as immunosuppressant and in ophthalmic preparations | Polymers based on HPβ-CD and poly(ethyleneglycol) diglycidyl ether | The polymer incorporating HPβ-CD allows good penetration of cyclosporine through sclera and ocular tissues | [72] |
Doxorubicin | Anti-cancer drug | β-CD grafted onto graphene oxide with L-phenylalanine as a linker | Enhancement of 10–40% in cytotoxicity activity with regard to free drugs | [73] |
Doxorubicin | Anti-cancer drug | Nanogels based on β-cyclodextrin-modified chitosan | Enhancement in the sustained release profile into the tumor cells; increased anti-tumor activity | [74] |
Eugenol | Methoxyphenol derivative with analgesic, anti-inflammatory properties employed as cement component in clinical dentistry | Complexes with α-CD and β-CD | Suggested increased bioavailability | [75] |
Flavonoids | Natural polyphenolic compounds with antioxidant and anti-inflammatory activity | Several CDs | Enhanced oral bioavailability with an increase in the biological activity | [76] |
Flurbiprofen | Nonsteroidal anti-inflammatory drug employed in the treatment of intraocular inflammation | γ-CD-based polypseudorotaxane hydrogels | Improved the precorneal drug retention ability, corneal permeability, and intraocular bioavailability | [77] |
Genistein | Isoflavone with anti-cancer activity | Amino-appended β-CDs | Complex solubility increased 1000-fold compared with free genistein; cytotoxic activity also increases | [78] |
Ginsenoside Re | A triterpene present in ginseng root with effects on ischemic damage of the cardiovascular system | Complexes with α-CD, β-CD, and γ-CD | Dissolution rate is increased ca. 10% and bioavailability is enhanced by 1.71% for the complex with γ-CD with regard to the free compound | [79] |
Irinotecan, Topotecan, Doxorubicin | Anticancer drugs and topoisomerase inhibitors | Heptakis-[6-deoxy-6-(3-sulfanyl HX acid)]-β-cyclodextrin; HX = acetic or propionic acid | pH-controlled release of anticancer drugs due to negative charge of polyanionic CDs | [80] |
Melatonin/sulforaphane hybrid | Treatment of ischemic stroke | HPβ-CD complexes | A 34-fold increase in solubility; stabilization at several pH and temperature values | [81] |
17-α-Methyltestosterone | Androgen | β-CD complex | A 6-fold hydrosolubility enhancement, with sustained release of the hormone | [82] |
Methotrexate 5-Fluorouracil | Antimetabolites employed for cancer treatment | β-CD/glycerol organogel based on self-aggregation of β-CD | Sustained drug release providing an improved therapeutic effect | [83] |
Morin | Flavonoid present in tea, wine, fruits, and vegetables acting as an antioxidant, anti-inflammatory | Complexes with HPβ-CD | Increased solubility and dissolution rate; oral bioavailability increased 4.2-fold compared with the free natural product | [84] |
Nifedipine | Calcium-channel blocking agent for hypertension treatment | Multicomponent complexes with β-CD and aspartic acid | Enhancement of solubility and increase in dissolution rate | [85] |
Nintedanib | Kinase inhibitor for the treatment of pulmonary fibrosis | Complexes with sulfobutyl ether-β-cyclodextrin | Improved stability at physiological pH and enhanced membrane transport | [86] |
Norfloxacin | Fluoroquinolone antibiotic employed for urinary tract infections | β-Cyclodextrin-based nanosponges cross-linked with diphenyl carbonate | Controlled release of norfloxacin with enhanced membrane permeability and antibiotic efficiency | [87] |
Oleuropein Hydroxytyrosol Tyrosol | Polyphenols present in olives and olive oil (functional foods) with antioxidant activity | Complexes with native β-CD | A 12–14% enhancement in the anti-oxidant activity (DPPH method) | [88] |
Sulforaphane | Natural product isolated from broccoli with anticancer properties | Complexes with α-CD | Chemical stabilization | [89] |
Tamoxifen | Antiestrogen—employed in hormone treatment of breast cancers | M-β-CD; HP-β-CD; and Sulfobutyl ether-β-cyclodextrin | Enhanced solubility and dissolution rate of tamoxifen inclusion complexes. Significant improvement in oral bioavailability | [90] |
Umbelliferon | Coumarin derivative with lipid-lowering capability, and anticarcinogenic and HIV-inhibition activities | Complexes with α-CD | Potential sunscreen agent for protection from UV radiation | [91] |
Guest | Host a | Solution State | Solid State | Ref. | |||
---|---|---|---|---|---|---|---|
Stoich. | Kass | Technique a | Preparation | Technique | |||
Aceclofenac | HPβ-CD | 1:1 | 222.11 | HPLC b | Kneading Coprecipitation | FTIR, DSC, PXRD | [235] |
Adamantane– Erythropoietin | mPEG β-CD | 1:1 | NP | 1H-NMR | Lyophilization | FTIR, DSC, TGA, PXRD, MALDI-TOF | [236] |
Berberine Coptisine Palmatine Epiberberine Dehydrocorydaline | SBE-β-CD | 1:1 1:1 1:1 1:1 1:1 | 19,200 ± 103 19,100 ± 1300 4700 ± 200 3000 ± 300 2500 ± 200 | Fluorescence b, UV/Vis, ITC | [237] | ||
Betulin 3,28- diphthalate Betulin 3,28- disuccinate Betulin 3,28-disulfate | HPβ-CD | 1:1 1:2 1:1 1:2 1:1 1:2 | 7.1 × 104 3.6 × 108 8.3 × 104 3.5 × 108 4.0 × 104 1.3 × 107 | ACE b | [238] | ||
Betulin 3,28- diphthalate Betulin 3,28- disuccinate Betulin 3,28-disulfate | DMβ-CD | 1:1 1:2 1:1 1:2 1:1 1:2 | 9.5 × 104 3.3 × 107 1.8 × 105 --- 9.3 × 104 1.7 × 108 | ACE b | [239] | ||
Betulin 3,28- diphthalate Betulin 3,28- disuccinate | HPγ-CD | 1:1 1:1 | 1.7 × 107 1.3 × 107 | ACE b | [240] | ||
Bifonazole Clotrimazole Miconazole Tioconazole | β-CD SBEβ-CD β-CD SBβ-CD β-CD SBEβ-CD β-CD SBEβ-CD | 1:1 1:1 1:1 1:1 1:1 1:1 1:1 1:1 | 2.5 × 103 5.2 × 104 4.5 × 102 2.9 × 103 5.0 × 102 1.5 × 103 1.5 × 103 9.3 × 103 | CD b, UV/Vis | [235] | ||
Bifonazole Miconazole | β-CD HPβ-CD β-CD HPβ-CD | 1:1 1:1 1:1 1:1 | 2767 2487 932 1012 | CE b | [241] | ||
Cefuroxime Axetil | β-CD β-CD-L-Arg | 1:1 1:1 | 339.74 ± 1.5 498.98 ± 2.7 | UV/Vis b | Spray drying | DSC, PXRD, SEM | [242] |
Celecoxib | SBEβ-CD | 1:1 | 8131 | UV/Vis b, HPLC, 1H-NMR, H-H ROESY | Freeze drying | [243] | |
Chysin | HPβ-CD | 1:1 | 1090 | UV/Vis b 1H-NMR | Kneading Coprecipitation | FTIR, TGA, SEM | [244] |
Curcumin | β-CD β-CD NS4 β-CD NS6 β-CD NS8 | 1:1 1:1 1:1 1:1 | 487.34 4972.90 4167.50 3567.87 | HPLC b | Freeze drying | FTIR, DSC, PXRD | [245] |
Diacerhein | HPβ-CD | 1:1 1:1 | 45 * 22 # | UV/Vis b,* HPLC b,# | Kneading Coevaporation Freeze drying | FTIR, DSC | [246] |
Eprosartan mesylate | β-CD | 1:1 | 280.78 | UV/Vis b 1H-NMR | Microwave irradiation | FTIR, DSC, PXRD, SEM | [247] |
Estradiol | β-CD HPβ-CD | 1:1 1:1 | 3.14 × 104 3.22 × 104 | Fluorescence b UV/Vis, CD | [248] | ||
Erlotinib | α-CD β-CD γ-CD HPβ-CD RAMEB CMβ-CD SBβ-CD | 1:1 1:1 1:1 1:1 1:1 1:1 1:1 | 142 ± 9 * 268 ± 11 * 324 # 54 ± 4 * 235 ± 10 * 434 ± 13 * 1396 ± 66 * 2380 ± 62 * | ACE b,*, LC-MS b,#, 1H NMR, H-H ROESY, UV, ESI-MS | Co-evaporation, kneading, vacuum desiccation, coprecipitation | XRD | [249] |
Etodolac | HPβ-CD HPβ-CD-L-Arg | 1:1 1:1 | 162.11 ± 6.24 2573.31 ± 11.31 | UV/Vis b, 1H NMR | Coevaporation Spray drying | FTIR, DSC, PXRD | [250] |
Flurbiprofen | β-CD | 1:1 | 2483.8 | 1H NMR *, H-H ROESY | [251] | ||
Folic Acid | β-CD | 1:1 1:2 | 944 ± 79 * 159 ± 26 # | TDA-CE * ACE# | [252] | ||
Genistein | Ab-CD1 Aβ-CD2 Aβ-CD3 Aβ-CD4 | 1:1 1:1 1:1 1:1 | 31,300 15,692 35,386 20,745 | UV/Vis b, 1H-NMR, H-H ROESY | Lyophilization | FTIR, PXRD, SEM | [79] |
Genistein Daidzein | SBEβ-CD | 1:1 1:1 | 34,926 ± 4500 13,131 ± 980 | UV/Vis b | Kneading | ATR-FTIR | [253] |
Gemfibrozil | β-CD HPβ-CD Meβ-CD | 1:1 1:1 1:1 1:2 | 760 ± 30 * 530 ± 20 * 440 ± 20 * | Fluorescence b,* 1H NMR b, UV b | Co-evaporation, kneading, vacuum desiccation, coprecipitation | [254] | |
Ginsenoside Re | α-CD β-CD γ-CD | 1:1 1:1 1:1 | 22 612 1.4 × 104 | HPLC b | Lyophilization | FTIR, DSC, PXRD | [80] |
Guanosine | β-CD | 1:1 1:1 | 59.79 * 151.97# | UV/Vis b,* Fluorescence b.# 1H-NMR, 13C-NMR | Coprecipitation | FTIR, DSC, TGA, PXRD, FESEM | [255] |
Guanosine | β-CD HPβ-CD SBEβ-CD | 1:1 1:1 1:1 | 87.53 *, 70.79 # 91.61 *, 98.97 # 103.29 *, 190.76 # | UV/Vis b,* Fluorescence b,# | Coprecipitation | FTIR, DSC, TGA, PXRD, FESEM | [256] |
Harmane Harmine | β-CD DMβ-CD TMβ-CD HPβ-CD β-CD DMβ-CD TMβ-CD HPβ-CD | 1:1 + 1:2 1:1 + 1:2 | 345 ± 42 207 ± 50 121 ± 29 602 ± 46 201 ± 14 148 ± 27 195 ± 14 353 ± 46 | Fluorescence b UV/Vis | 14 | ||
Hinokitiol | α-CD β-CD | 1:2 1:1 | 175 187 | UV/Vis b, H-H ROESY | Grinding | FTIR, DSC, PXRD, Fluorescence | [257] |
Inosine | β-CD | 1:1 1:1 | 33.59 * 104.53 # | UV/Vis b,* Fluorescence b,# | Kneading Coevaporation | FTIR, DSC; XRD, SEM | [258] |
(R)-Ketoprofen (S)-Ketoprofen | β-CD | 1:1 1:1 | 2750 *, 4088 # 1299 *, 2547 # | UV/Vis b,* Fluorescence b,# | Coevaporation | RAMAN | [259] |
Myrtenol | β-CD | 1:1 | -- | 1H-NMR, H-H ROESY | Kneading Slurry | DSC, TGA, PXRD, SEM | [200] |
Nifedipine | β-CD β-CD:Asp | 1:1 1:1 | 99 ± 2 117 ± 4 | HPLC b, 1H-NMR | Kneading | FTIR, DCS, TGA, PXRD, SEM | [86] |
Nifurtimox | β-CD SBEβ-CD | 1:1 1:1 | 236.79 359.57 | UV/Vis b, 1H-NMR, 13C-NMR | Coevaporation | FTIR, DSC, TGA, PXRD, SEM | [260] |
Olanzapine | β-CD DMβ-CD | 1:1 1:1 | 100 ± 3 278 ± 5 | UV/Vis b, 1H-NMR | Kneading | FTIR | [261] |
4-Phenylbutyrate | α-CD β-CD γ-CD | 1:1 1:1 2:1 | 481 ± 26 178 ± 23 119 ± 9 | HPLC b, CD, 1H-NMR, H-H COSY, H-H ROESY | [262] | ||
PNU 2FPNU 2MPNU 2MOPNU | β-CD | 1:1 1:1 1:1 1:1 | 1316 600 2200 5071 | Fluorescence b | [263] | ||
20S-Protopanaxatriol | EDBA-bis-β-CD | 1:1 | 995.94 ± 0.07 | UV/Vis b, 1H NMR, H-H ROESY | Coprecipitation | FTIR, PXRD, SEM | [264] |
6-Propyl-2-thiouracil | α-CD | 1:1 | 3297.57 ± 0.15 | UV/Vis b, 1H-NMR | Coevaporation | FTIR, DSC, TGA, PXRD, SEM | [265] |
Sulfabenzamide | β-CD Mβ-CD | 1:1 1:1 | 2.4 × 105 2.2 × 104 | UV/Vis b, 1H-NMR | Lyophilization | FTIR, PXRD, SEM | [266] |
Sulfisoxazole Sulfamethizole Sulfamethazine | β-CD | 1:1 1:1 1:1 | 650 1532 714 | UV/Vis b 1H-NMR | Coevaporation | DSC | [267] |
Temoporfin | β-CD NS cmβ-CD NS | 1:1 1:1 | 6.3 × 106 1.2 × 106 | Fluorescence b | [268] | ||
Tenofovir | β-CD | 1:1 | 863 ± 32 | UV/Vis b | Coprecipitation | FTIR, DSC, TGA, PXRD, SEM | [269] |
Trioxaadamantane Adamantoid scaffolds: G2 G3 G4 | β-CD | 1:1 1:1 1:1 1:1 | 969 ± 62 173 ± 11 2990 ± 65 4140 ± 193 | ITC b, 1H-NMR | Cocrystallization | PXRD | [270] |
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Sarabia-Vallejo, Á.; Caja, M.d.M.; Olives, A.I.; Martín, M.A.; Menéndez, J.C. Cyclodextrin Inclusion Complexes for Improved Drug Bioavailability and Activity: Synthetic and Analytical Aspects. Pharmaceutics 2023, 15, 2345. https://doi.org/10.3390/pharmaceutics15092345
Sarabia-Vallejo Á, Caja MdM, Olives AI, Martín MA, Menéndez JC. Cyclodextrin Inclusion Complexes for Improved Drug Bioavailability and Activity: Synthetic and Analytical Aspects. Pharmaceutics. 2023; 15(9):2345. https://doi.org/10.3390/pharmaceutics15092345
Chicago/Turabian StyleSarabia-Vallejo, Álvaro, María del Mar Caja, Ana I. Olives, M. Antonia Martín, and J. Carlos Menéndez. 2023. "Cyclodextrin Inclusion Complexes for Improved Drug Bioavailability and Activity: Synthetic and Analytical Aspects" Pharmaceutics 15, no. 9: 2345. https://doi.org/10.3390/pharmaceutics15092345
APA StyleSarabia-Vallejo, Á., Caja, M. d. M., Olives, A. I., Martín, M. A., & Menéndez, J. C. (2023). Cyclodextrin Inclusion Complexes for Improved Drug Bioavailability and Activity: Synthetic and Analytical Aspects. Pharmaceutics, 15(9), 2345. https://doi.org/10.3390/pharmaceutics15092345