Application of Molecular Dynamics Simulations in the Analysis of Cyclodextrin Complexes
Abstract
:1. Introduction
2. Molecular Modeling of CD Host–Guest Complexes—Theoretical and Practical Aspects
2.1. MD Simulations—A Perfect Choice to Study CD Complexes
2.2. Force Fields Dedicated to Cyclodextrins
2.3. MD Simulations of CD Complexes in Water Environment
2.4. Post-MD Simulation Analysis: GBSA, PBSA
2.5. Umbrella Sampling (US) and Steered (Biased) MD
2.6. Coarse-Grained MD
3. Application of the Molecular Dynamics Simulations for Systems Including Cyclodextrins—The Most Important and Interesting Cases
3.1. CDs Used as Drug Carriers (Water Environment)
N° | Reference | CD | Guest | Software Used for MD | Force Field | Equilibration Time and Conditions | Production Run Time and Conditions | Time Step | Water Model | Temperature (K) |
---|---|---|---|---|---|---|---|---|---|---|
I. CDs used as drug carriers (water environment) | ||||||||||
A. 2:1 host–guest CD complexes | ||||||||||
1 | [77] | β-CD | piroxicam | Materials Studio and Insight II/Discover packages | CVFF | no i.p. | 10 ns (1:1 host–guest), 100 ns (2:1 host–guest) | 1 fs | implicit | 300 |
2 | [78] | β-CD | posaconazole | GROMACS | GROMOS53A6 | no i.p. | 100 ns, NPT (p = 1 bar) | no i.p. | implicit; water and hydrogen peroxide | 298 |
3 | [79] | β- and HP-β-CD | sulfamethoxazole | Desmond | OPLS2005 | 1 ns | 15–20 ns, NPT (p = 1 bar) | no i.p. | TIP3P | 300 |
4 | [80] | β-CD | 17-α-methyltestosterone | AMBER 12 | Glycam06h, GAFF | 200 ps NVT, 200 ps NPT | 50 ns, NPT (p = 1 bar) | no i.p. | TIP3P | 298 |
5 | [81] | α-, β-, 2,6-DM-β-, and 2,3,6-TM-β-CD | citral isomers | AMBER 12 | Clycam06 (native CD), q4md-CD (CD-derivatives), GAFF (guest) | no i.p. | 12 ns | 1 fs | TIP3P | 300 |
6 | [82] | 2-HP-β- and 2-HP-γ-CD | imazapyr | Desmond | OPLS2005 | no i.p. | 30 ns, NPT (p = 1 atm) | TIP3P | 300 | |
B. NSAIDs* | ||||||||||
1 | [83] | HP-β-CD | etodolac and L-arginine | Desmond | OPLS2005 | no i.p. | 5 ns, NPT (p = 1.013 bar) | 2 fs | TIP4P | 300 |
2 | [84] | β- and HP-β-CD derivatives | flurbiprofen, ibuprofen, ketoprofen, and naproxen | GROMACS | ffgmx (derivative of GROMOS87) | no i.p. | 500 ps | no i.p. | no i.p. | 300 |
3 | [85] | β-CD | ketoprofen | GROMACS | GROMOS | 20 ps | 10 ns, 20 ns, NVT | 2 fs | no i.p. | 298 |
4 | [86] | α-, β-, γ-, HP-β-, M-β-, and SBE-β-CD | ketoprofen | AMBER 14 | GAFF | NVT, NPT | 100 ns, NPT (p = 1 bar) | 2 fs | TIP3P | 310 |
5 | [87] | SBE-β-CD | celecoxib | YASARA | AMBER ff14SB | no i.p. | 600 ns | 1.25 (intramolecular forces), 2.5 fs (intermolecular forces) | explicit | 298 |
6 | [88] | α-, β-, and γ-CD | etoricoxib | AMBER 11 | Glycam06h (CD), GAFF (guest) | 60 ps NVT, 1000 ps NPT | 20 ns, NPT (p = 1 bar) | TIP3P | 298 | |
7 | [89] | α-, β-, and γ-CD | nabumetone | AMBER 14 | GLYCAM-06j (CD), GAFF (guest) | 120 ps NVT, 2 ns NPT | 5 µs, NVT | 2 fs | TIP3P | 300 |
8 | [90] | β-CD | R- and S-ketoprofen | Desmond | OPLS2005 | 12 ps NVT (10 K), 12 ps NPT (10 K), 24 ps NPT (300 Km 1 atm), 24 ps (300 K, 1 atm) | 50 ns, NPT (p = 1.01325 bar) | no i.p. | TIP4P | 300 |
9 | [91] | α-, β-, and γ-CD | antipyrine | AMBER 12 | FF99SB | 50 ps NVT, 500 ps NPT | 10 ns, NPT (p = 1 bar) | no i.p. | TIP3P | 300 |
C. Anti-fungal drugs and antibiotics | ||||||||||
1 | [92] | 2,6-DM-β-CD | natamycin | GROMACS | GROMOS96 | no i.p. | 30 ns, NPT (p = 1 bar) | no i.p. | TIP3P | 300 |
2 | [93] | α-, β-, γ-, and 2-HP-β-CD | cefuroxime axetil | GROMACS | GROMOS 56A6 | 1 ns NPT | 500 ns NPT (p = 1 bar) | 2 fs | SPC | 298 |
3 | [94] | γ-CD | alamethicin | CHARMM | CHARMM36 | 5 ns NVT | 1000 ns, NPT (p = 1 atm) | no i.p. | TIP3P | 303 |
4 | [95] | α-, β-, and γ-CD | chloramphenicol | AMBER 14 | no i.p. | heating up to 300 K, 50 ps; NVT 500 ps | 10 ns, NPT (p = 1 bar) | no i.p. | TIP3P | 300 |
5 | [96] | β- and γ-CD | amphotericin B | NAMD | CSFF, CHARMM27 | no i.p. | 10 ns | 2 fs (short-range interactions), 4 fs (long-range interactions) | TIP3P | 300 |
D. Plant-derived substances | ||||||||||
1 | [97] | β-, 2-HP-β-, 6-HP-β-, 2,6-DHP-β-, 2,6-DM-β-, and RM-β-CD | 2-acetyl-1-pyrroline | AMBER 16 | Glycam06 (CD), GAFF2 (guest) | 500 ps (heating up) | 500 ns, NPT (p = 1 atm) | 2 fs | TIP3P | 298 |
2 | [98] | β- and γ-CD | polydatin | AMBER 14 | GAFF | 200 ps (heating up), 300 ps NVT | 55 ns, NPT (p = 1 bar) | 2 fs | TIP3P, 2545 ±29 water molecules | 300 |
3 | [99] | γ-CD | 3-hydroxyflavone | AMBER 16 | Glycam06 (CD), GAFF (guest) | 100 ps NVT | 300 ns, NPT (p = 1 atm) | no i.p. | TIP3P | 298 |
4 | [100] | β- and HP-β-CD | borneol | GROMACS | GROMOS54a7 | NVT, NPT (2 fs time step) | 100 ns, NPT | 1 fs | no i.p. | 300 |
5 | [101] | β-, 2,6-DM-β-, 2-HP-β-, 6-HP-β-, and 2,6-DHP-β-CD | eucalyptol | AMBER 14 | Glycam06-h (CD), GAFF (guest) | 100 ns, NVT | 70 ns NPT (p = 1 atm) | 2 fs | SPC, 2000 water molecules | 298 |
6 | [102] | β- and γ-CD | triterpene glycoside and glycyrrhizic acid | PRESTO | GAFF | 10,000 steps (heating up), 200,000 NVT | 0.8 ns | 1 fs | TIP3P | 300 |
7 | [103] | β-, 2,6-DM-β-, 2-HP-β-, 6-HP-β-, 2,6-DHP-β-, and RM-β-CD | luteolin and pinocembrin | AMBER 16 | Glycam-06 (CD), GAFF (guest) | 60 ps (heating up) | 100 ns, NPT (p = 1 atm) | 2 fs | TIP3P | 298 |
8 | [104] | β-, 2,6-DM-β-, and HP-β-CD | mansonone G | AMBER 16 | Glycam-06 (CD), GAFF (guest) | 60 ps (heating up) | 90 ns, NPT (p = 1 atm) | 2 fs | TIP3P | 303 |
9 | [105] | β-, 2,6-DM-β-, 2-HP-β-, 6-HP-β-, and 2,6-DHP-β-CD | pinostrobin | AMBER 12 | Glycam06 (CD), partial charges of guest: standard parametrization procedures | 100 ps (heating up) | 80 ns | 2 fs | explicit, 1400+- 42 water molecules | 298 |
10 | [64] | β-, 2,6-DM-β-, DM-β-, and randomly methylated β-CD | hesperetin and naringenin | AMBER 12 | Glycam06 (CD), partial charges of guest: standard parametrization procedures | 100 ps (heating up) | 80 ns, NPT (p = 1 atm) | 2 fs | SPC | 298 |
11 | [65] | β- and 2,6-DM-β-CD | naringenin | AMBER 12 | Glycam06 (CD), partial charges of guest: standard parametrization procedures | 100 ps | 80 ns, NPT | 2 fs | SPC, 1480 ± 10 and 1750 ± 3 water molecules | 298 |
12 | [106] | β-CD | daidzin | GROMACS | GROMOS96 | NPT | 12 ns, NPT (p = 1 atm) | 0.002 ps | explicit, 3100 water molecules | 300 |
13 | [107] | γ-CD | glycyrrhizin | CHARMM | added from cff | no i.p. | 1 ns | 1 fs | explicit, 2969 water molecules for β-CD and 5718 for γ-CD | 300 |
14 | [108] | β-CD | eriocitrin (flavanone) | AMBER 19 | Glycam06j (carbohydrates, 2-hydroxypropyl units), missing parameters and atom types: GAFF2 | 1 ns (heating and cooling: 0 K <-> 300 K); 5 ns, NPT | 200 ns, NVT | 2 ps | explicit, 8527–9303 water molecules | 300 |
15 | [109] | α-, β-, and γ-CD | cannabidiol | GROMACS | OPLS-AA | no i.p. | 250 ns, NPT (p = 1 bar) | 2 ps | no i.p. | 298, 310, 322, 334 |
16 | [110] | β- and γ-CD | rosmarinic acid | AMBER | q4md-CD (CD), GAFF (guest) | no i.p. | 50 ns, NPT | no i.p. | TIP3P | 300 |
17 | [111] | β-CD | harman (alkaloid) | GROMACS | GROMOS 54a7 | NVT, NPT, 100 ps | 50 ns, NPT (p = 1 bar) | 2 fs | SPC | 300 |
18 | [112] | β,- γ-, HP-β-, and DM-β-CD | myricetin | Desmond 2018.4 | OPLS3 | no i.p. | 30 ns, NPT (p = 1.013 bar) | no i.p. | TIP3P | 300 |
19 | [113] | HP-β-CD | capsaicin | AMBER 16 | GAFF | NVT 50 ps, NPT 50 ps | 5000 ps, NPT (p = 1 atm) | 2 fs | TIP3P | 300 |
20 | [58] | β- and γ-CD | pseudoginsenoside PF11 | YASARA | AMBER 14 | no i.p. | 100/150 ns, NPT (p = 1 bar) | no i.p. | COSMO | 298 |
21 | [114] | α- and β-CD | thymol | Desmond | OPLS 2005 | no i.p. | 48 ns | no i.p. | SPC | |
22 | [115] | α-, β-, and γ-CD | daidzein (isoflavone) | AMBER 12 | q4md-CD (CD), GAFF (guest) | no i.p. | 50 ns, NPT (p = 1 atm) | no i.p. | TIP3P | 300 |
23 | [116] | α-, β-, and γ-CD | cathinone | AMBER | GAFF | 200 ps NVT, 20000 ps NPT | 30 ns, NPT (p = 1 bar) | 2 fs | TIP3P | 298 |
24 | [117] | 2,6-DM-β- and 2,3,6-TM-β-CD | β-citronellol | AMBER | CLYCAM (β-CD), q4md-CD (methylated β-CD) | NVT, 250 ps NPT | 11 ns, NPT | no i.p. | explicit | 300 |
25 | [118] | β- and HP-β-CD | naringin | AMBER 14 | GAFF | no i.p. | 100 ps, NPT (p = 1 bar) | no i.p. | TIP3P | no i.p. |
26 | [119] | γ- and HP-γ-CD | naringin | Desmond | OPLS2005 | no i.p. | 100 ps, NPT (p = 1.0325 bar) | 2 fs | VSGB 2.0 (implicit) | 310 |
27 | [120] | 2-HP-β-CD | quercetin | AMBER 14 | GLYCAM_06j-1 (CD part of molecule), GAFF (2-HP groups of CD and guest) | no i.p. | 400 ns | no i.p. | TIP3P | 300 |
28 | [121] | HP-β-CD | silibinin | AMBER 12 | GLYCAM_06i-12SB (CD-part of molecule), GAFF (2-HP groups of CD) | 100 ps NVT, 100 ps NPT | 190 ns and 250 ns | no i.p. | TIP3P, 3841 water molecules | 300 |
29 | [122] | β-CD | cyanidin-3-O-glucoside | AMBER 10 | GLYCAM_04 (CD), GAFF (guest) | 100 ps NPT | 30 ns, NPT | 2 fs | TIP3P | 303.15 |
30 | [123] | β-CD | resveratrol | AMBER 11 | GLYCAM_06 (CD), GAFF (guest) | 100 ps NVT | 20 ns, NPT (p = 1 atm) | 2 fs | no i.p. | 300 |
31,32 | [124,125] | β-, 2,6-DM-β-, and 2-HP-β-CD | α-mangostin | AMBER (PMEMD module) | Glycam06j (CD) | 10 ns NVT | 100 ns, NPT (p = 1 atm) | 2 fs | TIP3P | 298 |
E. Others | ||||||||||
1 | [126] | 3-mono-amino-β-LHRH (luteinizing hormone releasing hormone) conjugate | MacroModel (implicit water model), Desmond (explicit water model) | OPLS2005 | 1 ns for implicit water model | 20 ns for implicit water model; 40 ns, NPT (p = 1.01325 bar) for explicit water model | 2 fs (explicit water model) | implicit and explicit (SPC, 2618 water molecules) | 298.1 | |
2 | [127] | HP-β-CD | efavirenz and L-arginine | Desmond | OPLS2005 | no i.p. | 5 ns, NPT (p = 1.013 bar) | TIP4P | 300 | |
3 | [128] | β- and M-β-CD | omeprazole and L-arginine | GROMACS | ffgmx | 3 ns | 15 ns (L-arginine: drug, 1:1), 6 ns (other L-arginine-drug ratio), NPT | 1.5 fs | explicit, more than 1000 water molecules | 300 |
4 | [129] | β- and γ-CD | pyrazoline dye | MOPAC2012 | Amber99 | 50 ps NVT, 2000 ps NPT | 2000 ps | 2 fs | TIP3P | 298 |
5 | [130] | β-CD | cyanine dye | SYBYL-X | Tripos | 500 fs per each 20 K gain; then 25 ps NVT | 2 ns | 2 fs | Molecular Silverware algorithm | 300 |
6 | [131] | β-CD | carbazole-based dyes | Chem3D Pro | MM2 | no i.p. | no i.p. | 2 fs | no i.p. | no i.p. |
7 | [132] | α-, β-, γ-, and 6-HP-β-CD | lutein | AMBER 14 | GAFF | 10000 steps (heating up) | 100 ns, NPT (p = 1 bar) | 2 fs | TIP3P | 310 |
8 | [133] | β-CD | maltogenic amylase | GROMACS | GROMOS96 | 50 ns | 10 ns | 2 fs | SPC | 343 |
9 | [134] | sulfated β- and M-β-CD | levosulpiride | AMBER 9 | GAFF | 10 ps (heating up) | 3 ns | 2 fs | 300 | |
10 | [135] | HP-β- and 2,6-DM-β-CD | bisacodyl | Forcite | COMPASS | 50 ps, 298 K, NVT | 40 ps | 1 fs | explicit, 20 water molecules | 500 → 300 |
11 | [136] | α-, β-, γ-, and differently substituted β- and γ-CD | chlorpromazine | Amber 16 | q4md-CD (CD), GAFF (guest) | heating up by 25 ps periods, 200 ps relaxation | 50 ns, NPT (p = 1 atm) | 2 fs | TIP3P | 300 |
12 | [137] | α- and β-CD | ambroxol hydrochloride | MOE | MMFF94x. | 100 ps | 500 ps | no i.p. | no i.p. | 300 |
13 | [45] | β- and 2-HP-β-CD | sertraline | Tinker code v8.4 | MM3 | no i.p. | no i.p. | no i.p. | COSMO | 298 |
14 | [138] | γ-, HP-γ-, and HP17-γ-CD | lopinavir | GROMACS | GROMOS-96 54a7 | NVT (1 ns, 300 K), NPT (2 ps, 300 K, 1 bar) | 100 ns, NPT (p = 1 bar) | no i.p. | SPC | 300 |
15 | [113] | β-, γ-, HP-β-, and M-β-CD | glipizide | AMBER 14 | GAFF | no i.p. | 70 ns | 2 fs | TIP3P | 310.15 |
16 | [139] | β-CD | metyrapone | YASARA | AMBER14 | no i.p. | 136 ns, NPT (p = 1 bar) | no i.p. | explicit | 298 |
17 | [140] | β-CD | calixarene sulfonates with 4-aminoazobenzene | LAMMPS | AMBER | 1 ns | 20 ns, NPT (p = 1 bar) | 2 fs | TIP4P2005, 2000 water molecules | 300 |
18 | [141] | 2,3,6-TM-β-CD | temoporfin | AMBER 14 | q4md-CD (CD), GAFF (guest) | 500 ps, NPT | 10 ns, NPT (p = 1 atm) | 1 fs | TIP3P | 300 |
19 | [142] | β-CD | theophylline | GROMACS | amber99sbildn | 0.1 ns NVT, 1 ns NPT | 50 ns | no i.p. | TIP3P, 1353 water molecules | 300 |
20 | [143] | 2,6-DM-β- and 2,3,6-TM-β-CD | α-naphthaleneacetic acid | AMBER 12 | q4md-CD (CD), GAFF (guest) | 250 ps NPT | 11 ns, NPT | no i.p. | TIP3P | 300 |
21 | [144] | β-, γ-, and randomly sulfated β- and 6-S-β-CD | medetomidine | AMBER | parm10 and ff14SB | 120 ns | 100 ns, NPT (p = 1 atm) | 2 fs | explicit | 300 |
22 | [145] | β-, DM-β-, TM-β-, and randomly methylated β-CD | glycocholate | AMBER 12 | GAFF, q4md-CD (CD-derivatives) | 400 ps (heating up) | 2 ns, NPT (p = 1 atm) | 2 fs | TIP3P | 300 |
23 | [146] | β- and 2,3-di-O-acetyl-β-CD | clenpenterol | no i.p. | Amber | 40 ns | 100 ns | no i.p. | explicit | no i.p. |
24 | [147] | β-CD | norepinephrine | Desmond | OPLS2005 | no i.p. | 15 ns, NPT (p = 1bar) | no i.p. | TIP3P | 300 |
25 | [67] | RM-β- and HP-β-CD | triamcinolone | GROMACS | GROMOS 54a7 | NVT 5 ns, NPT 5 ns | 200 ns | no i.p. | TIP3P | 298 |
26 | [148] | HP-β-CD | 1-indanone thiosemicarbazones | GROMACS | GROMOS96 53a6 | no i.p. | 100 ns | 1 fs | SPC | 300 |
27 | [149] | α-, β-, γ-, and 2-HP-β-CD | fentanyl | AMBER | literature source (CD), GAFF (guest) | 200 ns (heating up), 2.5 ns (equilibrium) | 10 ns or 30 ns (depending on guest) | 2 fs | TIP3P | 300 |
28 | [150] | HP-β-CD | clonidine | GROMACS | GROMOS-96 53a6 | no i.p. | 100 ns | 1 fs | SPC | 300 |
29 | [151] | sulfobutylether-β-, sulfated β-, and monochlorotriazinyl-β-CD | propiconazole nitrate | GROMACS | q4-MD (CD), GAFF (guest) | no i.p. | 50 ns, NPT (p = 1 atm) | no i.p. | TIP3P | 293,15 |
30 | [152] | β-CD | mammea A/AA | AMBER 12 | ff99SB | no i.p. | 10 ns, NPT (p = 1 atm) | 2 fs | TIP3P, 1452 water molecules | 300 |
31 | [153] | HP-β-CD | carbamazepine | NAMD | CHARMM | 5 ps heating up, 50 ps equilibration | 2 ns | 1 fs for covalent, 2 fs for vdW, 4 fs for electrostatic atom interactions | no i.p. | 300 |
32 | [154] | β-CD | methotrexate | AMBER 12 | GLYCAM_06 (CD), GAFF (guest) | 1 ns | 10 ns, NPT | 2 fs | TIP3P | 298 |
33 | [155] | α-, β-, and γ-CD | cumene hydroperoxide | GROMACS | GROMOS96 | no i.p. | 16 ns | no i.p. | 298 | |
34 | [156] | β-CD | N-methyl carbamates | AMBER 7 | GAFF | no i.p. | 3 ns, NPT (p = 1 atm) | 2 fs | TIP3P, 9000 water molecules | 300 |
35 | [157] | β- and randomly methylated β-CD | isosorbide diesters | AMBER 10 | GAFF | no i.p. | 10 ns, NPT (p = 1 bar) | 2 fs | TIP3P | 300 |
36 | [158] | β-CD | adamantane derivatives | NAMD | CHARMM (β-CD), CGenFF program (bond, angle and dihedral parameters of guest) and CHARMM GFF (atomic charges of guest) | 10 ns | 20 ns | 2 fs | TIP3P | no i.p. |
37 | [159] | amino-β-CD (protonated and non-protonated) | doxorubicin | NAMD | CHARMM FF | no i.p. | 30 ns, NPT (p = 1 atm) | 0.5 fs | TIP3P | 298.15 |
38 | [160] | β-CD | caffeine | GROMACS | GROMOS 56A | no i.p. | 4000 ps | 1 fs | explicit, 1000 water molecules | 333.15 |
39 | [161] | β-CD | zwitterionic phenylalanine | PINY-MD code | GROMOS | NVT; NPT (p = 0 bar) 500 ps | 30 ns, NVT | 4 fs | explicit, 2903 water molecules | 300 |
F. Umbrella sampling and steered (biased) molecular dynamics | ||||||||||
1 | [162] | β-CD | trimethylammonium adamantane salt | AMBER 16 | Glycam06 (CD), GAFF2 (guest) | unbiased MD: 100 ps (1 fs time step, heating up); 500 ps NVT density equilibration; NPT | NPT (p = 100 kPa); SMD | 1 μs (unbiased MD), 4.4 μs (biased MD) | TIP3P | 300 |
2 | [163] | β-CD | adamantane-doxorubicin | GROMACS | AMBER99SB-ILDN | NVT 2 ns, NPT 2 ns | 100 ns, NPT (p = 1 bar); umbrella sampling: 10 ns | no i.p. | TIP3P, 15,000 water molecules (for 6 drugs in one water box) | 310 |
3 | [164] | α-, β-, and γ-CD | adamantane-terminated gold nanoclusters | NAMD | potential model based on CHARMM (CD, guest), GolP (interactions with gold atoms) | no. i.p. | 10 ns, NPT (p = 1 atm); SMD; umbrella sampling for each window: 500 ps | 2 fs | SPC | 300 |
4 | [165] | 2-HP-β-CD | cilexetil | GROMACS | MMFF (guest), CHARMM (water) | NVT, NPT | umbrella sampling for each window: 500 ps | 2 fs | no i.p. | 310 |
5 | [66] | β-CD | chalcone and 2′,4′-dihydroxychalcone | GROMACS | GROMOS 53a6 | 10 ns for each window | 100 ns for each window, total time: 4290 ns | 2 ps | SPC water model, 1200 water molecules | 310 |
6 | [63] | β-CD | genistein | AMBER, umbrella sampling: GROMACS; DFTB-MD | Glycam06 (CD), partial atomic charges of guest: standard parameterization procedures | 2 ns (SMD) | unbiased MD: 100 ns, NPT (p = 1 atm); SMD: 8 ns; DFTB+: 1000 ps | 2 fs, DFTB+: 1 fs | SPC, 1400 water molecules | 298, DFTB+: 400 |
7 | [166] | β-, 2,6-DM-β-, and 2-HP-β-CD | pinostrobin | GROMACS | Glycam06 (CD), GAFF (guest) | no i.p. | 1 ns, NPT | no i.p. | SPC, 3200 water molecules | 289 |
8 | [167] | β-CD | cinnamaldehyde and eugenol | NAMD 2.6 | Charmm33b | 50 ps heating up | 1.2 ns | no i.p. | no i.p. | 298 |
9 | [168] | α-, β-, and γ-CD | umbelliferone | GROMACS | q4md (CD), GAFF (solvents, guest) | 2 ns | NPT (p = 1 bar); total time: 400 ns; 10 ns for each window | no i.p. | water (TIP3P model, 2:1 complex); other solvents (2:2 complex): methanol, ethanol, dimethyl sulfoxide, N,N-dimethylacetamide, N,N-dimethylformamide, acetone, tetrahydrofuran, acetonitrile, chloroform | 300 |
10 | [69] | β-CD | 1-butanol and aspirin | AMBER 14 | no i.p. | umbrella sampling: 1 ns NVT; heating up at 200 K, 250 K, 298 K for 150 ps | 100 ns: conventional MD; 10 ns: SMD (NPT, p = 1 bar); 2.5 ns: umbrella sampling | no i.p. | TIP3P | 300 (SMD), 298 (umbrella sampling) |
II. CDs used as extracting agents (different solvents) | ||||||||||
1 | [169] | β-CD | 2,3,7,8-tetrachlorodibenzo-p-dioxin | GROMACS | GROMOS96 | no i.p. | overall 12 ns (equilibrium + run), NPT (p = 1 bar) | 0.001 ps | SPC, 2500 water molecules | 298 |
2 | [170] | α-, β-, and γ-CD | 2,2′,5,5′-tetrachlorobiphenyl | Discover Model of Materials Studio | COMPASS | no i.p. | NPT (p = 1 atm) | 0.5 fs | COSMO, 800 water molecules | 298 |
3 | [171] | α-, β-, and γ-CD | DDT | NAMD | CHARMM27 | no i.p. | NPT (p = 1 atm) | 2 fs | TIP3P | 298 |
4 | [172] | quaternary ammonium β-CD | ochratoxin A | HyperChem | Amber | no i.p. | a few hundreds of ps time | TIP3P | 298 | |
5 | [173] | β-CD | PCB126 | GROMACS | GROMOS96 | no i.p. | 15 ns, NPT (p = 1 bar) | 1 fs | SPC, 2500 water molecules | 300 |
6 | [174] | β-CD | ibuprofen (racemic mixture) | GROMACS | GROMOS54a7 | 1 ns NVT, 10 ns NPT (P = 1 bar) | 100 ns, NVT | 1 fs | methanol, 2000 molecules | 260–380 |
7 | [76] | β-CD | ibuprofen (racemic mixture) | GROMACS | GROMOS54a7 | 1000 ps NPT (P = 1 bar), 500 ps NVT | 10 ns | 1 fs | methanol, 2000 molecules | 273.15 |
8 | [175] | HP-β-CD | (E)-piceatannol | GROMACS | GROMOS53A6 | no i.p. | 2 ns, NPT (p = 1 atm) | 2 fs | SPC/E (water), methanol + water, ethanol + water, n-propanol + water, glycerol + water cosolvents | 298.2 |
9 | [176] | β-, 2,6-DM-β-, and 2-HP-β-CD | UC781 | AMBER 10 | Amber parm03 | 400 ps NVT, 11 ns NPT | 10 ns, NPT (p = 1 atm) | 2 fs | 308 water molecules (TIP3P), 1670 ethanol molecules | 300 |
10 | [177] | γ-CD | gold nanoparticles | GROMACS | CHARMM36 | 100 ps; NPT 100 ps | 200 ns, 250 ns (depending on the number of CD molecules), NPT (p = 1 bar) | 2 fs | explicit, 10,500–12,620 water molecules | 298.15 |
11 | [178] | β- and 2,3-di-O-acetyl-β-CD | terbutaline enantiomers | AMBER 12 | q4md-CD and Glycam04 and Amber99SB (CD), GAFF (guest molecules with one positive charge) | 400 ps NVT | 6 ns, NPT (p = 1 atm) | 2 fs | TIP3P | 300 |
12 | [179] | γ-CD | regioisomers of bis-N-methylfulleropyrrolidines | NAMD | CHARMM | 20 ns | 60 ns, NPT (p = 1 bar) | 2 fs | DMSO, water (TIP3P) | 298 |
13 | [180] | permethylated β-CD | phenylazetidin derivatives | GROMACS | GROMOS | no i.p. | 4 ns, NPT (p = 1 bar) | no i.p. | no i.p. | 300 |
14 | [181] | β-CD | isoleucine enantiomers | no i.p. | AMBER ff99SB | no i.p. | 5 ns | 1 fs | 2021 | 293 |
15 | [182] | β-CD | terminally blocked phenylalanine dipeptide (Ace-Phe-Nme), | AMBER 9 | Amber 03 | no i.p. | 8 ns, NPT (p = 1 atm) | no i.p. | TIP3P | 300 |
3.2. Host–Guest Stoichiometry of CD Complexes
3.3. NSAIDs
3.4. Anti-Fungal Drugs and Antibiotics
3.5. Plant-Derived Substances
3.6. Others
3.7. Umbrella Sampling and SMD Used for CD Simulations
3.8. CDs Used as Extracting Agents (Different Solvents)
4. Conclusions
Author Contributions
Funding
Conflicts of Interest
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N° | Software/Code | Force Field | License | Ref. |
---|---|---|---|---|
1 | GROMACS | GROMOS CHARMM Carbohydrate Solution force field, CSFF (for CD) | General Public License (GPL) | [32] |
2 | AMBER | GAFF, Glycam06 (for CD), q4md-CD (for CD) | Commercial | [33] |
3 | CHARMM | CHARMM FF | Commercial | [34] |
4 | Desmond (Schrödinger, Inc.) | OPLS | Commercial | [35] |
5 | NAMD | CHARMM | Commercial, academic | [36] |
6 | Forcite (BIOVIA Materials Studio, Accelrys) | COMPASS | Commercial | [37] |
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Mazurek, A.H.; Szeleszczuk, Ł.; Gubica, T. Application of Molecular Dynamics Simulations in the Analysis of Cyclodextrin Complexes. Int. J. Mol. Sci. 2021, 22, 9422. https://doi.org/10.3390/ijms22179422
Mazurek AH, Szeleszczuk Ł, Gubica T. Application of Molecular Dynamics Simulations in the Analysis of Cyclodextrin Complexes. International Journal of Molecular Sciences. 2021; 22(17):9422. https://doi.org/10.3390/ijms22179422
Chicago/Turabian StyleMazurek, Anna Helena, Łukasz Szeleszczuk, and Tomasz Gubica. 2021. "Application of Molecular Dynamics Simulations in the Analysis of Cyclodextrin Complexes" International Journal of Molecular Sciences 22, no. 17: 9422. https://doi.org/10.3390/ijms22179422
APA StyleMazurek, A. H., Szeleszczuk, Ł., & Gubica, T. (2021). Application of Molecular Dynamics Simulations in the Analysis of Cyclodextrin Complexes. International Journal of Molecular Sciences, 22(17), 9422. https://doi.org/10.3390/ijms22179422