Influence of API physico-chemical properties on amorphization capacity of several mesoporous silica loading methods.

The objective of this work was to evaluate the impact of physico-chemical properties of pharmaceutical drugs on the optimal mesoporous silica loading methods. Indeed, a good combination between drug and loading process has to be studied to promote the deepest penetration of the drug inside the mesopores, allowing high drug amorphization. Six molecules, namely lidocaine and its hydrochloride, ibuprofen, ketoprofen, artemether and miconazole, with different physico-chemical properties (the ionized character, the acid-base character, the HBDA number, the solubility in sc-CO2 and the behavior under subcritical CO2) were used to produce drug-silica formulations. Different impregnation processes (physical mixing, melting, wetting, sc-CO2 and subcritical CO2 impregnations) have been compared for each drug, in terms of drug recovery and crystallinity. Formulations showed drug percentage close to 100% except for supercritical soluble drug formulations impregnated by using sc-CO2. However, the basic drug character provided less or no drug loss during impregnation. Processing insoluble sc-CO2 molecule under supercritical conditions led to less crystallinity than the correspondent physical mixture suggesting an interesting repulsive effect that forces the drug penetration within the mesopores. Besides, it has been also highlighted that the HBDA number is not sufficient to predict the final drug loading. Melting methods have high interest considering the drugs tested and subcritical CO2 could increase the loading, especially for drugs with high molten viscosity. This study showed that a plethora of loading methods can be used to provide high drug loaded MS formulations with a wide choice of equipment.

Rǒle des electrons π des fonctions amide et ester dans les peptides et depsipeptides.

The IR data for the R1 CO-O-CHR2 -CO-NHR3 derivatives are interpreted in terms of a H…π interaction involving the NH bond and the π orbitals of the ester function and giving rise to a high ν(CO) frequency and a low ν frequency. The resulting molecular conformation corresponds to the angular values ϕ # -90°, ψ # 0°. The H…π interaction in MeCO-L-Lac-NHMe is highly destabilized by water and aprotic solvents but is retained in methanol. Considering the high ν(CO) ester or amide frequency of the middle function in ß-folded depsipeptide or peptide sequences, it may be supposed that the residue indexed i + 2 in ß turns experiences a H…π interaction which has a stabilizing effect on ß turns. Some examples concerning valinomycin and some model compounds are discussed.

Structural variations in the crystal structures of two homologous DL-Leu and delta-Leu containing peptides.

The similar conformations and interaction modes of Ac-DL-Leu-NMe2 and Ac-delta-Leu-NMe2 molecules in the solid state allow the comparison of their geometrical parameters. The most evident variations are essentially restricted to the alpha, beta-unsaturated side-chain which adopts the Z-disposition. The dimensions of the peptide backbone are much less sensitive to alpha, beta-unsaturation, with a small shortening by 0.04 A and 0.02 A of the N--C alpha and C alpha--C' bonds, respectively, and an increase by 6 degrees of the N--C alpha--C' bond angle. The ethylenic and amide groups in the delta-Leu derivative are far from coplanarity, and a significant electronic conjugation of the pi-orbital is likely to be rejected.

Structural features of the Pip/AzPip couple in the crystalline state: influence of the relative AzPip location in an azadipeptide sequence upon the induced chirality and conformational characteristics.

Azapipecolic (AzPip) is a pipecolic (Pip) residue analogue containing a nitrogen atom in place of the C(alpha)H group. AzPip was introduced into two reverse dipeptide sequences, Piv-AzPip-L-Ala-NHiPr I and Boc-L-Ala-AzPip-NHiPr II in order to evaluate, in the crystalline state, the influence of the L-Ala-induced chirality upon the prochiral AzPip residue, and therefore the resulting conformational characteristics, according to the relative position of the AzPip residue. Piv-DL-Pip-NHMe III served as a control derivative for comparison between the properties of the two different heterocycles of Pip and AzPip residues. Piperidine and hexahydropyridazine rings have a few characteristics in common: chair conformation, axial disposition of the C-terminal backbone substituent and the cisoid form of the N-terminal tertiary amide function. An almost pure sp3 hybridization state is observed for the substituted nitrogen atom N(alpha), so that L-Ala induces an AzPip (R) or (S) chirality when it follows or precedes, respectively, the azaresidue in such a pseudodipeptide sequence. If both I and II compounds present a short NH...N contact between the sp2 tertiary amide nitrogen atom and the NH of the next secondary amide function, whatever the chiral nature of the sequence, the heterochiral azadipeptide I adopts a rather totally extended conformation while the homochiral azadipeptide II is folded by a beta-VI turn-like structure stabilized by a classical 4-->1 intramolecular hydrogen bond.

N-Methyl peptides. IV. Water and beta-turn in peptides. Crystal structure of N-pivaloyl-L-prolyl-N,N'-dimethyl-D-alaninamide in the anhydrous and monohydrated states.

The model tripeptide tBuCO-L-Pro-Me-D-Ala-MHMe crystallizes in both anhydrous (1) and monohydrated (2) states: 1, monoclinic space group C2 with a = 20.030 (2) A, b = 5.836 (2) A, c = 14.958 (3) A and beta = 94.11 (1) degrees; 2, orthorhombic space group P212121 with a = 6.971 (6) A, b = 11.766 (3) A, and c = 22.394 (8) A. Both crystal structures were solved by X-ray diffraction in order to characterize the influence of water on the molecular structure. The anhydrous molecule accommodates the well-known, beta II-folded conformation with three trans amide functions and an intramolecular i + 3 leads to hydrogen bond. In the hydrated molecule, water is inserted in a loop containing 12 atoms and induces some conformational changes of the peptide backbone.

Synthesis, crystal structure and molecular conformation of the tBuCO-D,L-Ala-delta Z-Phe-NHiPr alpha,beta-unsaturated dipeptide.

The crystal structure of the tBuCO-D,L-Ala-delta Z-Phe-NHiPr dipeptide has been solved by X-ray diffraction. The peptide crystallizes in monoclinic space group P2(1)/c with a = 13.445 (3) A, b = 35.088 (4) A, c = 14.755 (3) A, beta = 116.73 (1) degree, Z = 12 and dc = 1.151 g.cm-3. The three independent molecules per asymmetric unit accommodate a beta II-folded conformation, but only one of them contains the typical i + 3----i interaction characterizing a beta-turn. In the other two molecules, the N...O distance exceeds 3.2 A, a value generally considered the upper limit for hydrogen bonds in peptides. In solution, the beta II-turn conformation is largely predominant.

Conformational investigation of alpha,beta-dehydropeptides. VII. Conformation of Ac-Pro-deltaAla-NHCH3 and Ac-Pro-(E)-deltaAbu-NHCH3: comparison with (Z)-substituted alpha,beta-dehydropeptides.

The crystal structure and solution conformation of Ac-Pro-deltaAla-NHCH3 and the solution conformation of Ac-Pro-(E)-deltaAbu-NHCH3 were investigated by X-ray diffraction method and NMR, FTIR and CD spectroscopies. Ac-Pro-deltaAla-NHCH3 adopts an extended-coil conformation in the crystalline state, with all-trans peptide bonds and the deltaAla residue being in a C5 form, phi(1)=-71.4(4), psi(1)=-16.8(4), phi(2)= -178.4(3) and psi(2)= 172.4(3) degrees. In inert solvents the peptide also assumes the C5 conformation, but a gamma-turn on the Pro residue cannot be ruled out. In these solvents Ac-Pro-(E)-deltaAbu-NHCH3 accommodates a beta(II)-turn, but a minor conformer with a nearly planar disposition of the CO-NH and C=C bonds (phi(2) approximately 0 degrees) is also present. Previous spectroscopic studies of the (Z)-substituted dehydropeptides Ac-Pro-(Z)-deltaAbu-NHCH3 and Ac-Pro-deltaVal-NHCH3 reveal that both peptides prefer a beta(II)-turn in solution. Comparison of conformations in the family of four Ac-Pro-deltaXaa-NHCH3 peptides let us formulate the following order of their tendency to adopt a beta-turn in solution: (Z)-deltaAbu > (E)-deltaAbu > deltaVal; deltaAla does not. None of the folded structures formed by the four compounds is stable in strongly solvating media.

Aza-peptides. II. X-ray structures of aza-alanine and aza-asparagine-containing peptides.

In order to determine the structural consequences of the N alpha/C alpha H exchange in aza-peptides, we have solved the crystal molecular structures of some derivatives containing the aza-analogue of asparagine [Z-AzAsn(Me)-NMe2 (1), Z-AzAsn(Me)-Pro-NHiPr (2) and Piv-Pro-AzAsn(Me)-NHiPr (5)], aspartic acid [Z-AzAsp(OEt)-Pro-NHiPr (3) and alanine (Boc-AzAla-Pro-NHiPr (4)], by using X-ray diffraction. They reveal that the alpha-nitrogen accommodates a pyramidal (1-4) or planar (5) structure depending on the sequence. When pyramidal, the alpha-nitrogen assumes the R (D-like) chirality. All of the derivatives but 1 adopt either a beta 1-folded (2-4) or beta n-folded (5) structure in which the (AzAsn)N3H bond is intramolecularly hydrogen-bonded to the alpha-nitrogen.

Triphosgene: an efficient carbonylating agent for liquid and solid-phase aza-peptide synthesis. Application to the synthesis of two aza-analogues of the AChR MIR decapeptide.

The N alpha/C alphaH exchange in aza-peptides has the advantage of preserving the side chain. Bis(trichloromethyl)carbonate or triphosgene is a solid, stable phosgene substitute which retains its high reactivity. Temperature and coupling times are greatly reduced with reference to other usually recommended carbonylating agents, while purity and yield are increased. It has been used, in both liquid- and solid-phase procedures, for the synthesis of various aza-analogues of dipeptides, tripeptides and decapeptides containing the alanine, aspartic acid and asparagine aza-residue.

N-methyl peptides. III. Solution conformational study and crystal structure of N-pivaloyl-L-prolyl-N-methyl-N'-isopropyl-L-alaninamide.

The study of tBuCO-L-Pro-Me-L-Ala-NHiPr (1) by i.r. and n.m.r spectroscopies has indicated that the middle amide group accommodates preferentially the cis arrangement in inert (CCl4) and aprotic (DMSO) solvents. Cis conformers are folded by a strong intramolecular hydrogen bond involving both terminal CO and NH groups whereas the minor trans conformers accommodate an open conformation. The cis folded form is retained in the solid state and its crystal structure was fully characterized by X-ray diffraction.

Azaproline as a beta-turn-inducer residue opposed to proline.

Azaproline (AzPro) is an analogue of proline containing a nitrogen atom in place of the C(alpha)H group. AzPro has been introduced in various model peptides, and especially in the Boc-Ala-AzPro-Ala-NHiPr tripeptide. The structural consequence of that modification has been investigated in solution by using IR and 1H NMR, with reference to the cognate proline-containing peptide. Contrary to proline, which induces beta-folding of the Pro-Ala sequence, azaproline apparently favors betaVI-folding of the Ala-AzPro one with high occurrence. Opening of the AzPro pyrazolidine ring to get N-methylazaalanine fundamentally does not change the structural properties of the azatripeptide, but allows the existence of open conformers to an extent depending on the solvent.

Aza-peptides. III. Experimental structural analysis of aza-alanine and aza-asparagine-containing peptides.

To determine the structural perturbations induced by the C alpha H-->N alpha exchange in aza-peptides, we have examined by 1H NMR and IR spectroscopy various derivatives of the aza-analogues of alanine, aspartic acid and asparagine in different organic solvents with increasing polarity. Their general formulas are: R1-AzXaa-NR2R3, R1-Pro-AzXaa-NR2R3 and R1-AzXaa-Pro-NR2R3 (where AzXaa denotes the aza-analogue of the amino acid residue Xaa = Ala, Asp, Asn; R1 = Boc, Z; R2, R3 = H, Me, iPr). The aza-analogue of an amino acid residue appears to be a strong beta-turn-inducing motif, and the AzAsn carboxamide side-chain is capable of interacting, as a proton donor, with the preceding peptide carbonyl group.

Combination of high-performance anion-exchange chromatography and electrospray mass spectrometry for analysis of the in vitro O-glycosylated mucin motif peptide.

Reversed-phase high-performance liquid chromatography (HPLC) and high-performance anion-exchange chromatography (HPAEC) with pulsed amperometric detection were developed for the study of products obtained from the in vitro O-glycosylation of a mucin motif peptide, TTSAPTTS, the most representative sequence encoded by the human gene MUC5C. After incubation of the peptide, which is rich in clustered hydroxyamino acids, by both human colonic and gastric microsomal homogenates, the glycosylated products were separated by HPLC and HPAEC and analysed by electrospray mass spectrometry (ES-MS). The combination of HPAEC and ES-MS was the approach used for evaluating the differences between the polypeptide N-acetylgalactosaminyltransferase activity in different digestive tissues.

X-ray structures of aza-proline-containing peptides.

The aza-analogue of proline (AzPro) contains a nitrogen atom in place of the CH alpha of the cognate residue. The resolution of the crystal structures of seven AzPro-containing peptides, presenting a set of ten AzPro motifs, reveals the structural properties of this particular aza-residue. Because of sterical hindrances, both nitrogen atoms are out of planarity, and the reduced electronic conjugation in the two AzPro-adjacent amide groups probably explains the longer amide bond distances and the weak proton-accepting character of the two pyrazolidine nitrogens. The absolute configuration of both AzPro nitrogens depends on the chemical nature of the sequence. In all cases, the AzPro residue assumes the same intrinsic three-dimensional structure and presents folding tendencies opposed to those induced by proline.