Development of an organic polymer monolith column for the nano liquid chromatography fast analysis of monoclonal antibody in infusion bags prepared in a hospital pharmacy.

Poly(butyl methacrylate-co-ethylene dimethacrylate) monolith was in situ prepared in a liquid chromatography capillary column with a 75 µm internal diameter. This monolith offered high permeability (5.3 ± 10-14 m2) and good peak capacity (140 for a 15 cm column length at 300 nl/min with a 20 min gradient time). This is exemplified by its separation ability in reversed mode for subunit analysis of monoclonal antibodies after IdeS digestion (middle-up analysis). The potential of this column was also illustrated for the fast analytical control of therapeutic monoclonal antibodies in standardized infusion bags prepared in advance in a pharmacy department. Linearity analysis revealed the column's capability for accurate quantification analysis of the different dose bandings (in mg) of monoclonal antibodies in <2 min. In addition, lifetime analysis data indicated that the column can be highly reproducible and has a long lifetime with stable and low back pressure. The variations observed on the peak shape and area between unstressed (intact) and stressed monoclonal antibodies indicated that our nano liquid chromatographic method was stability indicating. In addition, using a gradient elution mode, the presence of minor components in the infusion bags was visualized.

New liquid chromatography columns for highlighting the interaction of ligand candidates with humic acid.

Humic acid was the main compound in soil and reduced the availability of some organic compounds in soils. In this work, humic acid was immobilized for the first time on a homemade neutravidin poly(glycidyl methacrylate-co-ethylene dimethacrylate) capillary column with a 20 µm i.d. for the screening of potential ligands to humic acid and the evaluation of their molecular recognition mechanism. This homemade humic acid column enabling it to work at very low backpressure (0.60 MPa at 20 nl/min flow rate), had a long lifetime, excellent repeatability, and negligible non-specific binding sites. The performance of this affinity humic acid column was demonstrated by the evaluation of recognition assay for a series of known ligands of humic acid (a series of rodenticide molecules) which is the heart of the fragment-based drug design. In addition, this column was used successfully for highlighting the binding mechanism to humic acid of the severe acute respiratory syndrome coronavirus-2-spike protein. As well this new humic acid miniaturized liquid chromatography column developed in this work could be used in the feature for another solute molecule-humic acid binding studies or for a separative mode.

Development of nano Bio LC columns for the search of acetylcholinesterase molecular targets.

A novel acetylcholinesterase Nano liquid chromatography capillary column (75 µm i.d. × 50 mm length) was developed for the fast screening of acetylcholinesterase inhibitors and the evaluation of their molecular recognition mechanism. Biotinylated acetylcholinesterase was immobilized on a streptavidin Nano liquid chromatography capillary column. Because of the very strong streptavidin-biotin interaction, the acetylcholinesterase immobilization step performed by frontal analysis is very fast (required less than 10 min), and the amount of immobilized acetylcholinesterase was in the microgram range (1 µg). The yellow anion obtained from the enzymatic reaction detected at 412 nm was achieved within 60 s, and the immobilized acetylcholinesterase retained 96% of the initial activity beyond 90 days. This column was successfully applied for the discrimination of weak affinity ligands to acetylcholinesterase from nonbinders, which is the heart of fragment-based drug design. This column was used for the determination of the IC50 values of a series of inhibitor molecules. In addition, it was demonstrated that competitive experiments could be performed with our miniaturized system to confirm the existence and binding pocket of a ligand to acetylcholinesterase contained in a methanol plant extract. The results revealed that our acetylcholinesterase Nano liquid chromatography capillary column developed in this work represents a useful tool for the rapid screening of inhibitor candidates and evaluation of the action mechanism.

ACE2 and SARS-CoV-2-Main Protease Capillary Columns for Affinity Chromatography: Testimony of the Binding of Dexamethasone and its Carbon Nanotube Nanovector.

In this paper, each of the two following proteins, the angiotensin-converting enzyme 2 (ACE2) and the Main protease (Main pro) of the Severe Acute Respiratory Syndrome Coronavirus-2 (SARS-CoV-2) were grafted for the first time on homemade neutravidin poly(GMA-co-EDMA) capillary columns for the research of their ligands. The effect of the column diameter on the quantity of immobilized biotinylated protein was studied. For a capillary length of 40 mm, when its internal diameter varied from 75 to 25 µm, the grafted quantity of ACE2 decreased by 85% (from 1.50 to 0.24 µg). Among all the studied ligands, a particular vigilance has been given for dexamethasone, a widely used molecule today for adult patients hospitalized with SARS-CoV-2. Competition experiments were performed with SARS-CoV-2 Receptor Binding Domain used as reference molecule with the ACE2 affinity column to assess the orthosteric binding site of dexamethasone (Dex) on ACE2. This ligand was then immobilized on Multiwall Carbon Nanotubes (Dex/MWCNT). By comparison of the normalized breakthrough curves measured for Dex and Dex/MWCNT on both the ACE2 and Main pro affinity columns, it was showed for the first time that nanovectorisation of Dex with MWCNT enhanced and stabilized its binding to both ACE2 and Main pro. This last result reinforced the use of Dex and the interest of MWCNT for boosting immune health against COVID 19.

Comparative binding to DR4 and DR5 receptors of TRAIL and BNNTs/PAHE/mPEG-DSPE/TRAIL nanoparticles.

TRAIL is a member of the tumor necrosis factor family of cytokines, which induces apoptosis of cancer cells, thanks to its binding to its cognate receptors DR5 and DR4. We have recently demonstrated that nanovectorization of TRAIL with single-walled carbon nanotubes enhanced TRAIL affinity to DR5. In this paper, 1-pyrenebutyric acid N-hydroxysuccinimide ester functionalized boron nitride nanotubes (BNNTs) were used to anchor the TRAIL protein. The resulting BNNT/1-pyrenebutyric acid N-hydroxysuccinimide ester nanotubes were mixed with methoxy-poly(ethylene glycol)-1,2-distearoyl-sn-glycero-3-phosphoethanolamine-N-conjugates so as to allow a good dispersion of these nanoparticle TRAIL (NPT) in aqueous solution. The difference of binding between NPT and soluble TRAIL to DR4 and DR5 receptors was then studied by the use of affinity chromatography. DR4 and DR5 receptors were thus immobilized on a chromatographic support, and the binding of the 2 ligands TRAIL and NPT to DR4 and DR5 was studied in the temperature range 30°C to 50°C. Negative enthalpy (ΔH) values indicated that van der Waals interactions and hydrogen bonding are engaged favorably at the ligand-receptor interface. It was shown that their rank-ordered affinities were strongly different in the sequence TRAILDR4  < NPTDR4  < TRAILDR5  < NPTDR5 , and the highest affinity for NPT to DR4 and DR5 receptors observed at low pHs was due to the less accessibility of the His molecular switch to be protonated when TRAIL was immobilized on BNNTs. Taken together, our results demonstrated that nanovectorization of TRAIL with BNNTs enhanced its binding to both DR4 and DR5 receptors at 37°C. Our novel nanovector could potentially be used for delivering TRAIL to cells for cancer treatment.

Enhanced DR5 binding capacity of nanovectorized TRAIL compared to its cytotoxic version by affinity chromatography and molecular docking studies.

Tumor necrosis factor-related apoptosis-inducing ligand (TRAIL) induces apoptosis of cancer cells when bound to its cognate receptors, TRAIL-R1 and TRAIL-R2 (DR4 and DR5), without being toxic to healthy cells. Nanovectorized TRAIL (abbreviated as NPT) is 10 to 20 times more efficient than one of the most potent soluble TRAIL used in preclinical studies (His-TRAIL). To determine whether differences in affinity may account for NPT superiority, a thermodynamic study was undertaken to evaluate NPT versus TRAIL binding affinity to DR5. Docking calculations showed that TRAIL in homotrimer configuration was more stable than in heterotrimer, because of the presence of one Zn ion in its structure. Indeed, TRAIL trimers can have head-to-tail orientations when Zn is missing. Altogether these data suggest that TRAIL homotrimer structures are predominant in solution and then are grafted on NPT. When docked to DR5, NPT carrying TRAIL homotrimer leads to a more stable complex than TRAIL monomer-based NPT. To comfort these observations, the extracellular domain of DR5 was immobilized on a chromatographic support using an "in situ" immobilization technique. The determination of the thermodynamic data (enthalpy ∆H° and entropy ∆S°*) of TRAIL and NPT binding to DR5 showed that the binding mechanism was pH dependent. The affinity of NPT to DR5 increased with pH, and the ionized energy was more important for NPT than for soluble TRAIL. Moreover, because of negative values of ∆H° and ∆S°* quantities, we demonstrated that van der Waals and hydrogen bonds governed the strong NPT-DR5 association for pH > 7.4 (as for TRAIL alone). Copyright © 2016 John Wiley & Sons, Ltd.

H2O2: a Ca(2+) or Mg(2+)-sensing function in statin passive diffusion.

In a previous paper Guillaume's group demonstrated that magnesium (Mg(2+) concentration range 0.00-2.60 mm) increased the passive diffusion of statins and thus played a role in their potential toxicity. In order to confirm an increase in this passive diffusion by divalent salt cations, the role of calcium chloride (CaCl2) on the statin-immobilized artificial membrane (IAM) association was studied. It was demonstrated that calcium supplementation (Ca(2+) concentration range 0.00-3.25 mm) increases the statin passive diffusion. In addition, it was shown that the Ca(2+) effect on the statin-IAM association is higher than that of Mg(2+). These results show that Ca(2+) enhances the passive diffusion of drugs into biological membranes and thus their potential toxicity. Also, addition of H2O2 to the medium showed a hyperbolic response for the statin passive diffusion and this effect was enhanced for the highest Ca(2+) or Mg(2+) concentrations in the medium. H2O2 is likely to interact with the polar head groups of the IAM through dipole-dipole interactions. The conformational changes in H2O2-IAM result in a higher degree of exposure of hydrophobic areas, thus explaining why the binding of pravastatin, which showed the lowest logP value, was less affected by H2O2. This result shows the significant contribution of H2O2 and thus the oxidative stress on the statin passive diffusion. Much of the sensitivity derives from the action of Ca(2+) or Mg(2+), in turn supported the idea that H2O2 may serve a Ca(2+) or Mg(2+) sensing function in statin passive diffusion.

Thermodynamic study of transthyretin association (wild-type and senile forms) with heparan sulfate proteoglycan: pH effect and implication of the reactive histidine residue.

The tetramer destabilization of transthyretin into monomers and its fibrillation are phenomena leading to amyloid deposition. Heparan sulfate proteoglycan (HSPG) has been found in all amyloid deposits. A chromatographic approach was developed to compare binding parameters between wild-type transthyretin (wtTTR) and an amyloidogenic transthyretin (sTTR). Results showed a greater affinity of sTTR for HSPG at pH 7.4 compared with wtTTR owing to the monomeric form of sTTR. Analysis of the thermodynamic parameters showed that van der Waals interactions were involved at the complex interface for both transthyretin forms. For sTTR, results from the plot representing the number of protons exchanged vs pH showed that the binding mechanism was pH-dependent with a critical value at a pH 6.5. This observation was due to the protonation of a histidine residue as an imidazolium cation, which was not accessible when TTR was in its tetrameric structure. At pH >6.5, dehydration at the binding interface and several contacts between nonpolar groups of sTTR and HSPG were also coupled to binding for an optimal hydrogen-bond network. At pH <6.5, the protonation of the His residue from sTTR monomer when pH decreased broke the hydrogen-bond network, leading to its destabilization and thus producing slight conformational changes in the sTTR monomer structure.

Carbon nanotube poroshell silica as a novel stationary phase for fast HPLC analysis of monoclonal antibodies.

A new carbon nanotube porous silica poroshell stationary phase was developed. The chromatographic support was coated with ultrashort single-wall carbon nanotubes (SWCNTs) in a noncovalent way. It was demonstrated that the porous amino silica surface of the 300 NH2 poroshell column stabilized with 1-methyl-2-pyrrolidinone efficiently and stably adsorbed SWCNTs onto the chromatographic support. It was shown that this novel poroshell carbon nanotube (CNT) stationary phase was very useful for the HPLC separation of a series of monoclonal antibodies (mAbs) in a short analysis time (<3 min). The high-performance liquid chromatography (HPLC) method was validated and was successfully tested for the fast quantitative and qualitative control of chemotherapeutic bags fabricated in a hospital pharmacy.

Analysis of the activation of acetylcholinesterase by carbon nanoparticles using a monolithic immobilized enzyme microreactor: role of the water molecules in the active site gorge.

A biochromatographic system was used to study the direct effect of carbon nanoparticles (CNPs) on the acetylcholinesterase (AChE) activity. The AChE enzyme was covalently immobilized on a monolithic CIM-disk via its NH2 residues. Our results showed an increase in the AChE activity in presence of CNPs. The catalytic constant (k(cat)) was increased while the Michaelis constant (K(m)) was slightly decreased. This indicated an increase in the enzyme efficiency with increase of the substrate affinity to the active site. The thermodynamic data of the activation mechanism of the enzyme, i.e. ΔH* and ΔS*, showed no change in the substrate interaction mechanism with the anionic binding site. The increase of the enthalpy (ΔH*) and the entropy (ΔS*) with decrease in the free energy of activation (Ea) was related to structural conformation change in the active site gorge. This affected the stability of water molecules in the active site gorge and facilitated water displacement by substrate for entering to the active site of the enzyme.

Development of a new heparan sulfate proteoglycan (HSPG) chromolith LC column to study the pH dependence binding of peptide vaccines to HSPG and role of human serum albumin on its binding.

Heparan sulfate proteoglycan (HSPG) expressed on immune cell surface participate in antitumor T-cell responses generated in the acidic lymph node (LN) microenvironment. In this work, HSPG was immobilized for the first time on a HPLC chromolith support for studying the effect of extra cellular acidosis in LNs on the binding to HSPG of two peptide vaccines (universal cancer peptide UCP2 and UCP4). This home-made HSPG column enabling to work at high flow-rates, was resistance to change in pH, had a long - life time, an excellent repeatability and negligible non-specific binding sites. The performance of this affinity HSPG column was confirmed by the evaluation of recognition assay for a series of known ligand of HSPG. It was shown that at 37 °C, the UCP2 binding to HSPG versus pH described a sigmoidal shape while UCP4 remained relatively constant in the pH range 5.0-7.5 and lower than the one of UCP2. By the use of an HSA HPLC column, it was shown at 37 °C and in acidic conditions a loss of affinity of UCP2 and UCP4 to HSA. It was demonstrated that upon UCP2/HSA binding, the protonation of the histidine residue in the cluster R(arg) Q(Gln) Hist (H) of the UCP2 peptide allowed to expose more favorably than UCP4 its polar and cationic groups to the negative net charge of HSPG on immune cells. Acidic pHs led to the protonation of the UCP2 residue histidine by flipping the His switch to the on position with a concomitant increase in affinity for the negative net charge of HSPG confirming that UCP2 was more immunogenic than UCP4. As well this HSPG chromolith LC column developed in this work could be used in the feature for other protein - HSPG binding studies or for a separative mode.

Immobilization of the SARS-CoV-2-receptor binding domain onto methacrylate-based monoliths for nano LC at 30 nL min-1 and application for research of its ligands.

For the design of novel potent molecules against therapeutic protein targets produced in a low quantity or that are very expensive, the development of miniaturized analytical techniques is of crucial importance. One challenging target is the receptor binding domain (RBD) of the SARS-CoV-2-spike protein (S), which mediates the binding of the virus to host cells. In the present study, the RBD protein was thus immobilized on polymethacrylate monoliths prepared in a miniaturized capillary column (25 µm internal diameter; 70 mm length) by in situ polymerization, which could offer low backpressure in Nano LC at 30 nL min-1. The immobilized quantity of the expensive RBD protein on the organic monolith was very low, in the submicrogram range, i.e., 0.060 µg. The immobilization method reduced non-selective interactions between the ligand and the organic monolith matrix and maintained the functionality of RBD due to the high activity rate (96%). The performance of this miniaturized affinity capillary column was demonstrated for the rapid evaluation of a recognition assay induced by 1,2,3,4,6-pentagalloyl glucose (PGG), a known ligand of RBD, and by five other molecules. In addition, it was demonstrated that competitive experiments could be performed with our miniaturized system to reveal the existence of only one type of binding site for three ligands of RBD, namely carbenoxolone, simeprevir and irinotecan. All these results showed the potential of our analytical miniaturized affinity system for the determination of interactions between potential ligands and immobilized RBD of SARS-CoV-2 to aid in the battle against COVID-19.

Development of nano affinity columns for the study of ligand (including SARS-CoV-2 related proteins) binding to heparan sulfate proteoglycans.

The interactions of heparan sulfate proteoglycans (HSPGs) present on the cell surface with target proteins lead to cell signaling and they are considered as viral receptors. The analysis of the recognition mechanism between HSPG and its potential ligands and high-throughput screening in drug discovery thus remain important challenges. Glycidyl methacrylate-based monoliths were thus prepared in situ in miniaturized capillary columns (internal diameter 75 µm) and HSPG was grafted onto them by the use of the Schiff base method. The quantity of grafted HSPG was in the nanogram range (11 nanograms per cm of capillary length). This is of significant importance when working with less available or expensive biological material. Other advantages of our miniaturized capillary column are as follows: (i) the immobilization process of HSPG onto the organic monolithic support was reliable and reproducible. (ii) The resultant affinity capillary column showed a strong resistance to changes in temperature and pH and a negligible non-specific interaction. So as to confirm the proper functioning of our miniaturized capillary column, the molecular recognition by HSPG of five selected compounds including three ligands of interest related to SARS-CoV-2 was studied.

Development of a new nano arginase HPLC capillary column for the fast screening of arginase inhibitors and evaluation of their binding affinity.

A simple and rapid Nano LC method has been developed for the screening of arginase inhibitors. The method is based on the immobilization of biotinylated arginase on a neutravidin functionalized nano HPLC capillary column. The arginase immobilization step performed by frontal analysis is very fast and only takes a few minutes. The miniaturized capillary column of 170 nL (length 5 cm, internal diameter 75 µm) significantly decreased the required amount of used enzyme (25 pmol). This was of significance importance when working with less available or expensive purified enzyme. Non-selective adsorption of the organic monolith matrix was reduced (<6%) and the arginase efficient yield was high (92%). The resultant affinity capillary columns showed excellent repeatability and long lifetime. The arginase reaction product was achieved within 60 s and the immobilized arginase retained 97% of the initial activity beyond 90 days. This novel approach can thus be used for the fast evaluation of recognition assay induced bya series of inhibitor molecules (caffeic acid phenylamide, chlorogenic acid, piceatannol, nor-NOHA acetate) and plant extracts.

A novel stationary phase based on amino derivatized nanotubes for HPLC separations: theoretical and practical aspects.

A novel column based on silica containing immobilized carbon nanotubes (CNTs) was developed and evaluated in terms of its binding efficiency and resolution. First, CNT functionalized with amino groups (CNT-NH(2)) were prepared via chemical modification of carboxylic groups introduced on the CNT surface. Secondly the covalent immobilization of CNT-NH(2) was carried out by using glutardialdehyde activating agent on aminopropyl (AP)-silica surface. This CNT stationary phase was applied to the HPLC separation of two molecule series, i.e. polychlorinated biphenyl (PCB) isomers with different degrees of substitution in the ortho-position (non-ortho to tetra-ortho substituted) and terpenes (linalool, geraniol, thymol, alpha-terpineol). The retention behavior of these solute molecules was measured under isocratic conditions with different mobile phase compositions, ranging from 0.05-0.70 v/v of toluene in cyclohexane. The retention factors of the solute molecule do not depend linearly on the toluene fraction but follow a quadratic relationship. This CNT stationary phase was a very useful column for the separation of PCB congeners and terpenes. It was demonstrated that a planar conformation of the solute molecule enhanced the solute retention on this CNT stationary phase. As well, a quantitative structure relationship derived, demonstrated the significant input to retention was due to the structurally selective dipole-dipole and charge transfer interactions with the solutes. These results were compared with those obtained on the AP stationary phase. The proposed CNT stationary phase for the separation possess distinctive and interesting retentive properties, and chemometric analysis of retention data of appropriate designed series of test solutes appears to be a convenient, objective and quantitative method to prove a new phase specificity.

Statins (HMG-coenzyme A reductase inhibitors)-biomimetic membrane binding mechanism investigated by molecular chromatography.

Many studies have demonstrated that the statin beneficial effects on cardiovascular diseases like coronary are linked to their hypocholesterolemic properties. These lipid-lowering drugs are the first-line pharmacologic therapy for hypercholesterolemia. In this paper, the interaction of a series of statin molecules STCOOH (pravastatin (prava), mevastatin (meva), simvastatin (simva) and fluvastatin (fluva)) with a phosphatidylcholine monolayer immobilized on to porous silica particles has been studied using a biochromatographic approach (molecular chromatography). The immobilized artificial membrane (IAM) provided a biophysical model system to study the binding of the statin molecules to a lipid membrane. For all the test statin molecules, linear retention plots were observed at all temperatures. An analysis of the thermodynamics (i.e., enthalpy (DeltaH(0)), entropy (DeltaS(0)*)) of the interaction of the statin molecules with the immobilized monolayer was also carried out. The DeltaH(0) and DeltaS(0)* values were negative due to van der Waals interactions and hydrogen bonding between the statin molecules with the polar head groups of the phospholipid monolayer (polar retention effect). The statin elution order was: Prava<<

Association mechanism of four acetylcholinesterase inhibitors (AChEIs) with human serum albumin: a biochromatographic approach.

In this work, the interaction of a series of acetylcholinesterase inhibitors (AChEIs; donepezil, galanthamine, huperzine and neostigmine) with human serum albumin (HSA) immobilized on porous silica particles was studied using a biochromatographic approach. For all the tested AChEI molecules, linear retention plots were observed at all temperatures. An analysis of the thermodynamics (i.e. enthalpy (DeltaH degrees ), entropy ((S degrees *)) of the interaction of the AChEI molecules with the immobilized human serum albumin was also carried out. The (H degrees and (S degrees * values for donepezil, galanthamine and neostigmine, were negative due to van der Waals interactions and hydrogen bonding which govern this association with albumin. Whereas the positive values of (H degrees and (S degrees * of huperzine binding on HSA indicated a predominance of hydrophobic interactions. The association of AChEIs with HSA was increased linearly with pH. A comparative thermodynamic study with benzodiazepine molecules was also done to determine the potential binding site of these drugs on HSA.

Magnesium cation effect on passive diffusion of statin molecules: molecular chromatography approach.

Recently, immobilized artificial membranes (IAMs) have been introduced as HPLC column packing materials. IAMs consist of phosphatidylcholine residues, the most common phospholipids in natural membranes, covalently bound to silica propylamine and consequently mimic fluid phospholipid bilayer. Thus, the immobilized artificial membrane provided a biophysical model system to study the passive diffusion of the statin molecules through the cellular membrane. Statins or 3-hydroxy-3-methylglutaryl coenzyme A reductase (HMG-CoA R) inhibitors are widely used for reducing the circulating atherogenic lipid fractions and decreasing cardiovascular morbidity and mortality. This paper describes magnesium cation (Mg(2+)) effect on five statin molecules (pravastatin, mevastatin, atorvastatin, simvastatin and fluvastatin)-IAM surface association using a molecular chromatography approach. An analysis of the thermodynamics (i.e. enthalpy (DeltaH degrees ), entropy (DeltaS degrees *)) of the interaction of the statin molecules with the immobilized monolayer was also carried out. The DeltaH degrees and DeltaS degrees * values were negative due to van der Waals interactions and hydrogen bonding between the statin molecules with the polar head groups of phospholipid monolayer (polar retention effect). However, the increase of statin-IAM association, with the Mg(2+) concentration increase, was associated with an increase of these thermodynamic data. This explains that this interaction was also governed by hydrophobic and electrostatic bonds which became preponderant. The statin elution order was: Pravastatin<<

Immobilization of arginase and its application in an enzymatic chromatographic column: thermodynamic studies of nor-NOHA/arginase binding and role of the reactive histidine residue.

A biochromatographic approach is developed to measure for the first time changes in enthalpy, heat capacity change and protonation for the binding of nor-NOHA to arginase in a wide temperature range. For this, the arginase enzyme was immobilized on a chromatographic support. It was established that this novel arginase column was stable during an extended period of time. The affinity of nor-NOHA to arginase is high and changes slightly with the pH, because the number of protons linked to binding is low. The determination of the enthalpy change at different pH values suggested that the protonated group in the nor-NOHA-arginase complex exhibits a heat protonation of approximately -33 kJ/mol. This value agrees with the protonation of an imidazole group. Our result confirmed that active-site residue Hist 141 is protonated as imidazolium cation. Hist 141 can function as a general acid to protonate the leaving amino group of L-ornithine during catalysis. The thermodynamic data showed that nor-NOHA-arginase binding, for low temperature (<15 degrees C), is enthalpically unfavourable and being dominated by a positive entropy change. This result suggests that dehydration at the binding interface and charge-charge interactions contribute to the nor-NOHA-arginase complex formation. The temperature dependence of the free energy of binding is weak because of the enthalpy-entropy compensation caused by a large heat capacity change, DeltaC(p)=-2.43 kJ/mol/K, of arginase. Above 15 degrees C, the thermodynamic data DeltaH and DeltaS became negative due to van der Waals interactions and hydrogen bonding which are engaged at the complex interface confirming strong enzyme-inhibitor hydrogen bond networks. As well, by the use of these thermodynamic data and known correlations it was clearly demonstrated that the binding of nor-NOHA to arginase produces slight conformational changes in the vicinity of the active site. Our work indicated that our biochromatographic approach could soon become very attractive for studying other enzyme-ligand binding.

Development of a simple technique for the coating of monolithic silica with pristine boron nitride nanotubes (BNNTs): HPLC chromatographic applications.

In this paper, a novel and very simple homogeneous coating of a monolithic silica HPLC support using pristine boron nitride nanotubes (BNNTs) was d0.escribed. The chromatographic support was coated with BNNTs in a non covalent way to preserve the nanotube structure. A solution of BNNTs dispersed in dimethylacetamide (DMAc) was pumped through the column at a flow-rate of 0.3mL/min for 24h at room temperature. Strong interaction between amino groups and the BNNT surfaces induces the adsorption of the BNNTs on the silica, while the stable solvation in DMAc hampers further adsorption of the tubes. The excellent stability of the non covalent BNNT-coating on the monolithic silica in view of application for HPLC was also demonstrated. It was shown that this novel stationary phase was efficient for the HPLC isocratic or gradient mode separation of molecules of different structure such as phenol derivatives, alkylbenzene or doping agents (steroids). As well, this simple technique of BNNT immobilization offers new perspectives for the BNNT-coating on the surfaces of a wide range of solid substrates.