Control of Charge Dynamics via Use of Nonionic Phosphonate Chains and Their Effectiveness for Inverted Structure Solar Cells

Considering that a high compatibility at hybrid organic/inorganic interfaces can be achieved using polar and hydrophilic functionalities, this approach is used to improve inverted polymer solar cell performance by introducing nonionic phosphonate side chains (at 0%, 5%, 15%, and 30% substitution levels) into a series of isoindigo‐based polymers (PIIGDT‐Pn). This approach led to ≈20% improvement in power conversion efficiency compared to a nonmodified control polymer, via an increased short‐circuit current (J _SC). This enhancement is believed to stem from reduced nongerminate recombination and improved charge carried extraction when the level of phosphonate substitution is optimized. These results are substantiated by a combination of detailed electrical measurements including space‐charged limited current modeling, light intensity–dependent photocurrent (J _ph) analysis, and morphological studies (grazing‐incidence wide‐angle X‐ray scattering and atomic force microscopy). This is the first practical report demonstrating the use of nonionic polar side chains to control charge carrier dynamics in an existing photovoltaic polymer structure. It is envisioned that this simple strategy may be applied to other material systems and yield new materials with the potential for even higher performance.     

Structural Basis for the Binding Affinity of a Homologous Series of Synthetic Phenoxazone Drugs with DNA: NMR and Molecular Mechanics Analysis

Abstract

The molecular basis of the marked structure-activity relationship for a homologous series of DNA-binding phenoxazone drugs (ActII-ActIV) has been investigated by NMR spectroscopy and molecular mechanics. The spatial structures of the complexes between the drugs and a model deoxytetranucleotide, 5′-d(TpGpCpA), have been determined by molecular mechanics methods using homonuclear ¹H-¹H 2D-NOESY and heteronuclear ¹H-³¹P (HMBC) NMR spectroscopic data. Observed intermolecular NOE contacts and equilibrium binding studies confirm that the binding affinity of the synthetic phenoxazone derivatives with d(TGCA) decreases with an increase in the number of CH₂ groups in the dimethylami- noalkyl side chains, i.e., ActII > ActIII > ActIV, in agreement with the observed biological activity of these compounds. Molecular mechanics calculations of the spatial structures of the intercalated complexes of ActII-ActIV with d(TGCA) indicate that the different binding constants of the phenoxazone derivatives with the DNA oligomer are due to the different degrees of intercalation of the chromophore and the different steric arrangements of aminoalkyl side chains in the minor groove of the tetramer duplex; this results in different distances between the negatively-charged phosphates of the DNA duplex and the terminal positively-charged N(CH₃)₂ groups of the side chains.     

Effect of Alkylsilyl Side‐Chain Structure on Photovoltaic Properties of Conjugated Polymer Donors

Side‐chain engineering is an important strategy for optimizing photovoltaic properties of organic photovoltaic materials. In this work, the effect of alkylsilyl side‐chain structure on the photovoltaic properties of medium bandgap conjugated polymer donors is studied by synthesizing four new polymers J70 , J72 , J73 , and J74 on the basis of highly efficient polymer donor J71 by changing alkyl substituents of the alkylsilyl side chains of the polymers. And the photovoltaic properties of the five polymers are studied by fabricating polymer solar cells (PSCs) with the polymers as donor and an n‐type organic semiconductor (n‐OS) m‐ITIC as acceptor. It is found that the shorter and linear alkylsilyl side chain could afford ordered molecular packing, stronger absorption coefficient, higher charge carrier mobility, thus results in higher J_sc and fill factor values in the corresponding PSCs. While the polymers with longer or branched alkyl substituents in the trialkylsilyl group show lower‐lying highest occupied molecular orbital energy levels which leads to higher V_oc of the PSCs. The PSCs based on J70 :m‐ITIC and J71 :m‐ITIC achieve power conversion efficiency (PCE) of 11.62 and 12.05%, respectively, which are among the top values of the PSCs reported in the literatures so far.     

C-11 diamino cryptolepine derivatives NSC748392, NSC748393, and NSC748394: Anticancer profile and G-quadruplex stabilization

G-Quadruplex DNA ligands are promising novel anticancer agents with potentially fewer side effects and greater selectivity than standard anticancer drugs. However, the design of G-quadruplex ligands remains challenging since known chemical features increasing selectivity have often compromised drugability. Three C-11 diamino cryptolepine derivatives, with significant chemical differences between the side chains, low cytotoxicity to mammalian non-tumor cells (Vero cells) and drug-like properties, were selected for anticancer drug screening in the NCI Developmental Therapeutics Program. The three compounds showed good in vitro anticancer profiles with GI₅₀ averages at sub-micromolar concentrations (0.32–0.78 μM), cytostatic effects (TGI) at micromolar concentrations (1.3–6.9 μM) and moderate cytotoxic effects to cancer cells (LC₅₀) also at micromolar concentrations (4.7–33 μM), but only the compound with a linear alkylamine side chain (NSC748393) showed a good score in the in vivo anticancer Hollow Fiber assay. compare analysis of growth inhibition profile of NSC748393 suggested a multi-target mechanism. G-Quadruplex DNA binding affinity and selectivity studies by FRET-melting assays showed that NSC748392 and NSC478393, with aliphatic amine side chains, are good G-quadruplex ligands but not selective, whereas a C-11 aromatic side chain, as in NSC748394, increases selectivity although with decreasing binding affinity. Overall, NSC748393 can be considered a lead molecule for the design of effective but more selective anticancer drugs targeting telomeric G-quadruplexes.     

Molecular dynamics simulation on structural conformation of conjugated polymer-functionalised films for optimal fluorescent performance

The sensitive structure-related fluorescent properties of p-phenyleneethynylene (PPE)-functionalised fluorescent films with side chains and without side chains in different chemical environments are studied by molecular dynamics simulations. The calculations demonstrate that the structural change plays a crucial role in the fluorescent performance of PPE films, in which a major contribution is from the conformation of side chains. The PPE molecules with sides chains immobilised on SiO₂ substrate prefer to aggregate together in a dry state, but are more likely to stay in a monomolecular state in THF solvent. To an optimal concentration of the solvent molecules, the side chains are even perpendicular to the backbones of the molecules. The aggregation and separation of the PPE molecules with side chains are found to be controlled by the contraction and extension of the side chains connected to PPE. The van der Waals' force between the side chains is mainly responsible for these changes, which leads to a spreading out of the side chains in the presence of THF. All the results from the simulation studies can successfully explain the experimental observations.     

Pulmonary Delivery of Liposomal Drugs

Abstract

This overview will discuss our studies of liposomes aerosols to treat diseases of the lung and will entail (i) formulation and characterization of liposome aerosols, including dry liposome powder aerosols, (ii) modulation of the pharmacokinetic profile of liposomal drugs delivered by aerosol or intratracheal instillation, (iii) liposome-alveolar macrophage interactions in vitro and in vivo, and (iv) safety of liposome aerosols in vivo in mice, sheep and healthy human volunteers. Water-soluble agents can be retained in liposomes during aerosolization with air-pressure nebulizers within certain limitations of liposome composition, size, and operating conditions. Dry powder liposome aerosols have been formulated and deliver water-soluble encapsulated substances efficiently. Pharmacokinetic profiles of liposomal drugs delivered via intratracheal instillation exhibit typical slow release plasma profiles indicating that the carrier is the rate-limiting barrier for release. Accordingly, pulmonary mean residence times are significantly prolonged and systemic concentrations remain low. Liposomes do not inhibit the phagocytic activity of alveolar macrophages in vitro and in vivo, have no apparent histopathologic effects on lung architecture even after chronic administration, and do not alter dynamic compliance, lung resistance, p_aO₂ and p_aCO₂ in awake, unanesthetized sheep and in healthy human volunteers. In conclusion, liposomes are a promising innocuous aerosol delivery system for drugs to achieve prolonged localized drug concentrations in the lung or intracellular drug targeting to alveolar macrophages.     

Targeting of Drugs to Solid Tumors Using Anti-Her2 Immunoliposomes

Abstract

Cancer therapy would clearly benefit from a carrier system capable of intracellular delivery of systemically administered drugs to cancer cells in solid tumors. Sterically stabilized immunoliposomes specific to the cells expressing HER2 protooncogene (anti-HER2 SIL), were designed by conjugating Fab’ fragments of a recombinant humanized anti-HER2 MAb to the distal termini of poly(ethylene glycol) chains on the surface of unilamellar liposomes (size 90–100 nm) of phosphatidylcholine, cholesterol, and poly (ethylene glycol)—derivatized phosphatidylethanolamine. Anti-HER2 SIL avidly and specifically bound to cultured HER2-overexpressing cancer cells (8,000–23,000 vesicles per cell) and became endocytosed (k_e = 0.022–0.033 min.^?1) via the coated pit pathway. Anti-HER2 SIL showed prolonged circulation lifetime in rats (blood MRT approx. 24 hours) and significantly increased antitumor activity of encapsulated doxorubicin against HER2-overexpressing human breast cancer xenografts in nude mice. Although the accumulation of anti-HER2 SIL in HER2-overexpressing tumor xenografts was not increased over that of non-targeted sterically stabilized liposomes (SL), microscopic examination revealed abundance of anti-HER2 SIL in the interstitial spaces, as well as within the cytoplasm of cancer cells, while identical liposomes lacking anti-HER2 Fab’ were located predominantly within tumor-resident macrophages. Anti-HER2 SIL, a targeted vehicle capable of in vivo intracellular delivery of substances to HER2-overexpressing solid cancers, enhances the potential for tumor targeting and opens new avenues for better treatment of cancer.     

Carbon-13 NMR studies of the lysine side chains of calmodulin and its proteolytic fragments

ThepH-titration and dynamic behaviour of the seven lysine side chains in bovine calmodulin were studied by carbon-13 NMR. The amino groups of the calcium saturated protein and its proteolytic fragments TR₁C(1–75) and TR₂C (78–148) were dimethylated with carbon-13 labeled formaldehyde; this modification did not alter the protein's structure or its ability to activate the enzyme cyclic nucleotide phosphodiesterase. Tentative assignments for 5 out of the 7 dimethyl lysine resonances could be obtained by comparing spectra of the fully and partially modified protein, with those of the proteolytic fragments. ThepK_a values measured for calcium saturated calmodulin ranged between 9.5 (Lys 75) and 10.2 (Lys 13); two residues (Lys 94 and Lys 13) showed a biphasic titration curve suggesting their possible involvement in ion-pairs. The dynamic behavior of the lysine side chains was deduced from spin lattice relaxation measurements. All side chains were flexible and this was not influenced by the removal of calcium, or the addition of the calmodulin antagonist trifluoperazine. The latter data suggest that the lysine side chains are not directly involved in calmodulin's target binding sites.     

Rational design of amphiphile-based drug carriers and sterically stabilized carriers

Abstract

This paper describes the parameters recommended for rational design of amphiphile-based drug carriers. The main advantage of a carrier is its ability to modify the pharmacokinetics and biodistribution of the drug, so that the drug level at the target is sufficient for therapeutic benefits. Three parameters are described. Two of them, the drug-to-carrier partition coefficient (Ky_iC) and the rate of drug release from the carrier (k_ff), are related to drug-carrier interactions; the third one is the rate of carrier clearance (k_c). We demonstrate that carrier performance for drugs associated with the carrier amphiphile(s) is determined to a large extent by K_c, while for drugs encapsulated in the aqueous phase of the carrier it is important that k_off will be similar to k_c These conclusions are based on two examples: (i) Amphotericin B as a drug associated with five dosage forms which represent different types of amphiphile-based carriers: micelles (Fungizone), stable micelle-like disks (Amphocil), a complex with phospholipids (ABPLC), liposomes (AmBisome), and a submicronized emulsion, (ii) Liposomal doxorubicin which consisted of either doxorubicin associated with the membrane of negatively-charged, fluid oligolamellar liposomes (L-DOX) or doxorubicin loaded by an ammonium sulfate gradient into small, unilamellar, rigid liposomes having steric stabilizing lipid grafted in their lipid bilayer, (S-DOX). To better understand what contributes to k, we also describe the effect of bilayer acyl chain composition and the role of precipitation of the drug inside the liposomes.     

Effects of Vitamin B12 Analogues with Alternations in the Side Chains of the Corrin Ring on Urinary Methylmalonate Excretion in Vitamin B12-Deficient Rats

To study how much the side chains of the corrin ring of vitamin B₁₂ are involved in the physiological roles of the vitamin, five vitamin B₁₂ analogues (cyanocobalamin-b-monocarboxylate, cyanocobalamin-d-monocarboxylate, cyanocobalamin-e-monocarboxylate, cyano-13-epicobalamin, and cyanocobalamin(c-lactam)) with alternations in the side chains were synthesized chemically and then administered orally and intravenously to vitamin B₁₂-deficient rats. Male rats fed a vitamin B₁₂-deficient diet for 11 wk developed a severe vitamin B₁₂ deficiency with a high urinary methylmalonate excretion (223.8 ± 136.2 μmol/d) and ~97% (1.2±0.7ng/g tissue) lower hepatic vitamin B₁₂ content. Oral and intravenous administration of cyanocobalamin-b-,-d-, and -e-monocarboxylates and cyano-13-epicobalamin could not improve the severe vitamin B₁₂-deficient status of the rats, indicating that the b-, d-, and e-propionamide side chains of the corrin ring of vitamin B₁₂ are important in the absorption, transport, and function of the vitamin in rats. Urinary methylmalonate excretion of the rats that were intravenously administered cyanocobalamin(c-lactam) increased twice as much as those of the other analogue-supplemented rats, suggesting that cyanocobalamin(c-lactam) act as a powerful Cbl-antagonist. The results also indicate that mammalian cells do not contain a system for synthesizing complete vitamin B₁₂ from these analogues.     

13C Nuclear magnetic resonance study of salt induced conformational change of basic polypeptides: Poly (L-lysine), poly (L-arginine), and poly (L-ornithine)

A ¹³C-nmr study of the salt-induced helix–coil transition of the basic polypeptides poly(L -lysine) [(Lys)_n], poly(L -arginine) [(Arg)_n], and poly (L -ornithine) [(Orn)_n] was performed to serve as a reference of the helical portion of histones and other proteins. As is the case with pH-induced helix–coil transition, the downfield displacement of the C^α and carbonyl carbon signals are observed in the helical state. The upfield shift of the C^β signals, on the other hand, is noted in the salt-induced transition. Regardless of the differences in the side chains and also the salts used, very similar helix-induced chemical shifts are obtained for (Lys)_n and (Arg)_n. However, the displacement of the C^α, C^β, and carbonyl carbons of (Orn)n in the presence of 4M NaClO₄ is found to be almost 50% of that of (Lys)_n and (Arg)_n. This is explained by the fact that the maximum helical content is about 50%, consistent with the ORD result. Further, the motion of the backbone and side chains of the helical from was estimated by measuring the spin-lattice relaxation time (T₁), nuclear Overhauser enhancement (NOE), and line width. In the case of (Lys)_n, the motion of the side chains is charged very little in comparison with that of the random coil. Indicating that the aggregation of the salt-induced helix is small in contrast to that of the pH-induced helix. For (Arg)_n, however, the precipitate of the helical polymers is mainly due to aggregation.     

Synthesis and characterization of an ionizable polyhexapeptide collagen model

Poly(Lys(HBr)-Gly-Pro-Pro-Gly-Pro) has been synthesized and studied by circular dichroism (CD) spectroscopy. It is apparently the first polyhexapeptide collagen model reported with an ionizable side chain. The monomer (ε-(p-nitrobenzyloxycarbonyl)-Lys-Gly-Pro-Pro-Gly-Pro-p-nitrophenyl-ester) was prepared by a stepwise strategy employing active esters. Polymerization in N,N-dimethyl formamide, followed by removal of the Lys side chain protection with HBr/acetic acid, gave a polydisperse product. Fractionation was accomplished by gel filtration chromatography. The polydisperse material had a molecular weight (M_r = 5–17,000). High molecular weight fractions from triple helices under concentrated conditions at 2°C. The triple helical structure gives a CD pattern very similar to that of collagen and its triple helical analogs. However, unlike collagen, the polyhexapeptide undergoes spontaneous dissociation at temperatures substantially below the melting temperature from a triple helical form to single chains. This process is promoted at low concentrations, high temperature, neutral pH, and low molecular weight, and is apparently due, in large part, to unfavorable ionic side-chain interactions. In addition to this relatively slow “ionic” dissociation the triple helical polypeptide may be thermally dissociated in a manner similar to collagen. The thermal denaturation is a relatively fast process compared with ionic dissociation. A high molecular weight fraction (3 × M_r = 48,000) was found to melt at 42°C at neutral pH but increased to 54°C at pH 12 where the lysyl side chains are predominantly deprotonated. Furthermore, reconstitution of triple helices appeared to be more readily achieved at high pH. Thus it is concluded that ionic repulsion between side chains causes destabilization of the triple helix and hinders reconstitution.     

Curious structure in “canonical” alanine-based peptides

We have performed all atom simulations of blocked peptides of the form (AAXAA)₃, where X = Gln, Asn, Glu, Asp, Arg, and Lys with explicit water molecules to examine the interactions between side chains spaced i,i–5 in the sequence. Although side chains in this i,i–5 arrangement are commonly believed to be noninteracting, we have observed the formation of unusual i,i–5 main chain hydrogen bonding in such sequences with positively charged residues (Lys) as well as polar uncharged groups (Gln). Our results are consistent with the unusual percentage of hydrogen bonding curves produced by amide exchange measurements on the well-studied sequence acetyl-(AAQAA)₃-amide in water (Shalongo, W., Dugad, L., Stellwagen, E. J. Am. Chem. Soc. 116:8288–8293, 1994). Analysis of our simulations indicated that the glutamine side chain showed the greatest propensity to support π helix formation and that the i,i–5 intramolecular hydrogen bonds were stabilized by water-bridging side chain interactions. This intermittent formation of the unusual π helix structure was observed for up to 23% of the total simulation time in some residues in (AAQAA)₃. Control studies on peptides with glutamine side chains spaced i,i–3, i,i–4, and i,i–6 did not reveal similar unique structures, providing stronger evidence for the unique role side chain interactions with i,i–5 spacing. © 1997 Wiley-Liss Inc.     

Arabinogalactan from Western larch, Part III: alkaline degradation revisited, with novel conclusions on molecular structure

Alkaline degradation of larch arabinogalactan (AG) involves rapid peeling of the (1→3)-galactan main chain from the reducing end. The products are the original side chains attached to galactometasaccharinic (GalMS) acids derived from main-chain residues. These products have been separated by GPC and studied by compositional, methylation and NMR analyses. Results confirm that in a typical AG molecule most main-chain residues carry a side chain on C-6. About half of these side chains are β-(1→6)-linked Galp dimers, and about a quarter are single Galp residues. The rest contain three or more residues and include most of the Ara (arabinose) found in the polysaccharide. About one-fifth of the original Ara is consumed by the peeling reaction, and Ara groups at the non-reducing end of the main chain are proposed, predominantly as arabinobiosyl groups [β-l-Arap-(1→3)-L-Araf-(1→.. In general for the larger side chains abundance decreases with size, while branching and Ara content increase with size. Most terminal Araf residues occur in three- and four-residue side chains, while most arabinobiosyl groups are found in side chains of more than three residues. The Ara probably occurs only as these monomeric or dimeric groups, and since no Ara is found in side chains smaller than three residues, this implies that there are no Ara branches attached directly to the main chain.     

Side chain interactions in aromatic dipeptides

A study of the 100-MHZ nuclear magnetic resonace spectra in D₂O solution was made of a series of linear dipeptides of the types L -phenylalanine-L -and-D -X, and L -phenylalanine-L -and-D -Y, where X comprised a group of amino acid residues with polar side chains (X = glutamine, glutamic acid, arginine, and N^ε-acetyllysine) and Y comprised amino acid residues with purely aliphatic side chains (Y = α-aminobutyric acid and norvaline). It was found that regardless of the side chain length, resonances due to the α-methylene protons in the X and Y side chains of the L -Phe-D -Y series consistently exhibited upfield shifts greater than any other protons in these side chains, when compared to the corresponding side chain resonances of the nonaromatic dipeptide series L -Ala-L -X and L -Ala-L -Y. The magnitudes of these shielding effects were consistently and considerably greater for the L -Phe-D -X series than for the L -Phe-D -Y series. An intramolecular complex–formed by association of armatic π-electrons with the positive end of the dipole in the polar side chains—was proposed as one plausible interpretation of the enhanced shielding effects. An increase in temperature from 32 to 70–80° was sufficient to overcome the enhanced shielding attributable to the suggested complex.     

Side‐Chain Engineering for Enhancing the Properties of Small Molecule Solar Cells: A Trade‐off Beyond Efficiency

Three small molecules with different substituents on bithienyl‐benzo[1,2‐b:4,5‐b′]dithiophene (BDTT) units, BDTT‐TR (meta‐alkyl side chain), BDTT‐O‐TR (meta‐alkoxy), and BDTT‐S‐TR (meta‐alkylthio), are designed and synthesized for systematically elucidating their structure–property relationship in solution‐processed bulk heterojunction organic solar cells. Although all three molecules show similar molecular structures, thermal properties and optical band gaps, the introduction of meta‐alkylthio‐BDTT as the central unit in the molecular backbone substantially results in a higher absorption coefficient, slightly lower highest occupied molecular orbital level and significantly more efficient and balanced charge transport property. The bridging atom in the meta‐position to the side chain is found to impact the microstructure formation which is a subtle but decisive way: carrier recombination is suppressed due to a more balanced carrier mobility and BDTT based devices with the meta‐alkylthio side chain (BDTT‐S‐TR) show a higher power conversion efficiency (PCE of 9.20%) as compared to the meta‐alkoxy (PCE of 7.44% for BDTT‐TR) and meta‐alkyl spacer (PCE of 6.50% for BDTT‐O‐TR). Density functional density calculations suggest only small variations in the torsion angle of the side chains, but the nature of the side chain linkage is further found to impact the thermal as well as the photostability of corresponding devices. The aim is to provide comprehensive insight into fine‐tuning the structure–property interrelationship of the BDTT material class as a function of side chain engineering.     

Interplay Between Side Chain Pattern,Polymer Aggregation,and Charge Carrier Dynamics in PBDTTPD:PCBM Bulk‐Heterojunction Solar Cells

Poly(benzo[1,2‐b:4,5‐b′]dithiophene–alt–thieno[3,4‐c]pyrrole‐4,6‐dione) (PBDTTPD) polymer donors with linear side‐chains yield bulk‐heterojunction (BHJ) solar cell power conversion efficiencies (PCEs) of about 4% with phenyl‐C₇₁‐butyric acid methyl ester (PC₇₁BM) as the acceptor, while a PBDTTPD polymer with a combination of branched and linear substituents yields a doubling of the PCE to 8%. Using transient optical spectroscopy it is shown that while the exciton dissociation and ultrafast charge generation steps are not strongly affected by the side chain modifications, the polymer with branched side chains exhibits a decreased rate of nongeminate recombination and a lower fraction of sub‐nanosecond geminate recombination. In turn the yield of long‐lived charge carriers increases, resulting in a 33% increase in short circuit current (J _sc). In parallel, the two polymers show distinct grazing incidence X‐ray scattering spectra indicative of the presence of stacks with different orientation patterns in optimized thin‐film BHJ devices. Independent of the packing pattern the spectroscopic data also reveals the existence of polymer aggregates in the pristine polymer films as well as in both blends which trap excitons and hinder their dissociation.     

Temperature-Induced conformational transition in xanthans with partially hydrolyzed side chains

The conformational properties of xanthans with partially hydrolyzed side chains were in vestigated by optical rotation, CD, and differential scanning calorimetry (DSC). All variants displayed the well-known temperature-driven, cooperative order–disorder transition, and both optical rotation and DSC showed that the transition temperature was essentially independent of the content of terminal β-mannose. It was found that up to 80% of the changes in the specific optical rotation accompanying the transition reflects conformational changes linked to the terminal β-mannose in the side chains. Modification of the sidechains also affected the CD when xanthan was in the ordered state, but in this case the data suggest that the glucuronic acid is the major component determining the magnitude of the CD signal. DSC measurements showed that the transition enthalpy (ΔH_cal) increased linearly with the fraction of β-mannose, again indicating that a significant part (up to 80%) of ΔH_cal reflects conformational changes in the side chains. The conformational transition of the xanthan variants generally showed a higher degree of cooperativity (sharper transition) than unmodified, pyruvated xanthan. Calculation of the cooperativity parameter σ by means of the Zimm–Bragg theory (OR data) or from the ratio between ΔH_cal and the van't Hoff enthalpy (ΔH_vH) using DSC data showed a correlation between σ and the content of β-mannose, but the two methods gave different results when the content of β-mannose approached 100%. The ionic strength dependence of the transition temperature, expressed as d (log I)/d(T^?1_m), was nearly identical for intact xanthan and a sample containing only 6% of the terminal β-mannose. Application of the Manning polyelectrolyte theory does not readily account for the observed ΔH_cal values, neither does it provide new information on the nature of the ordered and disordered conformations in xanthan. © 1993 John Wiley & Sons, Inc.     

Biodegradable polymeric derivatives of polypeptide drugs for targeting

Relatively short polymer chains with lower critical solution temperatures were immobilized on protein macromolecules to obtain biodegradable polymeric derivatives of proteins (including those for heat-inactivated targeting of polypeptide drugs). Addition of a derivative to a multicomponent biological system and heating of the target to a temperature in excess of the lower critical solution temperature was followed by the carrier release into a separate phase and the transportation of the bound protein to the target. The protein molecule served as a biodegradable region and was progressively hydrolyzed, with the formation of low-molecular-weight fragments. These fragments were readily eliminated from the organism. The physiological activity of immobilized serum albumin was independent of the number of attached chains in the polymer carrier (the constant of bilirubin binding equaled 10⁸ M^?1). The biodegradation of synthetic systems, caused by α-chymotrypsin, was also studied. The more polymer chains were attached to serum albumin, the greater was the resistance of the protein to enzymatic hydrolysis.     

Interactions of some commonly used drugs with human α-thrombin

Adverse side effects of drugs are often caused by the interaction of drug molecules to targets other than the intended ones. In this study, we investigated the off-target interactions of some commercially available drugs with human α-thrombin. The drugs used in the study were selected from Super Drug Database based on the structural similarity to a known thrombin inhibitor argatroban. Interactions of these drugs with thrombin were initially checked by in silico docking studies and then confirmed by thrombin inhibition assay using a fluorescence microplate-based method. Results show that the three commonly used drugs piperacillin (anti-bacterial), azlocillin (anti-bacterial), and metolazone (anti-hypertensive and diuretic) have thrombin inhibitory activity almost similar to that of argatroban. The K_i values of piperacillin, azlocillin, and metolazone with thrombin are .55, .95, and .62?nM, respectively. The IC₅₀ values of piperacillin, azlocillin, and metolazone with thrombin are 1.7, 2.9, and 1.92?nM, respectively. This thrombin inhibitory activity might be a reason for the observed side effects of these drugs related to blood coagulation and other thrombin activities. Furthermore, these compounds (drugs) may be used as anti-coagulants as such or with structural modifications.