Supramolecular approaches for insulin stabilization without prolonged duration of action

Aggregation represents a significant challenge for the long-term formulation stability of insulin therapeutics. The supramolecular PEGylation of insulin with conjugates of cucurbit[7]uril and polyethylene glycol (CB[7]‒PEG) has been shown to stabilize insulin formulations by reducing aggregation propensity. Yet prolonged in vivo duration of action, arising from sustained complex formation in the subcutaneous depot, limits the application scope for meal-time insulin uses and could increase hypoglycemic risk several hours after a meal. Supramolecular affinity of CB[7] in binding the B1-Phe residue on insulin is central to supramolecular PEGylation using this approach. Accordingly, here we synthesized N-terminal acid-modified insulin analogs to reduce CB[7] interaction affinity at physiological pH and reduce the duration of action by decreasing the subcutaneous depot effect of the formulation. These insulin analogs show weak to no interaction with CB[7]‒PEG at physiological pH but demonstrate high formulation stability at reduced pH. Accordingly, N-terminal modified analogs have in vitro and in vivo bioactivity comparable to native insulin. Furthermore, in a rat model of diabetes, the acid-modified insulin formulated with CB[7]‒PEG offers a reduced duration of action compared to native insulin formulated with CB[7]‒PEG. This work extends the application of supramolecular PEGylation of insulin to achieve enhanced stability while reducing the risks arising from a subcutaneous depot effect prolonging in vivo duration of action.

Development of a novel multi-functional integrated bioconjugate effectively targeting K-Ras mutant pancreatic cancer / 药物分析学报

Folate receptor(FR)overexpression occurs in a variety of cancers,including pancreatic cancer.In addi-tion,enhanced macropinocytosis exists in K-Ras mutant pancreatic cancer.Furthermore,the occurrence of intensive desmoplasia causes a hypoxic microenvironment in pancreatic cancer.In this study,a novel FR-directed,macropinocytosis-enhanced,and highly cytotoxic bioconjugate folate(F)-human serum albumin(HSA)-apoprotein of lidamycin(LDP)-active enediyne(AE)derived from lidamycin was designed and prepared.F-HSA-LDP-AE consisted of four moieties:F,HSA,LDP,and AE.F-HSA-LDP presented high binding efficiency with the FR and pancreatic cancer cells.Its uptake in wild-type cells was more extensive than in K-Ras mutant-type cells.By in vivo optical imaging,F-HSA-LDP displayed prominent tumor-specific biodistribution in pancreatic cancer xenograft-bearing mice,showing clear and lasting tumor localization for 360 h.In the MTT assay,F-HSA-LDP-AE demonstrated potent cytotoxicity in three types of pancreatic cancer cell lines.It also induced apoptosis and caused G2/M cell cycle arrest.F-HSA-LDP-AE markedly suppressed the tumor growth of AsPc-1 pancreatic cancer xenografts in athymic mice.At well-tolerated doses of 0.5 and 1 mg/kg,(i.v.,twice),the inhibition rates were 91.2％and 94.8％,respectively(P＜0.01).The results of this study indicate that the F-HSA-LDP multi-functional bioconjugate might be effective for treating K-Ras mutant pancreatic cancer.

Accurate construction of cell membrane biomimetic graphene nanodecoys via purposeful surface engineering to improve screening efficiency of active components of traditional Chinese medicine

Biomimetic nanoengineering presents great potential in biomedical research by integrating cell membrane (CM) with functional nanoparticles. However, preparation of CM biomimetic nanomaterials for custom applications that can avoid the aggregation of nanocarriers while maintaining the biological activity of CM remains a challenge. Herein, a high-performance CM biomimetic graphene nanodecoy was fabricated via purposeful surface engineering, where polyethylene glycol (PEG) was used to modifying magnetic graphene oxide (MGO) to improve its stability in physiological solution, so as to improve the screening efficiency to active components of traditional Chinese medicine (TCM). With this strategy, the constructed PEGylated MGO (PMGO) could keep stable at least 10 days, thus improving the CM coating efficiency. Meanwhile, by taking advantage of the inherent ability of HeLa cell membrane (HM) to interact with specific ligands, HM-camouflaged PMGO showed satisfied adsorption capacity (116.2 mg/g) and selectivity. Finally, three potential active components, byakangelicol, imperatorin, and isoimperatorin, were screened from Angelica dahurica, whose potential antiproliferative activity were further validated by pharmacological studies. These results demonstrated that the purposeful surface engineering is a promising strategy for the design of efficient CM biomimetic nanomaterials, which will promote the development of active components screening in TCM.

Effects of site-directed PEGylation on L-asparaginase thermostability / Efeitos da PEGuilação sítio-dirigida na termoestabilidade da L-asparaginase

The enzyme L-asparaginase (ASNase) is broadly applied as a drug to treat acute lymphoblastic leukemia, as well as in the food industry to avoid acrylamide formation in baked and fried food. In the present work, ASNase was covalently attached to polyethylene glycol (PEG) of different molecular weights (ASNase-PEG-5, ASNase-PEG-10, ASNase-PEG-20, and ASNase-PEG-40) at the N-terminal portion (monoPEGylation). Native and PEGylated forms were analyzed regarding thermodynamics and thermostability based on enzyme activity measurements. ASNase (native and PEGylated) presented maximum activity at 40 °C and denaturation followed a first-order kinetics. Based on these results, the activation energy for denaturation (E*d) was estimated and higher values were observed for PEGylated forms compared to the native ASNase, highlighting the ASNase-PEG10 with a 4.24-fold increase (48.85 kJ.mol-1) in comparison to the native form (11.52 kJ.mol-1). The enzymes were evaluated by residual activity over time (21 days) under different storage temperatures (4 and 37 °C) and the PEGylated conjugates remained stable after the 21 days. Thermodynamic parameters like enthalpy (ΔH‡), entropy (ΔS‡) and Gibbs free energy (ΔG‡) of ASNase (native and PEGylated) irreversible denaturation were also investigated. Higher - and positive - values of Gibbs free energy were found for the PEGylated conjugates (61.21 a 63.45 kJ.mol-1), indicating that the process of denaturation was not spontaneous. Enthalpy also was higher for PEGylated conjugates (18.84 a 46.08 kJ.mol-1), demonstrating the protective role of PEGylation. As for entropy, the negative values were more elevated for native ASNase (-0.149 J/mol.K), pointing out that the denaturation process enhanced the randomness and aggregation of the system, which was observed by circular dichroism. Thus, PEGylation proved its potential to increase ASNase thermostability

A enzima L-asparaginase (ASNase) é amplamente usada como medicamento para tratamento da leucemia linfoblástica aguda, bem como na indústria de alimentos para evitar a formação de acrilamida em alimentos cozidos e fritos. No presente trabalho, ASNase foi covalentemente ligada ao polímero poli(etilenoglicol) (PEG) de diferentes massas moleculares (ASNase-PEG-5, ASNase-PEG- 10, ASNase-PEG-20, and ASNase-PEG-40) na região N-terminal (monoPEGuilação) a fim de se estudar os efeitos da PEGuilação na termoestabilidade da enzima. As formas PEGuiladas e nativa foram analisadas em relação à termodinâmica e termoestabilidade a partir de atividade enzimática. A ASNase (nativa e PEGuilada) apresentou atividade máxima a 40 °C e a desnaturação ocorreu por cinética de primeira ordem. Com base nesses resultados, a energia de ativação para desnaturação (E*d) foi estimada e maiores valores foram observados para as formas PEGuiladas em comparação à enzima nativa, destacando-se a ASNase-PEG10 com aumento de 4.24 vezes (48.85 kJ.mol-1) em comparação com a forma nativa in (11.52 kJ.mol mol-1). As enzimas foram avaliadas por sua atividade residual ao longo do tempo em diferentes temperaturas de armazenamento (4 e 37 °C) e os conjugados PEGuilados mostraram-se mais estáveis após os 21 dias de ensaio. Parâmetros termodinâmicos como entalpia (ΔH‡) de desnaturação irreversível foram analisados. Valores maiores - e ), entropia (ΔS‡) de desnaturação irreversível foram analisados. Valores maiores - e ) e energia livre de Gibbs (ΔG‡) de desnaturação irreversível foram analisados. Valores maiores - e positivos - da energia livre de Gibbs foram encontrados para os conjugados PEGuilados (61.21 a 63.45 kJ.mol-1), indicando que o processo de desnaturação não ocorreu de forma espontânea. A entalpia também foi maior para os conjugados PEGuilados (18.84 a 46.08 kJ.mol-1), demonstrando o efeito protetivo da PEGuilação. Já para a entropia, os valores negativos foram mais elevados para a ASNase nativa (-0.149 J/mol.K), apontando que o processo de desnaturação aumentou a aleatoriedade e agregação do sistema, o que foi confirmado pelo dicroísmo circular. Dessa forma, a PEGuilação revelou o seu potencial de aumento de termoestabilidade para a ASNase

PEGuilação do peptídeo Lunatina-1 visando novo candidato à fármaco antimicrobiano / PEGylation of the peptide Lunatin-1 aiming at novel candidate for antimicrobial drug

As infecções relacionadas à assistência à saúde (IRAS) podem ser causadas por bactérias, vírus e fungos, sendo de extrema importância para o sistema de tratamento e pacientes. Com o alarmante avanço no surgimento de bactérias resistentes, tem havido uma preocupação crescente com as IRAS de origem bacteriana. Nesse sentido, várias pesquisas buscam alternativas para os fármacos antimicrobianos convencionais, sendo que os peptídeos antimicrobianos (AMPs), como a lunatina-1, aparecem como moléculas promissoras. No entanto, os AMPs geralmente apresentam rápida degradação proteolítica no trato gastrointestinal e meia-vida curta na corrente sanguínea, principais fatores limitantes para sua aplicação no tratamento de IRAS. Entre as estratégias empregadas para superar esses inconvenientes, a PEGuilação apresenta-se como alternativa eficaz que aumenta o tempo de circulação in vivo dos AMPs, resultando na melhora farmacocinética e, em alguns casos, também farmacodinâmica. A PEGuilação consiste na ligação covalente de cadeias de polietileno glicol (PEG) ao peptídeo, que pode ser efetuada por meio de uma reação aleatória ou sítio-específica. Neste trabalho, desenvolveu-se uma PEGuilação sítio-específica no N-terminal da lunatina-1 empregando-se mPEG-NHS de 2 kDa em tampão fosfato 100 mM, visando o aumento da solibilidade deste peptídeo, bem como para avaliar sua ação antimicrobiana. Com relação à reação de PEGuilação, avaliou-se a influência da razão molar PEG:peptídeo (10:1 ou 15:1) a pH 8,5. Foi obtido um rendimento de PEGuilação de 92%, através da análise por RP-HPLC quantitativo. Quanto à purificação da lunatina-1 PEGuilada, foi empregada a técnica semi-preparativa de RP-HPLC utilizando a coluna C18. A caracterização da lunatina-1 PEGuilada, incluindo determinação do grau de PEGuilação, foi realizada por MALDI-TOF Autoflex Speed (Bruker), mostrando que a molécula foi monoPEGuilada na região N-terminal. A atividade antimicrobiana de lunatina-1 livre e bioconjugada frente a diferentes cepas bacterianas, sendo duas Gram-negativas (ATCC 25922 de Escherichia coli e ATCC 9027 de Pseudomonas aeruginosa) e uma Gram-positiva (CECT 239 de Staphylococcus aureus), foi estudada por determinação da concentração inibitória mínima (CIM) em microplaca, sendo que foram obtidos valores de CIM de 86 e 140 µM para o peptídeo liver e PEGuilado, respetivamente. O potencial hemolítico também foi estudado, sendo que a forma PEGuilada mostrou significativa redução da atividade hemolítica em comparação à forma livre. Em suma, a PEGuilação da lunatina-1, aumenta a sua solubilidade e reduz a atividade hemolítica. Porém, para viabilizar esta estratégia a PEGuilação deve ser reversível, pois a conjugação ao polímero reduz atividade antimicrobiana

Health care-related infections (HAIs) caused by bacteria, viruses and fungi are extremely important for patients and health systems. With the alarming advance in the emergence of resistant bacteria, a growing concern with HAIs of bacterial origin is observed. In this sense, several studies investigate alternatives to conventional antimicrobial drugs and antimicrobial peptides (AMPs), such as lunatin-1, appear as promising molecules. However, AMPs generally show rapid proteolytic degradation in the gastrointestinal tract and short half-life in the bloodstream, the main limiting factors for their therapeutic application to treat HAIs. Among the strategies used to overcome these drawbacks, PEGylation presents itself as an effective alternative that increases the in vivo circulation time of AMPs, resulting in improved pharmacokinetics and, in some cases, also pharmacodynamics. PEGylation consists on the covalent attachment of polyethylene glycol (PEG) chains to the peptide, which can be carried out by means of a random or site-specific reaction. In this work, a site-specific PEGylation was developed at the N-terminus of lunatin-1 using 2 kDa mPEG-NHS to increase the solubility of this peptide, as well as to evaluate its antimicrobial activity. Regarding the PEGylation reaction, the influence of the molar ratio PEG: peptide (10: 1 or 15: 1) at pH 8.5 was evaluated and a PEGylation yield of 92% was obtained, based on quantitative RP-HPLC analysis. As for the purification of PEGylated lunatin-1, semi-preparative RP-HPLC was used. The characterization of PEGylated lunatin-1, including determination of the degree of PEGylation, was performed by MALDI-TOF Autoflex Speed (Bruker), showing that the peptide was monoPEGylated in the N-terminal region. The antimicrobial activity of free and bioconjugated lunatin-1 against different bacterial strains, two Gram-negative (ATCC 25922 from Escherichia coli and ATCC 9027 from Pseudomonas aeruginosa), and one Gram positive (CECT 239 from Staphylococcus aureus), was studied by determining the minimum inhibitory concentration (MIC) in a microplate, resulting in MIC values of 86 and 140 µM for the free and PEGylated peptide, respectively. The hemolytic potential was also studied and the PEGylated form showed a significant reduction in hemolytic activity compared to the free form. In short, the PEGylation of lunatin-1 increases its solubility and reduces hemolytic activity. However, to make this strategy feasible, PEGylation must be reversible, since the conjugation to the polymer reduces antimicrobial activity

Funcionalização do polietilenoglicol metil éter via reação de bromoacetilação: ativação, caracterização por MALDI-TOF e mecanismo de reação / Poly(ethylene glycol) methyl ether functionalization by bromoacetylation reaction: Activation, characterization by MALDI-TOF and reaction mechanism / Funcionalización de polietilenglicol metil éter mediante reacción de bromoacetilación: activación, caracterización por MALDI-TOF y mecanismo de reacción

Resumo A PEGuilação, reação química de conjugação com a molécula de polietilenoglicol (PEG) ou polietilenoglicol metil éter (mPEG), tem sido amplamente aplicada pelas indústrias farmacêuticas como estratégia de melhoria das propriedades farmaco-cinéticas de compostos bioativos. O PEG é um polímero que possui um esqueleto de poliéter quimicamente inerte e que apresenta grupos hidroxilas (-OH) em suas extremidades. Assim, o PEG para tornar-se apto como reagente de conjugação deve ser ativado com um grupo funcional que seja reativo. Nesse sentido, a bromoaceti-lação apresenta-se como uma alternativa para a funcionalização do PEG. Portanto, nesse trabalho objetivamos descrever em detalhes os procedimentos e o mecanismo de reação envolvida na funcionalização do mPEG, através da reação de bromoacetilação. Além do mais, estudamos a aplicação do MALDI-ToF para a caracterização do produto ativado. Após a bromoacetilação, por um procedimento adaptado, obteve-se o bromoacetil-mPEG-éster, com rendimento bruto de 56,78%. Análises posteriores, por espectrometria de massas por MALDI-ToF, possibilitaram identificar e caracterizar o produto bromoacetilado. Entre as condições de reação, o controle de temperatura (-10 °C a 0 °C) mostrou-se eficaz favorecendo a adição nucleofílica essencial à bromoacetilação. Assim, concluímos que o controle da baixa temperatura reacional é um fator chave para o favorecimento da adição nucleofílica à carbonila e, portanto, essencial na obtenção do mPEG funcionalizado via bromoacetilação. Estudos posteriores serão necessários, no entanto, para confirmar se o mPEG esterificado, nessas condições, poderá ser utilizado na conjugação com moléculas de natureza proteica ou peptídica, por meio de substituição nucleofílica bimolecular.

SUMMARY PEGylation, a chemical reaction of conjugation with the polyethylene glycol molecule (PEG), has been widely applied by the pharmaceutical industries as a strategy to improve the pharmacokinetic properties of bioactive compounds. PEG is a polymer that has a chemically inert polyether backbone and hydroxyl groups (-OH) at its ends. Thus, PEG to become fit as a reagent for conjugation must be activated with a functional group that is reactive. In this sense, bromoacetylation presents itself as an alternative for the functionalization of PEG. Therefore, in this study we aim to describe in detail the procedures and reaction mechanism involved in the functionalization of mPEG through the bromoacetylation reaction. In addition, we used the spectrometric technique, by MALDI-ToF, for the characterization of the activated product. After applying an adapted bromoacetylation procedure, bromoacetyl-mPEG-ester was obtained with a yield of 56.78%. Subsequent analyzes of MALDI-ToF mass spectrometry were able to correctly identify and characterize the bromoacety-lated product. Among the reaction conditions, temperature control (from -10 °C to 0 °C) was effective in favoring the essential nucleophilic addition to bromoacetylation. Thus, we conclude that the control of the low reaction temperature is a key factor in favoring the nucleophilic addition to carbonyl and, therefore, obtaining a favorable conversion to functionalized PEG via bromoacetylation. Further studies, however, will be necessary to confirm whether PEG esterified with these conditions can be used in conjunction with molecules of a protein or peptide nature by means of bimolecular nucleophilic substitution.

RESUMEN La PEGilación, una reacción química de conjugación con la molécula de polietilenglicol (PEG), ha sido ampliamente aplicada por las industrias farmacéuticas como una estrategia para mejorar las propiedades farmacocinéticas de los compuestos bioactivos. El PEG es un polímero formado por un esqueleto de poliéter químicamente inerte con grupos hidroxilo (-OH) en sus extremos. Por lo tanto, para usar el PEG como reactivo de conjugación debe activarse con un grupo funcional que sea reactivo. En este sentido, la bromoacetilación es una alternativa para la funcionalización de PEG. De esta manera, en este trabajo nuestro objetivo es describir en detalle los procedimientos y el mecanismo de reacción involucrados en la funcionalización de PEG a través de la reacción de bromoacetilación. Además, estudiamos la aplicación de MALDI-ToF para la caracterización del producto activado. Después de aplicar un procedimiento de bromoacetilación adaptado, se obtuvo bromoacetil-mPEG-éster con un rendimiento bruto de 56,78%. Los análisis posteriores de espectrometría de masas por MALDI-ToF pudieron identificar y caracterizar correctamente el producto bromoacetilado. Entre las condiciones de reacción, el control de la temperatura (desde -10 °C hasta 0 °C) fue eficaz para favorecer la adición nucleofílica esencial a la bromoacetilación. Así, concluimos que el control de la baja temperatura de reacción es un factor clave para favorecer la adición nucleofílica al carbonilo y, por lo tanto, esencial para obtener el mPEG funcionalizado mediante la bromoacetilación. Sin embargo, serán necesarios más estudios para confirmar si el mPEG esterificado en estas condiciones puede usarse junto con moléculas de naturaleza proteica o peptídica por medio de la sustitución nucleófila bimolecular.

Site-specific monoPEGylated interferon alpha2a mediated by microbial transglutaminase / 生物工程学报

PEGylation is considered one of the most successful techniques to improve the characteristics of protein drugs including to increase the circulating half-life of proteins in blood and to decrease their immunogenicity and antigenicity. One known PEG modification method is to attach PEG to the free amino group, typically at lysine residues or at the N-terminal amino acid with no selectivity, resulting in a heterogeneous product mixture. This lack of selectivity can present problems when a therapeutic PEGylated protein is being developed, because predictability of activity and manufacturing reproducibility are needed for regulatory approval. Enzymatic PEGylation of proteins is one route to overcome this limitation. Transglutaminases (TGase) are enzyme candidates for site-specific PEGylation. We use human interferon alpha 2a (IFN α2a) as a test case, and predict that the potential modification residues are Gln101 by computational approach as it contains 12 potential PEGylation sites. IFN α2a was PEGylated by Y shaped PEG40k-NH2 mediated by microbial transglutaminase. Our results show that the microbial transglutaminase mediated PEGylation of IFN α2a was site-specific only at the site of Gln101 in IFN α2a, yielding the single mono-conjugate PEG-Gln101-IFN α2a with a mass of 59 374.66 Da. Circular dichroism studies showed that PEG-Gln101-IFN α2a preserved the same secondary structures as native IFN α2a. As expected, the bioactivity and pharmacokinetic profile in rats of PEG-Gln101-IFN α2a revealed a significant improvement to unmodified IFN α2a, and better than PEGASYS.

A single-center, randomized controlled trial of PEG-rhG-CSF and common rhG-CSF to promote neutrophil recovery after induction chemotherapy in newly diagnosed acute myeloid leukemia / 中华血液学杂志

Objective@#To compare the time of the recovery of neutrophils or leukocytes by pegylated recombinant human granulocyte stimulating factor (PEG-rhG-CSF) or common recombinant human granulocyte stimulating factor (rhG-CSF) in the myelosuppressive phase after induction chemotherapy in newly diagnosed acute myeloid leukemia (AML) patients. At the same time, the incidences of infection and hospitalization were compared.@*Methods@#A prospective randomized controlled trial was conducted in patients with newly diagnosed AML who met the enrollment criteria from August 2014 to December 2017. The patients were randomly divided into two groups according to a 1:1 ratio: PEG-rhG-CSF group and rhG-CSF group. The time of neutrophil or leukocyte recovery, infection rate and hospitalization interval were compared between the two groups.@*Results@#60 patients with newly diagnosed AML were enrolled: 30 patients in the PEG-rhG-CSF group and 30 patients in the rhG-CSF group. There were no significant differences in age, chemotherapy regimen, pre-chemotherapy ANC, WBC, and induction efficacy between the two groups (P>0.05) . The median time (range) of ANC or WBC recovery in patients with PEG-rhG-CSF and rhG-CSF were 19 (14-35) d and 19 (15-26) d, respectively, with no statistical difference (P=0.566) . The incidences of infection in the PEG-rhG-CSF group and the rhG-CSF group were 90.0%and 93.3%, respectively, and there was no statistical difference (P=1.000) . The median days of hospitalization (range) was 20.5 (17-49) days and 21 (19-43) days, respectively, with no statistical difference (P=0.530) .@*Conclusions@#In AML patients after induction therapy, there was no significant difference between the application of PEG-rhG-CSF and daily rhG-CSF in ANC or WBC recovery time, infection incidence and hospitalization time.

PEGylation strategy to the development of analytical and therapeutic proteins / Potencial da PEGuilação para o desenvolvimento de proteínas para fins terapêuticos e analíticos

Protein PEGylation is the covalent bonding of polyethylene glycol (PEG) polymers to amino acid residues of the protein and it is one of the most promising techniques for improving the therapeutic effect of biopharmaceuticals and long-term stability of protein-based biosensors. This chemical modification brings advantages to biopharmaceuticals, such as an increased half-life, enhanced stability, and reduced immunogenicity. Moreover, in the analytical field, PEGylation improves the multiple properties of protein-based biosensors including biocompatibility, thermal and long-term stability, and solubility in organic solvents. However, the use of PEGylated conjugates in the analytical and therapeutic fields has not been widely explored. The limited industrial application of PEGylated bioconjugates can be attributed to the fact that the reaction and separation steps are currently a challenge. The correct selection of the PEGylation reaction design and the purification process are important challenges in the field of bioconjugation. In this sense, the design and optimization of site-specific PEGylation reactions and application of aqueous biphasic systems (ABS) as purification platforms for PEGylated conjugates are the two main objectives of this thesis. Regarding the purification step, the efficient fractionation (i) of the PEGylated conjugates from the native protein and (ii) of the PEGylated conjugates based on their degree of PEGylation was studied. Centrifugal partition chromatography (CPC) was applied as a continuous regime platform based on ABS technology to efficiently purify the PEGylated proteins. The two proteins under study are L-asparaginase, an important biopharmaceutical applied in the treatment of acute lymphoblastic leukemia and cytochrome c, a promising biosensor. The current work developed in this thesis demonstrates the great potential of ABS in the fractionation of PEGylated proteins, under batch and continuous regime. In addition, in situ recovery of the PEGylated products through one-pot bioconjugation and ABS purification was successfully demonstrated for both enzymes studied. Although further research on scale-up is still required, the results presented show the relevance of ABS platforms for the development of separation processes of PEGylated proteins

A PEGuilação de proteínas é a ligação covalente de polímeros de polietilenoglicol (PEG) a resíduos de aminoácidos da proteína e é uma das técnicas mais promissoras para melhorar o efeito terapêutico dos biofármacos e a estabilidade a longo prazo de biossensores proteícos. Esta modificação química traz vantagens aos produtos biofarmacêuticos, como um aumento da meia-vida, maior estabilidade e imunogenicidade reduzida. Além disso, no campo analítico, a PEGuilação melhora as múltiplas propriedades dos biossensores baseados em proteínas, incluindo biocompatibilidade, estabilidade térmica e a longo prazo, e solubilidade em solventes orgânicos. No entanto, o uso de conjugados PEGuilados em campos analíticos e terapêuticos não tem sido amplamente explorado. A aplicação industrial limitada dos bioconjugados PEGuilados pode ser atribuída ao facto de as etapas de reacção e separação serem atualmente um desafio. A seleção correcta do design da reacção de PEGuilação e do processo de purificação são importantes desafios no campo da bioconjugação. Neste sentido, a concepção e otimização de reações de PEGuilação sítio-específicas e aplicação de sistemas aquosos bifásicos (ABS) como plataformas de purificação de conjugados PEGuilados são os dois principais objetivos desta tese. No que concerne à etapa de purificação foi estudado o eficiente fracionamento (i) dos conjugados PEGuilados, da proteína nativa e (ii) dos conjugados PEGuilados baseados no seu grau de PEGuilação. A cromatografia por partição centrífuga (CPC) foi aplicada como uma plataforma de regime contínuo baseada na tecnologia de ABS para purificar eficientemente as proteínas PEGuiladas. As duas proteínas em estudo são a L-asparaginase, importante biofármaco aplicado no tratamento da leucemia linfoblástica aguda e o citocromo c, um potencial biossensor. A partir dos trabalhos desenvolvidos, é possível confirmar o grande potencial dos ABS no fracionamento de proteínas PEGuiladas, em regime contínuo e descontínuo. Além disso, a recuperação in situ dos produtos PEGuilados através da integração em uma única etapa de bioconjugação e purificação por ABS foi comprovada com sucesso para ambas as enzimas estudadas. Embora ainda sejam necessários estudos adicionais sobre a viabilidade destes sistemas em larga escala, os resultados aqui apresentados demonstram a relevância dos ABS para o desenvolvimento de processos de separação de proteínas PEGuiladas

Protein PEGylation for the design of biobetters: from reaction to purification processes

The covalent attachment of polyethylene glycol (PEG) to therapeutical proteins is an important route to develop biobetters for biomedical, biotech and pharmaceutical industries. PEG conjugation can shield antigenic epitopes of the protein, reduce degradation by proteolytic enzymes, enhance long-term stability and maintain or even improve pharmacokinetic and pharmacodynamics characteristics of the protein drug. Nonetheless, correct information in terms of the PEGylation process from reaction to downstream processing is of paramount importance for the industrial application and processing scale-up. In this review we present and discuss the main steps in protein PEGylation, namely: PEGylation reaction, separation of the products and final characterization of structure and activity of the resulting species. These steps are not trivial tasks, reason why bioprocessing operations based on PEGylated proteins relies on the use of analytical tools according to the specific pharmaceutical conjugate that is being developed. Therefore, the appropriate selection of the technical and analytical methods may ensure success in implementing a feasible industrial process

Modification of mPEGylated novel bifunctional fusion protein GAD and its propenty / 中国药科大学学报

In order to solve the difficucties of renaturation and immunogenicity of new bifunctional fusion protein GAD,inclusion bodies of GAD were modified by PEG-maleimide.Conformational changes of the modified GAD were compared by circular dichroism and tryptophan fluorescence spectroscopy.The biological activity was verified by oral glucose tolerance test and lipid scavenging.The results showed that PEG-maleimide completed the specific-point modification of GAD,and improved its refolding efficiency.The secondary and tertiary structures of mPEGylated GAD were consistent with that of GAD.PEG-GAD has significant hypoglycemic and lipid-lowering effects (P ＜0.001) with longer half life in vivo and lower immunogenicity (P ＜0.01).This study provides effective strategies for the development of strongly hydrophobic peptide drugs.

Establishment of a pharmacokinetic detection method for PEGylated recombinant human interleukin-11 mutein in cynomolgus monkeys / 国际药学研究杂志

Objective To evaluate the pharmacokinetics, drug concentration and effect relationship of PEGylated IL-11 mutein (PEG-mIL11) in cynomolgus monkeys through the validated anti-PEG-ELISA method. Methods PEG-mIL11 at 350 μg/kg was subcutaneously injected in cynomolgus monkeys, and the blood samples were collected at various time points. An anti-PEG-ELISA method was validated and used to investigate the concentration of PEG-mIL11, and platelet counts were measured to explore the relationship of drug concentration and effect. Results Results of the validation test demonstrated that PEG-mIL11 in monkey blood could be quantitated by anti-PEG-ELISA. Its linear range was (26.34-200) ng/ml. The specificity, accuracy and precision of the method met the present criteria. The terminal elimination half-life (T1/2) of PEG-mIL11 was (13.4 ± 2.4) h, the peak time (Tmax) was (6.7 ± 2.3) h, the peak concentration (Cmax) was (2.4 ± 0.5) μg/ml, the area under curve (AUC)(0-t) was (77.7 ± 15.6) μg∙h/ml, and the clearance (CL) was (4.6 ± 0.8) ml/ (h·kg). The thrombopoietic effect did not relate directly with the concentration of PEG-mIL11 in serum. Conclusion Anti-PEG-ELISA, used in this study to measure the concentration of PEG-mIL11, is a steady, reliable and specific method for PEGmIL11 pharmacokinetic study, and its chemical modification by PEG possesses long circulating half-lives, thereby suggesting less frequency of administration.

In situ absorption kinetics of series molecular weight of PEGylated mesalazine in rats / 中国药理学通报

Aim To study the absorption kinetics of se-ries molecular weight 5-ASA-mPEG in rats intestine. Methods The in situ intestinal absorption property of 5-ASA-mPEG in rats was investigated by means of sin-gle-pass perfusion, and HPLC method was established to determine the drug concentration in the perfusate. Results The drug concentration and the site of intes-tine segments had little effect on the drug absorption constant ( Ka ) and apparent absorption coefficient (Papp). The perfusion flow rate and the variable mo-lecular weight of 5-ASA-mPEG could significantly af-fect the Ka and Papp. Conclusion 5-ASA-mPEG can be absorbed at all segments of the intestine of rats and has no specific absorption site. It is preliminarily in-ferred that the absorption mechanism of 5-ASA-mPEG is passive transportation. The intestinal absorption of 5-ASA-mPEG shows a downward trend with the increase in molecular weight. The results shows that the modifi-cation of 5-ASA by PEG can effectively inhibit the in-testinal absorption of mesalazine.

Establishment and verification of assay method for the receptor binding affinity of a PEGylated Exendin-4 analogue / 中国药科大学学报

@#The assay method of GLP-1 receptor binding affinity for a long-acting hypoglycemic peptide—PEgylated Exendin-4 analogue(PE)was optimized and established based on the luciferase reporter gene approach. CHO-GLP-1R-CRE-Luc+ cells were previously constructed in our lab followed by the verification of methodology. This assay method showed good specificity and robustness as well as high accuracy and precision when PE was incubated with the cell for 4 h, the luminescent substrate reacted with cell lysates for 15 min and the concentration for PE ranged 5. 7×10-3-1. 5×103 nmol/L, on which condition this developed method is in accordance with General Principles of Analytical Method Validation Techniques for Biological Products Quality Control. This study also lays the foundations for rapid evaluation and screening of GLP-1 receptor agonist drugs.

Multi-mode microwave assisted preparation of PEGylated polystyrene resin / 国际药学研究杂志

Objective: To study a method of microwave-assistant PEGylation of polystyrene resin. Methods: Modify the commercial Merrifield resin with PEG-200, and study the influence of the yield under different conditions. The self-prepared PEG resin was further derived to PEG-wang resin; kinds of amino acids were anchored, and the loading rates were compared with commercial wang resin. Result: A general series react conditions were preferred, which was performed with 5 g resin, 50 ml PEG-200. irradiating for 15 min×2 at 600 W, preset temperature was 170 °C. The resin was then transformed to PEGylated Wang resin and anchored with amino acids, the yields were satisfied. Conclusion: The multi-mode microwave assistant PEGylation of Merrifield resin method was first reported in this paper. This method has the advantages of simple operation, fast preparation, mild reaction conditions and good yield, which was much better than the traditional method.

Analysis of problems on tumor-targeting drug delivery system / 药学实践杂志

Objective To analyze the current problems on tumor‐targeting nanoparticle drug delivery system .Methods Recent researches of tumor‐targeting nanoparticle drug delivery system were collected ,read and summarized .Results Three research fields on tumor‐targeting nanoparticle drug delivery system were reviewed in this article .Conclusion Not only a deeper understanding of the human physiology and tumor biology ,but changes in strategies and experimental methods are needed to make new achievements on nanoparticle drug delivery system .

Multi-mode microwave assisted preparation of PEGylated polystyrene resin / 国际药学研究杂志

Objective To study a method of microwave-assistant PEGylation of polystyrene resin. Methods Modify the commercial Merrifield resin with PEG-200, and study the influence of the yield under different conditions. The self-prepared PEG resin was further derived to PEG-wang resin; kinds of amino acids were anchored, and the loading rates were compared with commercial wang resin. Result A general series react conditions were preferred, which was performed with 5 g resin, 50 ml PEG-200, irradiating for 15 min ×2 at 600 W, preset temperature was 170 ℃. The resin was then transformed to PEGylated Wang resin and anchored with amino acids, the yields were satisfied. Conclusion The multi-mode microwave assistant PEGylation of Merrifield resin method was first reported in this paper. This method has the advantages of simple operation,fast preparation, mild reaction conditions and good yield, which was much better than the traditional method.

Arthropod venom Hyaluronidases: biochemical properties and potential applications in medicine and biotechnology

Hyaluronidases are enzymes that mainly degrade hyaluronan, the major glycosaminoglycan of the interstitial matrix. They are involved in several pathological and physiological activities including fertilization, wound healing, embryogenesis, angiogenesis, diffusion of toxins and drugs, metastasis, pneumonia, sepsis, bacteremia, meningitis, inflammation and allergy, among others. Hyaluronidases are widely distributed in nature and the enzymes from mammalian spermatozoa, lysosomes and animal venoms belong to the subclass EC 3.2.1.35. To date, only five three-dimensional structures for arthropod venom hyaluronidases (Apis mellifera and Vespula vulgaris) were determined. Additionally, there are four molecular models for hyaluronidases fromMesobuthus martensii, Polybia paulista and Tityus serrulatus venoms. These enzymes are employed as adjuvants to increase the absorption and dispersion of other drugs and have been used in various off-label clinical conditions to reduce tissue edema. Moreover, a PEGylated form of a recombinant human hyaluronidase is currently under clinical trials for the treatment of metastatic pancreatic cancer. This review focuses on the arthropod venom hyaluronidases and provides an overview of their biochemical properties, role in the envenoming, structure/activity relationship, and potential medical and biotechnological applications.(AU)

Arthropod venom Hyaluronidases: biochemical properties and potential applications in medicine and biotechnology

Hyaluronidases are enzymes that mainly degrade hyaluronan, the major glycosaminoglycan of the interstitial matrix. They are involved in several pathological and physiological activities including fertilization, wound healing, embryogenesis, angiogenesis, diffusion of toxins and drugs, metastasis, pneumonia, sepsis, bacteremia, meningitis, inflammation and allergy, among others. Hyaluronidases are widely distributed in nature and the enzymes from mammalian spermatozoa, lysosomes and animal venoms belong to the subclass EC 3.2.1.35. To date, only five three-dimensional structures for arthropod venom hyaluronidases (Apis mellifera and Vespula vulgaris) were determined. Additionally, there are four molecular models for hyaluronidases fromMesobuthus martensii, Polybia paulista and Tityus serrulatus venoms. These enzymes are employed as adjuvants to increase the absorption and dispersion of other drugs and have been used in various off-label clinical conditions to reduce tissue edema. Moreover, a PEGylated form of a recombinant human hyaluronidase is currently under clinical trials for the treatment of metastatic pancreatic cancer. This review focuses on the arthropod venom hyaluronidases and provides an overview of their biochemical properties, role in the envenoming, structure/activity relationship, and potential medical and biotechnological applications.

Progress in study on difficulties of quality control of PEGylated UOX / 中国药学杂志

PEGylated UOX is a kind of modified pharmaceuticals designed by coupling PEG with UOX to increase in vivo circulation half-life and reduce immunogenicity. UOX is modified by PEG at random multiple sites, which results in more complicated physical and chemical characteristics and in vivo and in vitro activities than UOX. At present, there is no standardized quality analysis method for such drugs. Through collecting and summarizing references about the quality control method of PEG-modified drugs in recent years, this article summarizes the analysis methods for three difficulties of the quality control of UOX namely the average extent of modification, consistency of modification and PEGylation sites so as to provide technical guidance for enterprises to develop the drug.