Extending Insulin Action in Vivo by Conjugation to Carboxymethyl Dextran

Baudyš, Miroslav; Letourneur, Didier; Liu, Feng; Mix, D.; Jozefonvicz, J.; Kim, Sung Wan

doi:10.1021/bc970180a

Cited by 38 publications

(24 citation statements)

References 33 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Other examples include dextran conjugates of asparaginase, carboxypeptidase G 2 , and hemoglobin, respectively, as well as CMD‐insulin conjugates …”

Section: Carbohydrate Polymersmentioning

confidence: 99%

Half‐Life Extension of Biopharmaceuticals using Chemical Methods: Alternatives to PEGylation

2016

View full text Add to dashboard Cite

Peptides and proteins constitute a vast pool of excellent drug candidates. Evolution has equipped these molecules with superior drug-like properties such as high specificity and potency. However, native peptides and proteins suffer from an inadequate pharmacokinetic profile, and their outstanding pharmacological potential can only be realized if this issue is addressed during drug development. To overcome this challenge, a variety of half-life extension techniques relying on covalent chemical modification have been developed. These methods include PEGylation, fusion to unstructured polypeptide-based PEG mimetics, conjugation of large polysaccharides, native-like glycosylation, lipidation, fusion to albumin or the Fc domain of IgG, and derivatization with bio-orthogonal moieties that direct self-assembly. This review provides an overview of available conjugation chemistries, biophysical properties, and safety data associated with these concepts. Moreover, the effects of these modifications on peptide and protein pharmacokinetics are demonstrated through key examples.

show abstract

“…Other examples include dextran conjugates of asparaginase, carboxypeptidase G 2 , and hemoglobin, respectively, as well as CMD‐insulin conjugates …”

Section: Carbohydrate Polymersmentioning

confidence: 99%

Half‐Life Extension of Biopharmaceuticals using Chemical Methods: Alternatives to PEGylation

2016

View full text Add to dashboard Cite

show abstract

“…For example, native insulin was typically released when the insulin releasing mechanism involves matrix swelling, matrix disassembly or degradation. In the case of glucose binding competition induced insulin release, the working insulin released was typically an insulin modified with polymers, such as dextran-insulin conjugate, [93] or small molecules, such as succinyl amidophenyl glucopyranoside [32]. It is particularly important to examine the bioactivity of the modified insulin.…”

Section: Evaluation Of Grir Systemmentioning

confidence: 99%

“…It is particularly important to examine the bioactivity of the modified insulin. Reports show that conjugating dextran to insulin loses 60–90% of native insulin bioactivity [93,94]. Thus, a significantly higher molar dose of conjugated insulin has to be delivered than unmodified native insulin in achieving comparable glucose suppressive effect.…”

Section: Evaluation Of Grir Systemmentioning

confidence: 99%

Glucose-responsive insulin release: Analysis of mechanisms, formulations, and evaluation criteria

Yang

Cao

2017

Journal of Controlled Release

View full text Add to dashboard Cite

Diabetes mellitus has become one of the biggest medical challenges affecting millions of people globally. Alternative treatments for diabetes are currently being intensively investigated to improve the treatment efficacy and life qualities for diabetic patients. Glucose-responsive insulin release (GRIR) systems have exhibited tremendous potential to improve the normal glycemic control and to reduce the incidence of hyperglycemia and hypoglycemia, which further reduces potential complications in diabetic patients. In a given GRIR drug formulation, accuracy, response time, and reversibility of the GRIR functions are three key features enabling potential seamless control of blood glucose level. Nevertheless, there is significant challenge preventing current GRIR formulations from achieving them. This review article analyzes the most updated literature and provides insights on the impact of GRIR mechanisms, and formulations on these key features, and the relevant in vitro and in vivo evaluation methods to test these functions.

show abstract

“…Investigators have demonstrated a direct correlation between the M W of the coupled dextran and the increase in the conjugate's half-life [52]. Other examples of protein-dextran conjugates include: uricase [54], superoxide dismutase [55], insulin [56] and hemoglobin [57,58]. Readers can refer to Mehva's review for an exhaustive overview of all dextran conjugates, including those with low M W s [43].…”

Section: Dextranmentioning

confidence: 99%

Polymers for Protein Conjugation

Pasut

2014

Polymers

View full text Add to dashboard Cite

Polyethylene glycol (PEG) at the moment is considered the leading polymer for protein conjugation in view of its unique properties, as well as to its low toxicity in humans, qualities which have been confirmed by its extensive use in clinical practice. Other polymers that are safe, biodegradable and custom-designed have, nevertheless, also been investigated as potential candidates for protein conjugation. This review will focus on natural polymers and synthetic linear polymers that have been used for protein delivery and the results associated with their use. Genetic fusion approaches for the preparation of protein-polypeptide conjugates will be also reviewed and compared with the best known chemical conjugation ones.

show abstract

Extending Insulin Action in Vivo by Conjugation to Carboxymethyl Dextran

Cited by 38 publications

References 33 publications

Half‐Life Extension of Biopharmaceuticals using Chemical Methods: Alternatives to PEGylation

Half‐Life Extension of Biopharmaceuticals using Chemical Methods: Alternatives to PEGylation

Glucose-responsive insulin release: Analysis of mechanisms, formulations, and evaluation criteria

Polymers for Protein Conjugation

Contact Info

Product

Resources

About