Peptide-related factors |
Peptide Hydrophobicity |
Peptide with high hydrophobicity is difficult to dissolve, but easier to gelate. |
(Banwell et al, 2009)32
|
Composition of Amino Acids |
Peptides with high ratio of hydrophobic residues form hydrogels with better mechanical properties. |
(Lutolf et al, 2003)33
|
Peptide Concentration |
Higher concentration benefits gelling. |
(Hauser and Zhang, 201021; Du et al, 201512) |
Peptide Length |
Longer peptide benefits gelling. |
(Fletcher et)35
|
Amino Acid Chirality |
D-peptide-based hydrogel is more stable than natural L-amino acid-based peptide. |
(Schutz et al, 2015)12
|
Peptides with Capped N- and C-Terminals |
Peptides with capped N- and C-Terminals benefit gelling. |
(Solaro, 2010)36
|
Environment-related factors |
Salt |
Salt changes the ionic strength, thus inducing noncovalent interactions among peptides. |
(Ozbas et al, 200438; Feng et al, 201237) |
Temperature |
Heating and cooling achieve highly ordered hydrogel, especially entropy-driven assembled hydrogel. |
Du et al, 201512
|
Sonication |
Ultrasound breaks self-locked intramolecular hydrogen bonds or π stacking, and interlocked structures between peptide and water molecule are formed. |
(Yokoi et al, 200541; Pappas et al, 201540) |
pH |
pH can affect protonation/deprotonation of basic or acidic groups in peptide. |
(Hutchinson etal, 201942; Lopez-Silva etal, 2019)30
|
Photochemical |
Photo affects the gelling ability inhibited by photo-reactive groups. |
(Collier et al, 2001)43
|
Enzyme |
Enzyme cleaves the enzyme-sensitive peptide to remove peptide-inhibited gelation and accelerates the degradation of SAP hydrogel. |
(Lian et al, 2016)44
|