Abstract
Natural rubber (NR) contains cis-1,4-polyisoprene as well as a small quantity of non-rubber components, affecting the physical properties of NR, especially the storage hardening via gel formation. The free and/or linked non-rubber components were removed from NR by various treatments. The origin of gel formation in NR mainly resulted from proteins, which could be removed by enzymatic deproteinisation, surfactant washing or saponification treatment, and partly from phospholipids linked to NR molecule via H-bonding, which were decomposed by saponification or polar solvent treatment. The effect of the non-rubber components in NR on storage hardening was investigated by an accelerated storage hardening test (ASHT). The crude NR (CNR) containing proteins and lipids clearly showed the increase of gel content, suggesting the formation of crosslink structure during storage, resulting in the high plasticity number and Mooney viscosity after the ASHT. The gel content in protein-free NR did not change significantly only in washed NR (WSNR), but increased in the enzymatic deproteinised NR (DPNR). This resulted from the presence of residual proteins, such as oligopeptides. Interestingly, the gel content also reduced in the acetone extracted CNR (AE-CNR) and there was no significant effect on the storage hardening after ASHT, like WSNR. These were supposed to be due to the interaction or the participation of proteins and free fatty acids in the branching formation. Although the saponification could be decomposed branching at both terminal ends of the NR molecule, the protein and lipid residues occluded in the saponified NR (SPNR) affected the storage hardening. However, the flocculant remaining in the SPNR coagulated with acid and flocculant (AF-SPNR) would obstruct both gel formation and storage hardening.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Tanaka Y (2001) Structural characterization of natural polyisoprenes: solve the mystery of natural rubber based on structural study. Rubber Chem Technol 74:355–375
Sriring M, Nimpaiboon A, Kumarn S, Sirisinha C, Sakdapipanich J, Toki S (2018) Viscoelastic and mechanical properties of large- and small-particle natural rubber before and after vulcanization. Polym Test 70:127–134
Tarachiwin L, Sakdapipanich J, Ute K, Kitayama T, Bamba T, Fukusaki E, Kobayashi A, Tanaka Y (2005) Structural characterization of α-terminal group of natural rubber. 1. Decomposition of branch-points by lipase and phosphatase treatment. Biomacromol 6:1851–1857
Mekkriengkrai D, Sakdapipanich JT, Tanaka Y (2006) Structural characterization of terminal groups in natural rubber: origin of nitrogenous groups. Rubber Chem Technol 79:366–379
Nawamawat K, Sakdapipanich JT, Ho CC, Ma Y, Song J, Vancso JG (2011) Surface nanostructure of Hevea brasiliensis natural rubber latex particles. Colloids Surf A 390:157–166
Sakdapipanich JT, Tanaka Y, Jacob JL, d'Auzac J (1999) Characterization of Hevea brasiliensis rubber from virgin tree: a possible role of cis-polyisoprene in unexploited tree. Rubber Chem Technol 72:299–307
Yunyongwattanakorn J, Sakdapipanich JT (2006) Physical property changes in commercial natural rubbers during long term storage. Rubber Chem Technol 79:72–81
Yunyongwattanakorn J, Tanaka Y, Kawahara S, Klinklai W, Sakdapipanich J (2003) Effect of non-rubber components on storage hardening and gel formation of natural rubber during accelerated storage under various conditions. Rubber Chem Technol 76:1228–1240
Sekhar BC (1958) Aeration of natural rubber latex. I. Effect of polyamines on the hardness and aging characteristics of aerated latex rubber. Rubber Chem Technol 31(3):425–429
Burfield DR (1974) Epoxy groups responsible for crosslinking in natural rubber. Nature 249:29–30
Burfield DR, Chew LC, Gan SN (1976) Distribution of abnormal groups in natural rubber. Polymer 17(8):713–716
Gregg EJ, Macey J (1973) The relationship of properties of synthetic poly(isoprene) and natural rubber in the factory. The effect of non-rubber constituents of natural rubber. Rubber Chem Technol 46(1):47–66
Amnuaypornsri S, Tarachiwin L, Sakdapipanich JT (2010) Character of long-chain branching in highly purified natural rubber. J Appl Polym Sci 115:3645–3650
Tarachiwin L, Sakdapipanich J, Ute K, Kitayama T, Tanaka Y (2005) Structural characterization of α-terminal group of natural rubber. 2. Decomposition of branch-points by phospholipase and chemical treatments. Biomacromol 6:1858–1863
Rolere S, Bottier C, Vaysse L, Sainte-Beuve J, Bonfils F (2016) Characterisation of macrogel composition from industrial natural rubber samples: influence of proteins on the macrogel crosslink density. Express Polym Lett 10(5):408–419
Sekhar BC (1962) Inhibition of hardening in natural rubber. Rubber Chem Technol 35(4):889–895
Nimpaiboon A, Sriring M, Sakdapipanich JT (2016) Molecular structure and storage hardening of natural rubber: insight into the reactions between hydroxylamine and phospholipids linked to natural rubber molecule. J Appl Polym Sci 133:43753. https://doi.org/10.1002/app.43753
Wadeesirisak K, Castano S, Berthelot K, Vaysse L, Bonfils F, Peruch F, Rattanaporn K, Liengprayoon S, Lecomte S, Bottier C (2017) Rubber particle proteins REF1 and SRPP1 interact differently with native lipids extracted from Hevea brasiliensis latex. Biochim Biophys Acta 1859:201–210
Nawamawat K, Sakdapipanich J, Ho CC (2010) Effect of deproteinized methods on the proteins and properties of natural rubber latex during storage. Macromol Symp 288:95–103
Kawahara S, Klinklai W, Kuroda H, Isono Y (2004) Removal of proteins from natural rubber with urea. Polym Adv Technol 15:181–184
Amnuaypornsri S, Sakdapipanich J, Tanaka Y (2010) Highly purified natural rubber by saponification of latex: Analysis of green and cured properties. J Appl Polym Sci 118:3524–3531
Thuong NT, Nghia PT, Kawahara S (2018) Factors influencing green strength of commercial natural rubber. Green Process Synth 7:399–403
Monadjemi SMA, McMahan CM, Cornish K (2016) Effect of non-rubber constituents on guayule and Hevea rubber intrinsic properties. J Res Updates Polym Sci 5:87–96
Bonfils F, Ehabe EE, Aymard C, Vaysse L, Sainte-Beuve J (2007) Enhanced solvent extraction of polar lipids associated with rubber particles from Hevea brasiliensis. Phytochem Anal 18:103–108
Xu T, Lin J, Luo Y, Fu W, Jia Z, Jia D, Peng Z (2018) Determination of molecular structures of acetone solutes from natural rubber by pyrolysis gas chromatography coupled to mass spectroscopy. Chromatographia 81:1085–1096
Xu T, Lin J, Luo Y, Fu W, Jia Z, Jia D, Peng Z (2018) Quantitative analysis of higher fatty acids in acetone solutes (AS) from raw natural rubber and their impacts on the structure and properties of NR/silica composites. Ind Crops Prod 121:80–89
Nun-anan P, Wisunthorn S, Pichaiyut S, Nathaworn CD, Nakason C (2020) Influence of nonrubber componets on properties of unvulcanized natural rubber. Polym Adv Technol 31:44–59
Xu T, Jia Z, Wu L, Chen Y, Luo Y, Jia D, Peng Z (2017) Effect of acetone extract from NR on the structure and interface interaction in NR/CB composites. R Soc Chem 7:26458–26467
Tangpakdee J, Tanaka Y (1997) Characterization of sol and gel in Hevea natural rubber. Rubber Chem Technol 70:707–713
ISO/TS 289-4 (2017) Rubber, unvulcanised—determinations using a shearing-disc viscometer—part 4: determination of the Mooney stress-relaxation rate
ISO 2930 (2017) Rubber, raw natural—determination of plasticity retention index (PRI)
Bottier C (2020) Biochemical composition of Hevea brasilliensis latex: a focus on the protein, lipid, carbohydrate and mineral contents. In: Nawrot R (ed) Latex, laticifers and their molecular components: from functions to possible applications, Advance in botanical research, vol 93. Academic Press, Londres, pp 201–237
Amnuaypornsri S, Nimpaiboon A, Sakdapipanich J (2009) Role of phospholipids and proteins on gel formation and physical properties of NR during accelerated storage. Kautsch Gummi Kunstst 62:88–92
Rojruthai P, Tarachiwin L, Sakdapipanich JT, Tanaka Y (2009) Phospholipids associated with NR molecules inducing long-chain branching, part II analysis of phospholipids. Kautsch Gummi Kunstst 62:399–404
Acknowledgements
The authors gratefully acknowledge Mahidol University and the Center of Excellence for Innovation in Chemistry (PERCH-CIC), Ministry of Higher Education, Science, Research and Innovation. Sincere appreciation is extended to the Thai Rubber Latex Group Public Co., Ltd. for supplying NR latex.
Funding
The Center of Excellence for Innovation in Chemistry (PERCH-CIC), Ministry of Higher Education, Science, Research and Innovation.
Author information
Authors and Affiliations
Contributions
The manuscript was written through contributions of all authors. All authors have given approval to the final version of the manuscript.
Corresponding author
Ethics declarations
Conflict of interest
The authors declare no competing financial interest.
Additional information
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
About this article
Cite this article
Rojruthai, P., Kantaram, T. & Sakdapipanich, J. Impact of non-rubber components on the branching structure and the accelerated storage hardening in Hevea rubber. J Rubber Res 23, 353–364 (2020). https://doi.org/10.1007/s42464-020-00063-7
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s42464-020-00063-7