Wine Chemistry and Biochemistry

(Steven Felgate) #1

134 R. Marchal and P. Jeandet


caused by cold stabilization is why some winemakers decide to fine with bentonite


during or following potassium bitartrate stabilization. In certain wines, free tartaric


acid can be complexed with proteins and polyphenolics, inhibiting potassium bitar-


trate crystal formation. Removal of a portion of these complexing compounds with


bentonite can enhance potassium bitartrate stability. Additionally, bentonite fining


of wines during cold stabilization allows potassium bitartrate crystals to compact


the bentonite lees.


However, because the use of bentonite alters the organoleptic characteristics


of wines (Lubbers et al. 1996; Main and Morris 1994; Miller et al. 1985), other


authors have searched for alternative treatments for the use of bentonites, particu-


larly mannoproteins (see Sect. 5.3).


5.1.2 Use of Gelatin in White Wine Fining


The primary reaction occurring with gelatin is a complex formation between poly-


phenols in the wine and the protein of gelatine to give the desired floccular precipi-


tate. The second reaction, less well understood but equally important, is the complex


formation between the natural wine proteins and the added protein, i.e. gelatin.


5.1.2.1 The Nature of Gelatin


Gelatin is prepared from derived sources of collagen. Gelatin is a protein, that is,


a polymer of amino acids joined together by peptide bonds. Hence, proteins can


be depicted as long molecules with many different side chains, which accounts for
their varying properties. Proline, that is, a very important amino acid of gelatin,


imparts a twist to the chain and affects the shape of the protein molecule and its


rigidity. The protein chain is amphoteric and can carry either a positive or a negative


charge depending on the pH of the medium. In wine and beverages at a pH of 2.9–


3.6, most of the amino groups are positively charged and most of the acidic groups


are uncharged. The molecule then behaves as a cation. It attracts and forms polar


associates with anions in solution. In addition, proteins form associations due to


hydrogen bonding using the negatively charged oxygen and nitrogen atoms in the


molecules.


The isoelectric point (pI) of a protein is the pH at which the protein will not


migrate in an electric field. At that pH, the molecule carries an equality of positive


and negative charges: the molecule is isoionic, in the absence of added ions other


than hydrogen and hydroxyl ions in solution. Gelatin, is rather unique in that it


can have an isoelectric point anywhere between pH 9 and pH 5, depending upon


the source and method of production. Gelatins used in enology are usually derived


from acid pre-treated pigskin (Type A) and have isoelectric points between 6 and 9.


Gelatins with a high gel strength (Bloom strength) have the higher pI and gelatins


with a low Bloom strength have a pI closer to 6. Some enological gelatins sometimes


derived from limed hide or limed ossein (Type B gelatins) and all of them have a pI


close to 5. The significance of pI is, of course, that the higher the pI, the greater the

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