Alkali-free method of hide preparation for tanning

Valeika, V.; Beleska, K.; Sirvaityte, J.

doi:10.1590/S0104-66322012000200012

Abstract

Usually, beamhouse processes are carried out by varying a medium from strongly alkaline (unhairing-liming) up to strongly acid (pickling). This study is designed to develop a preparation of hide for tanning via processes that avoid a sharp change of hide pH. Enzymes active in acid medium are employed for hide unhairing in a buffer system containing 2.5% acetic acid and 0.3% sodium acetate. An oxidative treatment with peracetic acid then allows the complete removal of residual hair and scud. During both processes, unhairing and oxidative treatment, the opening of the derma structure occurs: 13.3-14.6g of non-collagen proteins are removed and amount of dermatan sulphate decreases by 35%. The hide obtained can be chromed directly after the above processes and subsequent treatment with sodium chloride solution omitted conventional pickling. The pH of the hide varies in the range of 8.3-3.7 during the processes of preparation for tanning.

Hide; Unhairing; Enzyme; Peracetic acid; Dermatan sulphate; Leather

KINETICS AND CATALYSIS; REACTION ENGINEERING; AND MATERIALS SCIENCE

Alkali-free method of hide preparation for tanning

V. ValeikaI,^* * To whom correspondence should be addressed ; K. Beleska^II; J. Sirvaityte^II

^IDepartment of General Chemistry, Faculty of Chemical Technology, Kaunas University of Technology, Phone: + 370 37 300189, Fax: + 370 37 300152, Radvilėnų pl. 19, Kaunas LT-50254, Lithuania

^IIDepartment of Organic Technology, Faculty of Chemical Technology, Kaunas University of Technology, Radvilėnų pl. 19, Kaunas LT-50254, Lithuania. E-mail: virgilijus.valeika@ktu.lt

ABSTRACT

Usually, beamhouse processes are carried out by varying a medium from strongly alkaline (unhairing-liming) up to strongly acid (pickling). This study is designed to develop a preparation of hide for tanning via processes that avoid a sharp change of hide pH. Enzymes active in acid medium are employed for hide unhairing in a buffer system containing 2.5% acetic acid and 0.3% sodium acetate. An oxidative treatment with peracetic acid then allows the complete removal of residual hair and scud. During both processes, unhairing and oxidative treatment, the opening of the derma structure occurs: 13.3-14.6g of non-collagen proteins are removed and amount of dermatan sulphate decreases by 35%. The hide obtained can be chromed directly after the above processes and subsequent treatment with sodium chloride solution omitted conventional pickling. The pH of the hide varies in the range of 8.33.7 during the processes of preparation for tanning.

Keywords: Hide; Unhairing; Enzyme; Peracetic acid; Dermatan sulphate; Leather.

INTRODUCTION

An unhairing method that removes intact hairs is better than hair degradation methods from an environmental point of view due to less pollution of tannery wastewater by products of hair degradation and chemicals. Secondly, such a method decreases the process duration and saves the valuable raw material: hair. More and more often, various enzymes are used for intact hair removal (Foroughi et al., 2006; Priya et al., 2008; Sivasubramanian et al., 2008; Valeika et al., 2009; Dettmer et al., 2011). Usually, these enzymes are active in alkaline medium.

The use of enzymes for various leather manufacturing processes is very relevant, especially for developing environmentally clean technologies. The advantages of the use of enzymes for intact hair removal in comparison with hair degradation unhairing are as follows: shorter process duration, better opening of the derma structure, fast removal of dermatan sulphate (Madham et al., 2010), faster penetration of chromium and shorter chroming time (Saravanabhavan et al., 2003), and the leather obtained is softer and has a cleaner grain.

The main aim of unhairing with enzymes is to sufficiently weaken the bond of hair with derma by degrading the epidermis and ensuring the quality of the unhaired hide and the intact hairs (Crispim and Mota, 2003).

The problem is that, after enzymatic unhairing, some hair, scud, and epidermis always remain. Additional chemical materials must then be used to remove the mentioned residuals.

Previous investigations have shown that fresh hide can be unhaired by the hide's enzymes, which are activated by organic acid (Sivaparvathi et al., 1974; Sivaparvathi et al., 1979). This phenomenon appears while carrying out the unhairing process in acid medium and is named "autolytic unhairing". Unfortunately, only fresh hides and skins can be unhaired using "autolytic unhairing" because long term preservation fully inactivates hide enzymes.

The core of the present investigation was the processing of preserved and soaked hides, selecting enzymes that act as unhairing agents in acid medium. Further processes, such as oxidative removal of remaining hair, the opening up of the derma structure, and the preparation for chroming are also carried out in acid medium. Therefore, this approach to hide processing avoids the use of hazardous materials such as sodium sulphide mixed with large amounts of lime and ammonium salts.

The aim of this research was the development of leather processing in acid medium employing enzymes that are active as unhairing agents in such a medium and the estimation of the suitability of the method in conformity with the hide and leather properties after unhairing, removal of remaining hair and chroming.

EXPERIMENTAL

Salted cattle hide was used as the raw material. The samples for the investigation were taken from the lower part of the hide. The parameters of hide processing are presented in Table 1.

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The soaked hide was cut into 5x10 cm pieces and a series of samples was prepared from these pieces. One series contained 2 pieces from the lower (cattle rump) part, 2 pieces from the shoulder part, and 2 pieces from the belly part of hide. One series was used for each experiment. The pieces from the rump part were marked and, afterwards, used for determination of indexes such as amount of dermatan sulphate, shrinkage temperature, pH, strength properties etc.

The processing of hide pieces was carried out using equipment that imitated the movement of hides in a drum, i.e., rolling vessels (volume of the vessel was 1 litre) with the hide samples. The rate of rolling was 20±1 revolutions per minute.

Proteolytic enzyme preparations (EP) having high activity in weak acid medium, NovoBate WB (Novo Nordisk, Denmark) and Lithudac L (FGL International, Italy), were chosen as unhairing agents.

The removed collagen proteins were estimated from the amount of hydroxyproline in the alkaline solutions. The amount of hydroxyproline was determined by the photocolorimetric method (Golovtejeva et al., 1982).

The total amount of protein was estimated by employing Kjeldahl's method (Zaides et al., 1964). The amount of removed non-collagen proteins was calculated as the difference between the total proteins and the collagen proteins in the treatment solutions.

The EP proteolytic activity was determined by using the Anson method (Standard USSR, 1988). Sodium caseinate was used as substrate.

The pH of hide was determined according to a standard procedure (Standard ISO, 2008). The shrinkage temperature of hide (leather) was measured with a special instrument (Golovtejeva et al., 1982). The strength properties and amount of chrome compounds in leather were determined according to standard procedures (Standard ISO, 2002; Standard ISO, 2007).

The quality of unhairing was evaluated according to the following scoring system: 0 the bond between hair and derma is not weakened; 1 the bond between hair and derma is weakened marginally; 2 the bond between hair and derma is weakened markedly, but mechanical removal of hair from derma is not easy; 3 hair can be completely removed mechanically.

The content of dermatan sulphate in the hide was determined by using the modified method of Gibbons and Wolfrom (Kazlauskaite et al., 2002). After removing soluble sulphates using distilled water and drying to absolute dryness, the samples were ashed at 600-700ºC. The ash was dissolved and determination of sulphate sulphur was carried out.

Samples of hide chosen for IR-spectroscopic analysis were split to obtain a 0.9-1.0 mm width of the upper layer. The samples for the IR-spectroscopic analyses were prepared as pellets using 200 mg of optically pure KBr and 2 mg of hide tissue, which was taken from the surface formed after splitting. An infrared reflection spectrum was obtained using a Perkin-Elmer FTIR Spectrum GX (USA) spectrometer. The resolution was 1 cm¹, scan rate 0.2 cm/s and scan number 16 times. The software "Spectrum 5.0.1" was used for calculation of the area of the peaks in the spectra ΔS (T%·cm¹).

RESULTS AND DISCUSSION

Enzymatic Unhairing of Hide

Fresh and short term preserved hides can be unhaired and further processed without sodium sulphide and alkali (Sivaparvathi et al., 1979). Unfortunately, this method can not be applied to preserved hides as the "autolytic unhairing" does not occur for preserved hide. During preliminary investigation, two proteolytic EP: NovoBate WB (Novo Nordisk, Denmark) isolated from Bacillus microorganisms and Lithudac L (FGL International, Italy) isolated from Aspergillus flavus, were chosen for further experiments because these EP had shown evident unhairing ability in acid medium. Commonly, the mentioned EP are adapted for re-bating of leather (wet-blue) after chroming, but not as unhairing agents.

It was established that acetic acid, which is used in the unhairing process, not only activates hide enzymes but also removes affected components of hide (Balciuniene et al., 1994). Due to this, the enzymatic unhairing should occur more intensively using acetic acid in the process medium compared with other acids.

Because the enzymes had higher activity in a particular pH range, pure acetic acid was replaced by unhairing buffer system (UBS) having a pH 5.4-5.5 and containing acetic acid, sodium acetate and EP.

In order to reduce the amount of wastewater, it is advisable to carry out unhairing directly after soaking (after draining of soaking solution, but without washing). The pH of the soaking solution is 9.9 and the pH of the hide after soaking is 8.7-8.8.

First, investigations seeking to establish the suitable amount of EP, acetic acid and sodium acetate for qualitative weakening of the bond between the hair and derma were carried out. The results obtained are presented in Table 2.

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Based on these results, it can be supposed that the amount of EP required to unhair is 0.6%; the buffer solution should consist of 2.5% CH₃COONa and 0.3% CH₃COOH (% based on hide mass), and the duration of the process should be not shorter than 3 h.

Secondly, a comparative investigation of the pH change kinetics of unhairing solutions (water with enzyme or UBS) was carried out (Fig. 1). This showed that the pH increases up to 8.78.8 (Fig. 1, (a)) when unhairing with an aqueous solution of enzyme was carried out for 0.5 h. This can be explained by diffusion of alkaline materials from the soaked hide into solution. On the other hand, the degradation of soft keratin, which is present in the roots of hair, by enzymes begins and products of its degradation (amino acids) slowly decrease the pH to 8.5 during the second 3 h. After that, the equilibrium is reached and the pH of medium does not change.

Using UBS the value of the pH rises from 5.5 up to 6.2 during the first hour (Fig. 1, (b)). During the second 4 hours, the pH changes up to 6.9 and, after that, remains unchanged. Since an investigation of EP activity showed that EP NovoBate WB and Lithudac L have higher activity in the range of pH 6.17.2 (Fig. 2), this means that acetate buffer is very suitable for action of these EP.

The unhairing using UBS was carried out under the conditions described in Table 1. The amount of removed collagenous and total proteins was determined, and the pH of the solution was measured. The quality of unhairing was evaluated by attributing points. Also, the influence of temperature on the process was established. The results obtained are presented in Table 3.

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Results show that, when NovoBate WB or Lithudac L is used, the bond between hair and derma is completely broken and the structure of the derma is somewhat opened up. Obviously, temperature has an influence on the changes in the derma structure. The increase of the process temperature increases the amount of proteins removed. On the other hand, too high a degradation and removal of collagenous proteins during unhairing is undesirable, as this can cause defects in the leather produced. It is known that, during unhairing and opening up of the derma structure, 0.50.6 g/kg of hide collagenous and 10 g/kg of hide total proteins are usually removed (Valeika et al., 2000). This means that unhairing should be carried out at 20-25ºC, but the process should be prolonged up to 5 h. Jian et al. (2011) report that further prolongation of the unhairing process by proteases is not desirable due to possible serious injury of collagen.

The pH of the UBS solution remains suitable for high activity of EP during 24 hours.

It can be concluded that qualitative unhairing of hides can be carried out using UBS containing 0.6% (based on hide mass) EP NovoBate WB or Lithudac L, with a temperature of 2025ºC and process duration of 5 h.

Changes of Proteins, Dermatan Sulphate, Shrinkage Temperature, and pH of Hide During Unhairing and Oxidative Treatment

The principal problem of enzymatic unhairing is always that, after the process and mechanical removal of hair, the scud and some hair remain on the hide. There are several ways to solve this problem. The first one includes the use of sulphides. However, the amount of sulphides usually used is so large that enzymatic unhairing no longer makes any sense, as the enzymes are being used precisely as an alternative to sulphide unhairing. Due to this, an oxidative treatment using peracetic acid was chosen for the final degradation of the remaining hair and opening up of the derma in this case. Carried out under the conditions described in Table 1, the oxidative treatment consisted of two processes: oxidation of keratin containing epidermis and hair with peracetic acid; and subsequent dissolving of oxidized hair and epidermis by alkali. After oxidation with peracetic acid, a small amount of weak alkali (ammonia in this case) is sufficient for final degradation of hair and epidermis residues and does not change the pH of hide noticeably.

The properties of hide obtained by enzymatic unhairing and subsequent oxidative treatment have been investigated and compared with conventionally processed hide properties (Table 4).

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The investigation of the change in the amount of dermatan sulphate has shown that removal of dermatan sulphate is intensive. Also, the removal of dermatan sulphate from hide occurred during oxidative treatment and the amount of dermatan sulphate that remained in the hide depended on the enzymatic preparation used. The shrinkage temperature of hide after unhairing and oxidative treatment was 8.09.0ºC lower compared to soaked hide. All results show that an effective opening up of the derma structure takes place during hide processing. Also, the grain of hide after oxidative treatment was completely clean.

The changes of hide pH are presented in Fig. 3.

The data (Fig. 3) show that hide pH changed in a smaller interval and the changes of pH were less when the processes were carried out according to the proposed technology as compared to the conventional one.

Investigation of Unhaired Hide Structure

The evaluation of hide structural changes was carried out by IR-spectroscopy, recording reflection spectra of hide (Fig. 4) in the range of 4000800 cm¹. IR-spectra were recorded for the sample and control hides after the processes described in Table 1. IR-spectra were analysed using the software Spectrum v5.0.1. and the area of peaks (ΔT, % T·cm^-1) calculated. Comparison of peak areas allows conclusions about the formation of functional groups and degradation or formation of bonds during leather processing. The results are presented in Table 5.

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The data in Table 5 show differences between the areas of peaks in the ranges of 32703283 cm¹ and 29162921 cm¹. The vibrations in the range of 33002500 cm¹ are attributed to the functional groups O-H, NH and CH. The experimental hide's peak area is about 1.6 time bigger than the control. This shows that the processing of experimental hide breaks fewer hydrogen bonds. Due to this, we have a more stable system compared to the control hide. The evaluation of the removal of interfiber and collagen proteins (Table 3) proves this supposition: a smaller amount of interfiber and collagen proteins is degraded during processing of the experimental hide.

In the IR spectra of carboxylic acids, the peaks are in the range of 17601720 cm¹; the peak of the deformation vibration of COH is in the range of 14401395 cm¹ and the peak of CO valence vibration is in the range of 13201210 cm¹ (Buika et al., 2007). In the carboxylate anion, there are two peaks: an intense peak for the valence vibration in the range of 16501550 cm¹ and a weak peak for the symmetric valence vibration at ~ 1400 cm¹. Such peaks allow using the changes in spectra for identifying carboxylic acids.

Investigating derma proteins, the amount of carboxyl groups reflects the ongoing situation. The data in Table 4 show that peak areas in experimental hide spectra (17381740 cm¹ and 17241726 cm¹) are about 3.6 times bigger than the control. It is known that the amount of carboxyl groups depends on hide pH: the amount decreases with increasing pH of the hide and vice versa (Bienkewicz, 1983). The pH of experimental hide was 4.3 and of the control was 9.4. These values of pH determine the amount of ionized carboxyl groups in collagen and, correspondingly, the areas of the peaks.

Peaks in the ranges of 16271629 cm¹, 15391540 cm¹ and 12351236 cm¹ are attributed to deformation vibrations of NH (respectively I, II and III amide bands). The areas of the peaks in these ranges are similar and thus indicate similar changes of hide structure during beam house processes. The results (Table 3) of investigation of removed interfiber and collagen proteins, dermatan sulphate, and shrinkage temperature prove this supposition.

Very big differences (about 11-fold) between the areas of peaks in the experimental and control hide were observed in the range of 872874 cm^-1. This difference appears to be due to Ca-O in control hide, because this hide was obtained using Ca(OH)₂, while the experimental one was processed without Ca(OH)₂. It is known that, when using Ca(OH)₂ for unhairing and opening up of derma, part of the Ca binds to carboxyl groups of derma and is not removed in the deliming process.

According to data in the literature, peaks at 1081 cm^-1 and 1030 cm^-1 are specific to collagen (Bienkewicz, 1983). Unfortunately, it is not clear what groups absorb in these ranges. There is an opinion that these vibrations are specific to the sulpho group. The data in Table 5 show that the area of peaks of experimental hide in the mentioned range is about 4 times lower than for the control. The increase of sulpho groups in the control hide is due to the (NH₄)₂SO₄ used in deliming.

Therefore, the IR-spectroscopic analysis confirms the results of chemical and physical analyses of hide: the hide obtained according to the experimental technology has properties very close to hide processed using conventional one.

Properties of Chromed Leather

In order to establish the workability of the unhairing and oxidative treatment methods for leather processing, the properties of chromed leather were evaluated.

As shown by previous investigation, a hide after treatment with peracetic acid and bating could be directly chromed, omitting pickling, or chromed after treatment with NaCl solution (low-pickle) instead of conventional pickling (Sirvaityte et al., 2009).

Due to this, before chroming the hide was treated under the following conditions (% based on hide mass): H₂O 40%, NaCl 6.5%, temperature 20-22ºC, duration 2 h, run continuously. The chroming was carried out in the solution of the previous treatment and the parameters of chroming were (% based on hide mass): H₂O 40%, Cr₂O₃ 1.5% (basicity of chromium extract 20%), temperature 20-22ºC, duration 12 h; Neutragene MG-120 (material for increasing basicity) 0.25%, duration 2 h; Neutragene MG-120 0.25%, duration 2 h; Neutragene MG-120 0.25%, duration 2 h; H₂O 40%, temperature 60ºC, duration 1 h, all run continuously.

The analysis of chromed leather was performed and the results obtained are presented in Table 6.

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The results show good quality of chroming because the shrinkage temperature exceeds 100ºC; the distribution of chromium in the layers of leather is even enough. The strength properties of the leather are not impaired when compared with the figures corresponding to normal production leather (Zhou et al., 2011; Bacardit et al., 2009).

CONCLUSIONS

Washed and soaked hide can be qualitatively unhaired using an unhairing buffer system containing acetic acid, sodium acetate, and the enzyme preparations NovoBate WB (Denmark) or Lithudac L (Italy) active in acid medium. The acetate buffer should have pH 5.45.5. The amount of EP NovoBate WB or Lithudac L in acetate buffer for unhairing should be 0.6 % (based on hide mass) EP and the process should be carried out at 2025ºC for 56 h.

The residual hair and scud can be removed completely with peracetic acid. The influence of the enzymatic preparations NovoBate WB and Lithudac L on noncollagen and collagenous proteins is similar during both the unhairing and oxidative treatment. Dermatan sulphate analysis has shown that removal of dermatan sulphate is intensive. All results show that an effective opening up of derma structure occurs during the hide processing.

After enzymatic unhairing and oxidative treatment, the hide can be prepared for chroming by replacing conventional pickling with treatment with NaCl solution.

Leather processing in acid medium avoids the use of sodium sulphide and decreases significantly the demand for ammonium salts and chromed leather with good shrinkage and strength properties is produced.

(Submitted: February 20, 2011 ; Revised: October 24, 2011 ; Accepted: November 21, 2011)

Bacardit, A., Olle, L., Morera, J., Bartoli, E., Palomares, H. and Borras, D., Lower pollution pickle-chrome process: a no-float/low-salt approach. Journal of the Society of Leather Technologists and Chemists, 93, No. 2, 67 (2009).
Balciuniene, J., Beleska, K., Skrodenis, A., Valeika, V. and Valeikiene, V., Sochrannost I razrychlenye dermy shkur pri avtoliticheskom obezvolachivanyi. Kozhevenno-obuvnaiya Promyshlennost, No. 11, 23, (1994). (In Russian).
Bienkewicz, K., Physical chemistry of leather making. Robert E. Krieger Publishing Co. Inc., Malabar, Florida (1983).
Buika, G., Getautis, V., Martynaitis, V. and Rutkauskas K., Spectroscopy of organic compounds. Vitae Litera, Kaunas, Lithuania (2007). (In Lithuanian).
Crispim, A. and Mota, M., Unhairing with enzymes. Journal of the Society of Leather Technologists and Chemists, 87, No. 5, 198 (2003).
Dettmer, A., Ayub, M. A. Z., and Gutterres, M., Hide unhairing and characterization of commercial enzymes used in leather manufacture. Brazilian Journal of Chemical Engineering, 28, No. 3, 373 (2011).
Foroughi, F., Keshavarz, T. and Evans, C. S., Specificities of proteases for use in leather manufacture. Journal of Chemical Technology and Biotechnology, 81, No. 3, 257 (2006).
Golovtejeva, A., Kucidi, D. and Sankin, L., Laboratornyi praktikum po technologyi kozhi i mecha. Legkayia I Pischevayia Promyshlenost, Moscow, USSR (1982). (In Russian).
Jian, S., Wenyi, T. and Wuyong, C., Kinetics of enzymatic unhairing by protease in leather industry. Journal of Cleaner Production, 19, No. 4 (2011).
Kazlauskaite, E., Balciuniene, J., Zaliauskiene, A., Beleska, K., Valeika V. and Valeikiene V., Influence of unhairing method on dermatan sulphate and microscopical investigation of pelt and leather. Journal of the Society of Leather Technologists and Chemists, 86, No. 2, 59 (2002).
Madham, B., Dineshkumar, M., Rao, J. R. and Nair, B. U., Studies on the removal of inter-fibrillary materials. Part II: Removal of protein, proteoglycan and glycosoaminoglykans from biobased pre-tanning process. Journal of American Leather Chemists Association, 105, No 6, 181 (2010).
Priya, S., Rajaram, A., Rajaram, R. and Ramasami, T., Depilation of skins by pure enzymes. Journal of the Society of Leather Technologists and Chemists, 92, No. 5, 214 (2008).
Saravanabhavan, S., Aravindham, R., Thanikaivelan, P., Rao, J. R. and Nair, B. U., Green solution for tannery pollution: effect of enzyme based lime-free unhairing and fibre opening in combination with pickle-free chrome tanning. Green Chemistry, 5, No 6, 707 (2003).
Sirvaityte, J., Valeika, V. and Plavan, V., Peracetic acid deliming. Part II: Pickle-free and low-pickle processing of peracetic acid delimed pelt. Journal of Society of Leather Technologists and Chemists, 93, No. 2, 40 (2009).
Sivaparvathi, M., Nandy, S. C. and Dhar S. C., Effect of various factors on the autolitic enzymatic unhairing of skin. Leather Science, 21, No. 9, 297 (1974).
Sivaparvathi, M., Nandy, S. C. and Santappa, M., Die Funktion der sauren Proteasen der Haut bei der Entharung. Das Leder, No. 6, 97 (1979). (In German).
Sivasubramanian, S., Manohar, B. M., Rajaram, A. and Puvanakrishnan, R., Ecofriendly lime and sulfide free enzymatic dehairing of skins and hides using a bacterial alkaline protease. Chemosphere, 70, No. 6, 1015 (2008).
Standard ISO 4045:2008. Leather – Chemical tests – Determination of pH.
Standard ISO 3376:2002. Leather – Physical and mechanical tests – Determination of tensile strength and percentage extension.
Standard ISO 5398-1:2007, Leather – Chemical determination of chromic oxide content – Part 1: Quantification by titration.
Standard USSR: GOST 20264-88. Enzyme preparations Methods of determination of proteolytic activity.
Valeika, V., Balciuniene, J., Beleska, K. and Valeikiene, V., Lime-free unhairing: Part 3. Influence of unhairing method on chemical, physical and mechanical properties of pelt and leather. Journal of Society of Leather Technologists and Chemists, 84, No. 4, 165 (2000).
Valeika, V., Beleska, K., Valeikiene V. and Kolodzeiskis, V., An approach to cleaner production: from hair burning to hair saving using a lime-free unhairing system. Journal of Cleaner Production, 17, No. 2, 214 (2009).
Wang, R., Min, C., Haiming, C. and Li, Z. Q., Enzyme unhairing an eco-friendly biotechnological process. Journal of the Society of Leather Technologists and Chemists, 93, No. 2, 51 (2009).
Zaides, A., Mikhailov, A. and Pushenko O., Modiphitsirovanyi method opredeleniya oksiprolina. Biokhimiya, No. 1, 5 (1964). (In Russian).
Zhou, P., Xuepin, L. and Bi, S., Preparation of lignosulfonate Reduced Chrome Tanning Agent and its Tanning Effect. Journal of the Society of Leather Technologists and Chemists, 95, No. 4, 158 (2011).

*

To whom correspondence should be addressed

Publication Dates

Publication in this collection
21 June 2012
Date of issue
June 2012

History

Received
20 Feb 2011
Accepted
21 Nov 2011
Reviewed
24 Oct 2011

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] Bacardit, A., Olle, L., Morera, J., Bartoli, E., Palomares, H. and Borras, D., Lower pollution pickle-chrome process: a no-float/low-salt approach. Journal of the Society of Leather Technologists and Chemists, 93, No. 2, 67 (2009).

[2] Balciuniene, J., Beleska, K., Skrodenis, A., Valeika, V. and Valeikiene, V., Sochrannost I razrychlenye dermy shkur pri avtoliticheskom obezvolachivanyi. Kozhevenno-obuvnaiya Promyshlennost, No. 11, 23, (1994). (In Russian).

[3] Bienkewicz, K., Physical chemistry of leather making. Robert E. Krieger Publishing Co. Inc., Malabar, Florida (1983).

[4] Buika, G., Getautis, V., Martynaitis, V. and Rutkauskas K., Spectroscopy of organic compounds. Vitae Litera, Kaunas, Lithuania (2007). (In Lithuanian).

[5] Crispim, A. and Mota, M., Unhairing with enzymes. Journal of the Society of Leather Technologists and Chemists, 87, No. 5, 198 (2003).

[6] Dettmer, A., Ayub, M. A. Z., and Gutterres, M., Hide unhairing and characterization of commercial enzymes used in leather manufacture. Brazilian Journal of Chemical Engineering, 28, No. 3, 373 (2011).

[7] Foroughi, F., Keshavarz, T. and Evans, C. S., Specificities of proteases for use in leather manufacture. Journal of Chemical Technology and Biotechnology, 81, No. 3, 257 (2006).

[8] Golovtejeva, A., Kucidi, D. and Sankin, L., Laboratornyi praktikum po technologyi kozhi i mecha. Legkayia I Pischevayia Promyshlenost, Moscow, USSR (1982). (In Russian).

[9] Jian, S., Wenyi, T. and Wuyong, C., Kinetics of enzymatic unhairing by protease in leather industry. Journal of Cleaner Production, 19, No. 4 (2011).

[10] Kazlauskaite, E., Balciuniene, J., Zaliauskiene, A., Beleska, K., Valeika V. and Valeikiene V., Influence of unhairing method on dermatan sulphate and microscopical investigation of pelt and leather. Journal of the Society of Leather Technologists and Chemists, 86, No. 2, 59 (2002).

[11] Madham, B., Dineshkumar, M., Rao, J. R. and Nair, B. U., Studies on the removal of inter-fibrillary materials. Part II: Removal of protein, proteoglycan and glycosoaminoglykans from biobased pre-tanning process. Journal of American Leather Chemists Association, 105, No 6, 181 (2010).

[12] Priya, S., Rajaram, A., Rajaram, R. and Ramasami, T., Depilation of skins by pure enzymes. Journal of the Society of Leather Technologists and Chemists, 92, No. 5, 214 (2008).

[13] Saravanabhavan, S., Aravindham, R., Thanikaivelan, P., Rao, J. R. and Nair, B. U., Green solution for tannery pollution: effect of enzyme based lime-free unhairing and fibre opening in combination with pickle-free chrome tanning. Green Chemistry, 5, No 6, 707 (2003).

[14] Sirvaityte, J., Valeika, V. and Plavan, V., Peracetic acid deliming. Part II: Pickle-free and low-pickle processing of peracetic acid delimed pelt. Journal of Society of Leather Technologists and Chemists, 93, No. 2, 40 (2009).

[15] Sivaparvathi, M., Nandy, S. C. and Dhar S. C., Effect of various factors on the autolitic enzymatic unhairing of skin. Leather Science, 21, No. 9, 297 (1974).

[16] Sivaparvathi, M., Nandy, S. C. and Santappa, M., Die Funktion der sauren Proteasen der Haut bei der Entharung. Das Leder, No. 6, 97 (1979). (In German).

[17] Sivasubramanian, S., Manohar, B. M., Rajaram, A. and Puvanakrishnan, R., Ecofriendly lime and sulfide free enzymatic dehairing of skins and hides using a bacterial alkaline protease. Chemosphere, 70, No. 6, 1015 (2008).

[18] Standard ISO 4045:2008. Leather – Chemical tests – Determination of pH.

[19] Standard ISO 3376:2002. Leather – Physical and mechanical tests – Determination of tensile strength and percentage extension.

[20] Standard ISO 5398-1:2007, Leather – Chemical determination of chromic oxide content – Part 1: Quantification by titration.

[21] Standard USSR: GOST 20264-88. Enzyme preparations Methods of determination of proteolytic activity.

[22] Valeika, V., Balciuniene, J., Beleska, K. and Valeikiene, V., Lime-free unhairing: Part 3. Influence of unhairing method on chemical, physical and mechanical properties of pelt and leather. Journal of Society of Leather Technologists and Chemists, 84, No. 4, 165 (2000).

[23] Valeika, V., Beleska, K., Valeikiene V. and Kolodzeiskis, V., An approach to cleaner production: from hair burning to hair saving using a lime-free unhairing system. Journal of Cleaner Production, 17, No. 2, 214 (2009).

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Alkali-free method of hide preparation for tanning

Abstract

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