Biopigments from Monascus: strains selection, citrinin production and color stability

Carvalho, Júlio Cesar de; Oishi, Bruno Oliva; Pandey, Ashok; Soccol, Carlos Ricardo

doi:10.1590/S1516-89132005000800004

Abstracts

Fungi form the genus Monascus are a promising source for natural color additives. However, before effectively applying Monascus to foods, it is important to select strains which produce large amounts of biopigments but little or no citrinin, a mycotoxin usually also produced by these fungi. Also, color stability of these pigments should be properly investigated. In order to compare Monascus strains for biopigment production in solid substrate fermentation (SSF), 4 strains (NRRL 1991, NRRL 2897, CCT 3802 and LPB 31) were cultivated over PDA in Petri dishes, and compared for radial growth velocity. Also, these strains were cultivated over cooked rice, and compared in relation to their capacity to produce biopigments and citrinin. The results showed that the strain LPB 31 is the best strain for biopigment production in SSF, giving both higher pigment concentration and lower citrinin concentration on the extracts, showing that it is a promising strain for production of this bioproduct. Biopigmentassays for heat and pH stability, show that these biopigments are unstable at low pH and high temperatures, but may be successfully used at near-neutrality pH's and in non-thermal processed foods.

Monascus; biopigment; citrinin; solid-substrate fermentation

Fungos do gênero Monascus são uma fonte promissora de corantes vermelhos naturais. No entanto, antes de se aplicar Monascus a alimentos, é importante selecionar linhagens capazes de produzir grandes quantidades de pigmentos, com o mínimo possível de citrinina. Além disso, a estabilidade de cor desses pigmentos deve ser adequadamente investigada. Com o objetivo de comparar linhagens de Monascus para a produção de biopigmentos em fermentação em substrato sólido (FSS), 4 linhagens (NRRL 1991, NRRL 2897, CCT 3802 e LPB 31) foram cultivadas sobre PDA em placas de Petri, e comparadas com relação à velocidade de crescimento radial. Além disso, essas linhagens foram cultivadas em arroz cozido, e comparadas quanto à sua capacidade de produção de biopigmentos e de citrinina. Os resultados mostram que a linhagem LPB 31 é a melhor linhagem para produção de biopigmentos em FSS, dando tanto maior concentração de pigmentos quanto menor concentração de citrinina, mostrando que se trata de uma linhagem promissora para a obtenção deste bioproduto. Os biopigmentos extraídos dos substratos fermentados foram testados quanto à estabilidade frente ao calor e ao pH, mostrando que os biopigmentos de Monascus são instáveis em pH's baixos e altas temperaturas, mas que podem ser usados sem problema em condições de neutralidade, em alimentos sem processamento térmico.

AGRICULTURE, AGROBUSINESS AND BIOTECHNOLOGY

Biopigments from Monascus: strains selection, citrinin production and color stability

Júlio Cesar de Carvalho^I; Bruno Oliva Oishi^I; Ashok Pandey^II; Carlos Ricardo Soccol^I,^* * Author for correspondence

^IDivisão de Engenharia de Bioprocessos e Biotecnologia; Setor de Tecnologia; Universidade Federal do Paraná; C. P. 19011; soccol@ufpr.br; 81531-990; Curitiba - PR - Brasil

^IIBiotechnology Division; Regional Research Laboaratory; CSIR; Trivandrum 695 019; India

ABSTRACT

Fungi form the genus Monascus are a promising source for natural color additives. However, before effectively applying Monascus to foods, it is important to select strains which produce large amounts of biopigments but little or no citrinin, a mycotoxin usually also produced by these fungi. Also, color stability of these pigments should be properly investigated. In order to compare Monascus strains for biopigment production in solid substrate fermentation (SSF), 4 strains (NRRL 1991, NRRL 2897, CCT 3802 and LPB 31) were cultivated over PDA in Petri dishes, and compared for radial growth velocity. Also, these strains were cultivated over cooked rice, and compared in relation to their capacity to produce biopigments and citrinin. The results showed that the strain LPB 31 is the best strain for biopigment production in SSF, giving both higher pigment concentration and lower citrinin concentration on the extracts, showing that it is a promising strain for production of this bioproduct. Biopigmentassays for heat and pH stability, show that these biopigments are unstable at low pH and high temperatures, but may be successfully used at near-neutrality pH's and in non-thermal processed foods.

Key words:Monascus, biopigment, citrinin, solid-substrate fermentation

RESUMO

Fungos do gênero Monascus são uma fonte promissora de corantes vermelhos naturais. No entanto, antes de se aplicar Monascus a alimentos, é importante selecionar linhagens capazes de produzir grandes quantidades de pigmentos, com o mínimo possível de citrinina. Além disso, a estabilidade de cor desses pigmentos deve ser adequadamente investigada. Com o objetivo de comparar linhagens de Monascus para a produção de biopigmentos em fermentação em substrato sólido (FSS), 4 linhagens (NRRL 1991, NRRL 2897, CCT 3802 e LPB 31) foram cultivadas sobre PDA em placas de Petri, e comparadas com relação à velocidade de crescimento radial. Além disso, essas linhagens foram cultivadas em arroz cozido, e comparadas quanto à sua capacidade de produção de biopigmentos e de citrinina. Os resultados mostram que a linhagem LPB 31 é a melhor linhagem para produção de biopigmentos em FSS, dando tanto maior concentração de pigmentos quanto menor concentração de citrinina, mostrando que se trata de uma linhagem promissora para a obtenção deste bioproduto. Os biopigmentos extraídos dos substratos fermentados foram testados quanto à estabilidade frente ao calor e ao pH, mostrando que os biopigmentos de Monascus são instáveis em pH's baixos e altas temperaturas, mas que podem ser usados sem problema em condições de neutralidade, em alimentos sem processamento térmico.

INTRODUCTION

The pigments produced by the fungus Monascus sp. are of traditional use in oriental countries, and have been subject of intense research in the last decades, because of its potential for application as food additives. The use of this color additive is not yet regulated in the European Union, United States and Brazil, among other regions. As is the case for other fungi, Monascus strains produce also mycotoxins. In this case, the mycotoxin produced is citrinin, a nephrotoxic substance which also presents antibiotic properties. Despite this toxicity problem, Monascus pigments may be quickly produced in large scale throughout the year in industrial facilities, so that it might become an industrially important pigment. The key is to find strains which produce pigments with as little citrinin as possible.

The genus Monascus (see characteristic morphology in Fig. 3) encloses three main species (M. pilosus, M. purpureus e M. ruber) belonging to the family Monascaceae and to the class Ascomyceta (Pitt, 1997), whose most important characteristic is the ability to produce secondary metabolites of polyketidic structure, (Juszlová, 1996), some of them with strong yellow, orange or red pigmentation. The two first species are more important for pigment production, while M. ruber is associated to the decomposition of several foods. Easily found in several ecosystems, these fungi were used originally in Chine and Thailand, for the preparation of angkak, a fermented rice of strong red color which finds several uses, from conferring color to other products such as wine, cheese and meat, to medicinal uses and as meat preservative (Wong, 1981). At this moment, several industries commercialize the red, grinded rice as a natural food supplement capable of lowering blood cholesterol, while others sell the dry product or purified extracts as food colorants (Allok, 2003).

Among the pigments produced by Monascus, the red ones (Fig. 1) are regarded as the most important, because these may be used as substitutes for nitrites in meat products and for synthetic colors such as erythrosine (FD and C red no. 3) (Johns and Stuart, 1991, Fabre, 1993). Oriental countries such as Japan make extensive use of these pigments since decades - for an instance, as yellow water soluble pigments in candies (Watanabe, 1997), or red pigment for red rice wine.

The strains used for pigment production are usually isolates from Japan, China, Thailand or Indonesia, of several fermented foods: soy cheese, red koji, and the most common source, angkak (ATCC, 1987). Strains differ in the amount produced and the tone of the pigments, besides other factors such as growth velocity and overall metabolic profile. Temperature, pH and humidity are factors that influence the microorganism growth and pigmentation.

Excluding those that are restricted to particular research institutes, universities or companies, the strains more often cited in Monascus literature are listed below (Table 1). Notice that the same strains present several denominations, depending on the institute where it is conserved. Some of these strains were deposited with a different name than that currently accepted; the table shows the denomination in 2004, and some references related specifically to pigment production (some other strains were used for metabolic studies and anti-hyperlipidemics production). The growth and metabolite production of the fungi of the genus Monascus are accomplished under a number of conditions. There are several adequate culture media, but the most common are PDA and malt-extract-agar (MEA) (ATCC, 2004). The growth is possible from 15-18°C (minimum) to around 45°C (maximum) (Pitt, 1997), with the pigment production greatly varying with the species and cultivation conditions. Among the important metabolites of Monascus are the pigments, citrinin, and also a series of anti-hyperlipidemics as monacolins K and L (Ma, 2000). During the culturing of Monascus CO₂, ethanol and acetate are also produced. While working with SSF of rice, Rosenblitt et al (2000) showed that at the end of a 240 h fermentation, carbon balance was as follows: ca 23% of the carbon was converted to biomass, 35% to CO₂, 15% to ethanol, 1% to acetic acid and 17% remained unused.

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The optimal temperature range for Monascus growth is 28-32°C, according to the registers of each species in strain banks, although this temperature varies depending on the strain between 25°C and 37°C (Lin, 1991). Growth has been observed in a wide range of pH, from 2.5 to 8.0, with the ideal range being from 4.0 to 7.0 (Yongsmith, 1993). There are several studies on the toxicity of Monascus pigments showing that this biopigment is apparently safe in the quantities tested. The many years for which these biopigments have been used suggested low or non-existent toxicity (Lin, 1991a). When Monascus started to be studied systematically, it has been believed that the biopigments produced also presented antibiotic properties; later, it was verified that this activity is due mainly to other substance, named monascidin A (Wong, 1981). Further studies showed that this substance was, in fact, citrinin (Blanc et al., 1995a), but that not all Monascus strains produced it. It was also found that the nitrogen source used could interfere in the citrinin production.

As an example, for the same strain of M. ruber in a synthetic medium with ethanol, citrinin production ranged from 0 mg/L using methionine as nitrogen source, to 100 mg/L using ammonium nitrate as a nitrogen source (Blanc, 1995). Finally, studies over the toxicity of purified fractions of pigments showed that there was indeed an antibiotic activity for Monascus biopigments, especially the orange ones and, in lower degree, the red ones (Martínková, 1995).

Citrinin is a fungal metabolite known since 1931, when it was isolated from Penicillium citrinum and later from the Australian plant Crotolaria crispata. Ten years later it was characterized as an antibiotic and antibacterial, and later on tested for activity against bacteriophages, sarcomas, protozoa, animal cells and superior plant cells (Betina, 1984). Citrinin structure is illustrated in Fig. 2. Citrinin present a highly acidic character, is practically insoluble in water, soluble in hot alcohol, dioxane and other non polar solvents. Due to its conjugated double bonds, citrinin absorbs light in the visible wavelength range - its color varies from lemon yellow at pH 4,6 to cherry red at pH 9,9 - and its absorption maxima are in the in the uv range: 250 -331 nm. It presents a melting point of 175ºC and molecular mass 250.25 g/mol (Merck, 1996). Citrinin may be extracted with non polar solvents.

Derivatives of citrinin such as decarboxycitrinin have unknown metabolic function, but several studies in systems in vivo and in vitro indicate that citrinin itself has an biological action by inhibition of cholesterol and triglyceride synthesis, this inhibition being possibly caused by damage to transport systems and/or interferences in energetic metabolism (Betina, 1984).

The majority of Monascus researchers estimate the production of pigments by spectrophotometry, with pigment production varying from hundreds of absorbance units per mL culture medium, in submerged fermentations, to thousands of absorbance units/g dry substrate, in SSF (Kim et al, 2002; Lin and Demain, 1992). Experiments may be compared by relative production, in a 0-100% scale.

Surprisingly, relatively few articles deal with stability of Monascus preparations, considering that several industries produce this pigment. According to Lin and Demain (1992), these pigments are reasonably stable to autoclaving, in a wide range of pH. According to Fabre (1993), sauces and pâtés colored with red Monascus pigments show a residual color of 92 to 98% after three months at 4°C, with good sensorial acceptance. However, these pigments are unstable towards light (only 20% residual color after 50 days) and heat (45% residual color after 2h at 100°C). These pigments are more stable under basic or neutral pH (Fabre 1993, Lee 2000).

The aim of this work is to compare different Monascus strains for their biopigment and citrinin production, and also investigate Monascus biopigments stability, in order to provide information for further development of a biopigment preparation with low toxicity.

MATERIAL AND METHODS

All the experiments were performed at the "Divisão de Engenharia de Bioprocessos and Biotecnologia" (DEBB) at UFPR.

Strains used - Four Monascus strains were used in this work: two strains from United States Department of Agriculture, NRRL 1991 (Monascus. sp) and NRRL 2897 (M. purpureus), one strain from Fundação André Tosello (Brazil), CCT 3802 (M. purpureus), and LPB 31, a strain isolated at LPB from rice contaminated with red mycelium. The strains were conserved by routine inoculation and incubation in PDA at 30-32°C for 10 days, and then conserved by refrigeration for 3 to 4 months.

Radial growth determination - Radial growth of the strains was measured by inoculating PDA on Petri dishes with each strain, in a point on the center of the dish, in duplicate (8 dishes). The cultures were then incubated at 30°C for 12 days. The radius of the colonies was measured with a ruler, from the center of the dish, along 2 perpendicular axes (4 measures by dish) at intervals of approximately 24 h. The values obtained were used to calculate average values (arithmetic means) of radius x incubation time.

Medium and inoculation for pigment comparison - Inoculum was prepared immediately before use, obtained from the stock cultures by inoculation, over sterile PDA in Petri dishes, and incubated for 8 to 10 days. After incubation, a spore suspension was prepared by addition of 5 mL of Tween 80 at 0.1%, directly over the Petri dishes, using a Drigalski hook. The spore suspensions were standardized to 1.10⁶ spores/mL by addition of sterile water, counting also as "spores" intact mycelial fragments. The count was performed using a Neubauer chamber (on a microscope). The inoculum (0.5 mL of spores suspension) was transferred to 600 mL fermentation flasks using sterile pipettes, and then homogenizing the medium (10g of rice with 56% humidity, or 10 g of cassava bagasse with 70% humidity, with pH adjusted to 6,5 and autoclaved for 15 min at 121°C). These flasks were incubated at 30-32°C for 8 days, then dried and the content of citrinin and pigments was determined.

Pigment extraction and analysis - Monascus biopigments were extracted from fermented media using as solvent 95% ethanol, with the proportion of 5 mL ethanol:g dry fermented mass, with occasional agitation, for 24 h, then centrifuging for 15 min at 10000 g. The extracts were diluted and the absorbance was measured against pure solvent at 500 nm, near the absorbance peak of red pigments (Johns, 1991; Lin and Demain 1992). The absorbance obtained was corrected for the dilution and dry fermentate mass, giving what we call specific absorbance, a value proportional to pigment concentration (Johns, 1991; Lin 1992; Chiu, 1993). In order to compare different strains, absorbance was translated into relative (0 - 100%) absorbance.

Citrinin extraction and analysis - This analysis was made only for rice fermentations. After drying the fermentate, 5 g of the homogenized material was extracted with 50 mL of water, under agitation at 100 rpm for 1 hour. The liquid phase was filtered, extracted twice with ethyl acetate and analyzed in accordance to Blanc et al. (1995a), using a C₁₈ HPLC column and a PDA detector.

Biomass for stability analysis - These pigments were extracted from fresh mycelium of a submerged fermentation, in an attempt to avoid contamination with material extracted from the substrate. The fermentation was performed in a Bio-Flo fermenter with 12 L of liquid medium, with an aeration of 10 liters/minute, 100 rpm agitation, incubated at 32ºC for 10 days. The medium used was that of Lin e Demain (1991).

Biomass separation - After cultivation, the fermented broth was filtered trough cotton cloth, the biomass was washed with deionized water, drained and stored at -20°C until use. Extract preparation - 5 g of stored biomass were mixed with 20g of 95% ethanol. After 1h extraction, with periodic agitation, the mixture was filtered trough a 0,47µm membrane, and the filtrate was used as a raw pigment extract.

Pigment solutions - 5 mL of the raw alcoholic extracts were diluted in enough water to complete 500 g. From this solution, other solutions were prepared, with pH adjusted to several values, from 4 to 8, by the addition of concentrated NaOH or HCl solutions. The dilution caused by acid/base addition was of the order of 0,5% w/w. An alcoholic solution was prepared in a similar manner, diluting 1 mL of an alcoholic extract in 95% ethyl alcohol to a 100 mL final volume.

Stability analysis - The aqueous and alcoholic solutions were stored in stoppered glass tubes with same size and absorbance (as determined by prior absorbance analysis). These solutions were incubated at different temperatures for several hours. The color intensity was read as absorbance at 500 nm, directly for each tube, against water as blank. The results were normalized by dividing the obtained absorbance for each tube, all along incubation time, by the initial absorbance of the same tube.

RESULTS AND DISCUSSION

Microorganism isolation and characterization - The strain LPB 31 was isolated from rice contaminated with red mycelium. A portion of this mycelium was carefully extracted and inoculated in PDA in a test tube and incubated at 28°C for 5 days. After this step, a portion of the mycelium in the test tube was inoculated in another sterile tube, and the process was repeated until a morphologically homogeneous culture was obtained. The observation of this culture shows that the isolated microorganism isolated presents the characteristics typical to Monascus cultures: planar colonies, with some aerial development, mycelium initially white, turning to the characteristic brownish red color with time (from the center to the borders), with diffusion of the pigments through the agar. Fig. 3a shows a PDA Petri dish with some colonies well developed. Notice the diffusion halo, and the flocculent aspect of the aerial mycelium.

Microscopical exam of the colonies show a mycelium with brownish red pigmentation, cleistotechia with thin walls and hyaline ascospores with round appearance. Fig. 3b shows an isolated portion of the aerial mycelium, with formation of terminal aleurioconidia, pyriform and isolated. Fig. 3c shows two cleistotechia, one intact and another ruptured, with liberation of spores. The aspect of the isolated strain is also similar to other Monascus species, including in the formation of pigments of characteristic color. Fig. 4 shows the 4 Monascus strains used in this work, incubated at 30-32°C.

Strain comparison - The four Monascus strains used in this work were compared regarding growth velocity in PDA, measured through radial growth (Fig. 4) and also regarding red pigment production in rice and cassava bagasse, after 7 and 11 days of fermentation, respectively.

Analysis of Fig. 4 shows that strains 1991, 2897 and LPB 31 develop in a comparable manner, with colonies slightly larger for LPB 31, while the strain 3802 presents colonies 30% smaller. The growth velocity, determined from the same data, show that the isolated strain, LPB 31, presents a growth velocity similar to strains NRRL 2897 and NRRL 1991, and superior to the strain CCT 3802 (Table 2).

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Table 2

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The analysis of Table 3 show that the best strain tested is LPB 31, either in terms of relative production (inferior only to the commercial product, in roughly 13%) or in pigment productivity, superior to the other strains, and citrinin production, the lowest among all strains. This shows that a product made using this strain may be similar to the commercial sample in terms of color, and better in terms of toxicity, with roughly 40% less citrinin than the commercial product.

Pigment stability analysis - In an attempt to estimate how stable Monascus pigments may be in several applications, different solutions of these pigments were incubated at different pH and temperatures. Stability was measured as relative residual absorbance. All aqueous solutions of Monascus pigments show a smaller absorbance in the course of time, in all the tested conditions. This effect is more important in higher temperatures; Fig. 5 shows this effect for 5 pigment solutions at pH 6 (a typical value for foods), at different incubation temperatures.

The effect of temperature is similar to that observed in other thermal degradations, in which higher temperatures greatly increase the effect. However, an Arrhenius kinetic model of exponential decay does not represent the system well. This is possibly due to the fact that the extract is a mixture of pigments, whose degradation may present different decaying behavior. It is clear, however, that color alterations should be expected in thermally processed products with Monascus pigments - as an example, smoked, dried or autoclaved products.

The effect of the pH is equally clear: when several samples were incubated at the same temperature but with different pH values, in the range from 4 to 8, it was observed that in smaller pH's the color degradation is more significant. This effect is illustrated in Fig. 6.

Fig. 6

The effect of pH and temperature in residual color is summarized in the following table (Table 4). In an attempt to stabilize the pigments, several solutions at pH 7,0 with different solutes such as the antioxidant ascorbic acid, oxidizing salts of Fe³⁺ and Cu²⁺, and peptone (to provide complex amino compounds, present in proteins) were tested; none of these factors contributed appreciably to the stabilization of these pigments.

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In brief, the results indicate that there is an important decrease in color for all pH's, at temperatures above 60ºC, and that in higher pHs (near neutrality), the pigment is more stable. These results are in accordance with those reported by Fabre (1993) and Lee (2000). Color degradation is common for natural pigments, and is therefore a major concern in coloring foods, frequently compensated by proper dosage of the pigment. Despite its poor stability, Monascus compares well with other natural pigments, so that these pigments are still a promising color additive.

CONCLUSIONS

The results obtained show that the isolate LPB 31 is a Monascus sp strain with growth ability equivalent or superior to other tested strains, either in cassava bagasse or in rice, in glass flasks. The amount of citrinin produced by this strain is inferior to the amount found in a commercial standard. The pigment production and the productivity were superior to other strains, except the commercial sample (with a production 13% smaller), so that it may be concluded that the strain LPB 31 is adequate for the industrial production of Monascus biopigments over rice. Therefore, this strain was selected for subsequent assays, regarding the development of bioprocesses for production of red biopigments.

The biopigments obtained by Monascus were assayed for its stability towards pH and temperature, and it was found that these pigments are unstable at low pH's and high temperatures, so that they should be used in applications in processes with temperatures inferior to 60°C and pH's near neutrality. This pigment is especially adequate for application in dry or refrigerated foods, in which case color degradation is low, or in alcoholic beverages, in which the color degradation may not be observed in several months.

Received: September 23, 2004;

Revised: April 08, 2005;

Accepted: August 03, 2005.

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*

Author for correspondence

Publication Dates

Publication in this collection
20 Jan 2006
Date of issue
Nov 2005

History

Accepted
03 Aug 2005
Received
23 Sept 2004
Reviewed
08 Apr 2005

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

[1] Allok and CO (2003), Disp. in: http://www.allok.com Access in: 10 oct. 2003.

[2] ATCC (American Type Culture Collection) (1987), Catalogue of Fungi/Yeasts 17^th ed. Maryland: ATCC.

[3] ATCC (American Type Culture Collection) (2004), Online catalog Disp. in: http://www.atcc.org Access in: 03 sept. 2004.

[4] Betina, V. (Ed.) (1984), Mycotoxins - production, isolation, separation and purification. Amsterdam: Elsevier. pp. 217-236.

[5] Blanc, P. J.; Loret, M. O. and Goma, G. (1995), Production of citrinin by various species of Monascus Biotech. Lett, 17 : (3), 291-294.

[6] Blanc, P. J.; Laussac, J. P. and Goma, G. (1995a), Characterization of monascidin A from Monascus as citrinin. Int. J. Food Microbiol, 27, 201-213.

[7] Carvalho J. C., (2004), Desenvolvimento de bioprocesso para a produção de pigmentos a partir de Monascus por fermentação em substrato sólido. Tese (Doutorado), UFPR, Brasil.

[8] Broder, C. V. and Koehler, P. E. (1980), J. Food Sci, 45, 567-569.

[9] Chiu, S. W. and Poon, Y. K. (1993), Submerged production of Monascus pigments. Mycologia, 85 : (2), 214-218.

[10] Fabre, C. E.; Goma, G. and Blanc, P. J. (1993), Production and food applications of the red pigments of Monascus ruber. J. Food Sci, 58 : (5), 1099-1110.

[11] Johns M. R. and Stuart D. M. (1991), Production of pigments by Monascus purpureus in solid culture. J. Ind. Microbiol, 8, 23-38.

[12] Jozlová, P.; Martínková, L. and KYen, V. (1996), Secondary metabolites of the fungus Monascus: a review. J. Ind. Microbiol, 16, 163-170.

[13] Kim, H. J.; Kim, J. H.; Oh, H. J. and Shin, C. S. (2002), Morphology control of Monascus cells and scale-up of pigment fermentation. Proc. Biochem, 38, 649-655.

[14] Lee, Y. K. and Chen, D. C. (2000), Applications of Monascus pigments as food colorant. Disp. in: http://www.allok.com/literature Access in: oct. 2000.

[15] Lin, T. F. and Demain, A. L. (1992), Formation of water-soluble Monascus red pigments by biological and semi-synthetic processes. J. Indl. Microbiol, 9, 173-179.

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