Effect of Methodology on the Determination of Total Volatile Basic Nitrogen as an Index of Quality of Meat and Fish

Document Type : Original Articles

Authors

Abstract

Determination of TVB-N values expressed as mg /100g of fresh meat and fish using four different methods (Conway’s Microdiffusion; Direct water vapor distillation with MgO; water vapour distillation of an acidic extract using Perchloric acid 6% and vapour distillation of an acidic extract using trichloroacetic acid 7.5%) were evaluated during storage in refrigerator till the beginning of spoilage. The results revealed that there was an increase in the level of TVB-N during storage of fresh meat from 4.03±0.152, 6.72±0.37, 6.18±4.59 and 6.62±0.7 at 1st day to 43±0.31, 50.08±0.5, 47.1±0.32 and 47.8±0.33 at 11th day, respectively and the mean values of TVB-N mg/100g of fresh fish were 5.03±1.12, 7.71±0.58, 7.14±0.47 and 6.42±0.43 to 66.5±0.39, 73±0.1, 70.67±1.48 and 70.2±1.04 respectively.  Direct water vapor distillation with MgO yielded the highest concentration of TVB-N, whereas the lowest TVB-N value was obtained with the Conway’s Microdiffusion method. The accuracy % of detection of nitrogen in mg/100g from 100ml standard solution contained 210.9 mg nitrogen using the four methods were 64.84, 69.43, 99.81 and 100.73 respectively.

Introduction

Volatile amines are the characteristic molecules responsible for the fishy odor and flavor present in fish several days after the catch and they are commonly used as criteria for assessing the fish quality. The determination of TVB-N known as to be the most common chemical parameter applied to evaluate the quality of fish and other meat products. TVB-N, being a measure of all the volatile nitrogen–containing compounds present in samples via steam distillation (Chan et al., 2006). Total Volatile Base Nitrogen (TVB-N) is one of the most widely used methods today to estimate the degree of decomposition of fish. It includes the measurement of trimethylamine (produced by spoilage bacteria), dimethylamine (produced by autolytic enzymes during frozen storage), ammonia (produced by the deamination of amino-acids and nucleotide catabolites) and other volatile nitrogenous compounds associated with seafood spoilage (Malle and Poumeyrol, 1989 and Riquixo, 1998). DMA and TMA results of the degradation of TMAO, a fish typical molecule which has an important role in osmoregulation, DMA is mostly produced by endogenous enzymes and TMA by bacterial enzymes (Huss, 1995; Etienne, 2005 and Chebet Lillian, 2007).

Ali et al., (2010) reportedthattheSpoilage was the result of whole series of complicated deteriorative changes brought about in dead fish tissue by its own enzyme, by bacteria and by chemical action (Shewan, 1976). The early reaction of spoilage is autolytic and bacterial enzymes become progressively the more active in the later stages (Jones, 1954). After catching the fish, the oxygen supply in the tissue ceases due to disruption of the circulatory system. In short time of post-mortem, the mitochondrial system ceases to function. Adenosine triphosphate (ATP) is gradually depleted through the action of various ATPase. After residual supplies of creatine phosphate have been depleted, anaerobic glycolysis continue to regenerate some ATP with the end product, lactate accumulation (Foegeding et al., 1996).  Due to formation of lactic acid from glycogen by a series of enzymatic reaction in the tissue which decrease pH value. When the pH reaches a critical value, the ultimate pH, certain critical enzymes, especially phosphorfructokinase, are inhibited and glycolysis ceases.  A drop in the pH of the muscle triggers the release of proteolytic enzymes such as cathepsin. Enzymes from spoilage microorganisms can metabolize the amino acids of the fish muscle producing a wide variety of volatile compounds resulting off-flavors and odors. The combined total amount of ammonia (NH3), dimethylamine (DMA) and trimethylamine (TMA) in fish is called the total volatile base (TVB) nitrogen content of the fish and is commonly used as an estimate of spoilage. Total volatile nitrogen has been widely used as an index for freshness of fish. The increase in the amount of TVB parallel with the increase in TMA during spoilage. As the activity of spoilage bacteria increases after the death of a fish, a subsequent increase in the reduction of TMAO to TMA (Stansby et al., 1944).

Etienne, (2005) reported that The total volatile base nitrogen or total volatile bases noted TVB-N or TVB or TVN consists mainly of a mixture of ammonia, DMA and TMA plus amines from the decarboxylation of amino acids and other nitrogen compounds that become volatile when made alkaline, and the results of analysis are given in nitrogen equivalent, ammonia-N, DMA-N, TMA-N and TVB-N. The designation "volatile amines" regroups mostly three molecules, ammonia, dimethylamine (DMA) and trimethylamine (TMA). Also they reported that TVB-N is an indicator of spoilage of some fish species such as red fish, flat fish, gadoids, hake and Atlantic salmon. However TVB-N cannot be used as a freshness indicator (constant level during the first days of iced storage) and does not reflect the mode of spoilage.  Huss, (1995) reported that the ammonia is formed by the bacterial degradation/deamination of proteins, peptides and amino-acids. It is also produced in the autolytic breakdown of adenosine monophosphate (AMP) in chilled seafood products. Although ammonia has been identified as a volatile component in a variety of spoiling fish, few studies have actually reported the quantification of this compound since it was impossible to determine its relative contribution to the overall increase in total volatile bases.  Chebet Lillian, (2007) saidthatthedetermination of TVB-N in fish flesh can be measured by steam distillation of fish extract with subsequent titration against a strong acid, such as sulphuric acid (H2SO4). However, according to Huss (1995) TVB-N concentrations may be affected by the mode of handling during the analysis, and they are often destructive in application. Byrne, et al., (2002) interested in developing rapid methods to evaluate fish freshness by using general quality indicators and has stated that microbial, chemical, biochemical or other instrumental methods are all appropriate methods for determination of fish freshness, and the analyses must be convenient, fast and inexpensive to perform, and TVB-N levels have been recognized as useful indicators of seafood spoilage.  Hebard et al. (1982) discussed the analysis of amines and TVB and their suitability as indices of quality.  Howgate, (2010) assumed  that the chemical test with the longest history of use as an indicator of freshness is measurement of the amount of basic compounds recovered by distilling fish muscle, or extracts of fish muscle, under alkaline conditions. The amount of these bases is almost invariable expressed on a nitrogen basis. TVB can be determined by distillation methods, a direct water vapour distillationmethod (Antonocoupoulos, 1968, FAO, 1979, Woyewoda, et al., 1986, Halland and Najaa 1988, Antonocoupoulos and Vyncke, 1989, AOAC 2003, Egyptian Standards, 2006 ) or a water vapour distillation of an acidic extract made with aqueous perchloric or trichloracetic acid (Codex Alimentarius Committee in 1969, Billon et al., 1979, Pearson, 1981, Stockemer and Kruse, 1985,  Antonacopoulos and Vyncke 1989, Malle and Poumeyrol 1989  and  European Commission 2005). The microdiffusionof an acidic extract (Conway and Byrne, 1933, Conway, 1957 and, 1962, Aksnes, 1989, FAO, 1979) is also used.

The European Commission decision (2005) has specified the analysis methods to be used: a referenceprocedureinvolving preliminary deproteination with perchloric acid followed by a water vapour distillation of the acidic extract and three others routine methods that may be used, the microdiffussion method described by Conway and Byrne (1933), the direct distillation method (Antonacopoulos, 1968) and the distillation of an extract deproteinesed by trichloroacetic acid (Codex Alimentarius Committee on Fish and Fishery Products, 1968).

Hu et al., (1991) illustrated that the amines extraction need a destruction of cellular structures and a protein precipitation by acids. Then, the amines could be recovered into an organic solvent or into a solvent mixture with different polarities. At acid pH, amines are dissolved in the hydrophilic phase. However, at alkaline pH, amines change their polarity. A migration to lipophile phase is observed. An evaporation of organic phase could let a concentration of amines. For these reasons, an extraction with organic solvents and at alkaline pH will be used to facilitate the concentration and to minimize the wastage (Rosier and Van Peteghem, 1988; Lebiedzinska et al., 1991). Nucleotides In parallel, to the previous methodology, it is necessary to develop a rapid technique to study the degradation of nucleotides. A cellular structure disruption and a protein precipitation with acids are necessary. Perchloric or trichloroacetic acids could be used. Then, neutralization with NaOH or KOH is necessary to adjust the pH between 6.4-7.8. To achieve nucleotides detection, a column of ionic interchange or reverse phase will be used).

Material and Methods

Twenty samples from each of fresh meat and  fresh fish  were purchased from local markets in Giza and stored at refrigerator  temperature 4 ±1˚C till the beginning of spoilage and examined for determination of TVB-N with 4 different methods at 1st, 3rd, 5th, 7th …….day of storage.

DETERMINATION OF TVB-N IN FOOD SAMPLES BY:

Method 1: Conways Microdiffusion Method according to FAO, 1979:

Twenty five grams of sample were homogenated with 75ml distilled water and the pH was brought to 5.2 with 2M HCL then heated slowly to 70C˚ and cooled at room temperature, the mixture was filtered. Two ml 0.01 M HCL were added into the center compartment of the Conway dish, 2ml of the filtrate were added into the outer compartment with 1ml of saturated potassium carbonate. The dish was covered with a glass plate and left at 37 C˚ for 2 hours. The HCL was titrated with 0.01 N NaOH using 2 – 3 drops of methyl red indicator.

Calculation

Mg TVB-N/100g sample = 0.01 x (2-t) x 96 x 14 x100/25x2 = 26.88 (2 – t)

t= volume of NaOH used in titration.

96 is taken to be the amount of water (in ml) in which the sample weight was dispersed, assuming that the 25g of chopped fish contained 4g of dry matter.

Method 2: Direct water vapor distillation method according to Egyptian Standards, ES 2760-1 and 63-9/ 2006:

Ten g of sample were weighed with 0.01 g accuracy and straight into the distillation bottle, 2 g of MgO (magnesium oxide) were added and 300 ml of distilled water (the water was added in small portions to avoid lumps of fish).

Distillation flask was arranged in the distillation apparatus. A collection flask with 25 ml of Boric acid 2% was placed under the tube from the cooling coil. Take care that the end of the tube was immersed in the boric acid. Distillation was started and continues for 15 min.

Titration

The contents of the collection flask were titrated from green to grey with 0.1 N H2SO4.

Calculations

TVB-N mg N/100g = (ml x N x 14.01) / g x 100

ml = ml of H2SO4 titrated

N =strength of H2SO4

g = weight of sample (10g)

14.01 molecular weight of Nitrogen

Method 3: water vapor distillation of an acidic extract (Perchloric acid 6%) according to European Commission (2005):

The sample to be analyzed was ground carefully by a meat grinder.  Exactly 10 g ± 0,1 g of the ground sample were weighed in a suitable container, mixed with 90 ml perchloric acid solution 6%, homogenized for two minutes with a blender and then filtered. Steam distillation of 50 ml of the extract after sufficient alkalinization with NaOH 20% (6.5 ml) and addition of several drops of phenolphthalein (1 g/100 ml 95 % ethanol) and a few drops silicone anti foaming agent began immediately. The steam distillation was regulated so that around 100 ml of distillate were produced within 10 minutes. The distillation outflow tube was submerged in a receiver with 100 ml boric acid solution 3% to which three to five drops of the indicator solution, Tashiro Mixed Indicator (2 g Methyl - red and 1 g Methylene - blue are dissolved in 1000 ml 95 % ethanol) have been added. After exactly 10 minutes the distillation was ended. The volatile bases contained in the receiver solution were determined by titration with standard hydrochloric solution 0.01M till the pH 5.0± 0.1

Calculation:

TVB-N (mg/100 g sample) = (V1 - V0) × 0.14 × 2 × 100/ M

V1 = Volume of 0.01 M hydrochloric acid solution in ml for sample;

V0 = Volume of 0.01 M HCL solution in ml for blank; M = Weight of sample in g.

Blank: Instead of the extract, 50 ml perchloric acid solution 6% was used.

Method 4: water vapour distillation of an acidic extract (trichloroacetic acid 7.5%) according to Malle and Poumeyrol (1989):

Briefly, 200 ml of a 7.5% aqueous trichloroacetic acid solution were added to 100 g of fish muscle and homogenized in a blender. The mixture was filtered through Whatman filter paper. Steam distillation of 25 ml of filtrate was performed using a Kjeldahl-type distillator with addition of 6 ml of 10% NaOH. A beaker containing 10 ml of 4% boric acid and 0.04 ml of methyl red and bromocresol green indicator was placed under the condenser for the titration of ammonia. Distillation was started and steam distillation continued until a final volume of 50 ml was obtained in the beaker (40 ml of distillate). The boric acid solution turned green when alkalinised by the distilled TVB-N which was titrated with aqueous 0.0125 M sulphuric acid solution using a 0.05 ml graduated burette. Complete neutralization was obtained when the colour turned pink on the addition of a further drop of sulphuric acid. The TVB-N content was calculated by the following equation:

TVB-N mg/100g = 14mg/mol x a x b x 2 x 300 / 25ml

Where: a = ml of sulphuric acid. b = molarity of sulphuric acid.


Results and Discussion

Table (1): Mean values of TVB-N (mg/100g) of meat and fish with four different methods of determination during storage in refrigerator (n = 20):

Day of

storage

Method 1

Method 2

Method 3

Method 4

Meat

Fish

Meat

Fish

Meat

Fish

Meat

Fish

1st

4.03±0.152

5.03±1.12

6.72±0.37

7.71±0.58

6.18±4.59

7.14±0.47

6.62±0.7

6.42±0.43

3rd

8.06±0.1

5.376±0.21

10.5±0.48

9.06±0.34

9.15±1.48

8.4±0.73

9±0.37

8.4±0.33

5th

11.47±0.32

9.74±0.08

14±0.06

13.3±0.07

12.2±1.05

10.4±0.86

12.6±0.77

10.64±0.63

7th

20.16±0.09

20.16±0.33

23.4±0.61

23.52±0.04

19.82±1.34

21.53±0.9

19.76±0.54

22.3±0.92

9th

33.6±0.5

33.1±0.29

36.29±0.07

37.6±0.1

33.9±0.32

34.8±1.05

34.4±0.42

35±0.81

11th

43±0.31

66.5±0.39

50.08±0.5

73±0.1

47.1±0.32

70.67±1.48

47.8±0.33

70.2±1.04

                   

 

By comparing the results of Conways  Microdiffusion; Direct water vapor distillation with MgO;  water vapour distillation of an acidic extract using Perchloric acid 6% and vapour distillation of an acidic extract using trichloroacetic acid 7.5%  methods used for freshness evaluation of meat and fish kept at 4°C±1, (table 1, fig. 1 and fig. 2) it was observed that the  mean values of TVB-N mg/100g of fresh meat samples at 1st day were 4.03±0.152, 6.72±0.37, 6.18±4.59 and 6.62±0.7 respectively and the  mean values of TVB-N mg/100g of fresh fish were 5.03±1.12,  7.71±0.58, 7.14±0.47 and  6.42±0.43 respectively, these values increased gradually till spoilage occurred reach to 43±0.31, 50.08±0.5, 47.1±0.32 and 47.8±0.33 for fresh meat and 66.5±0.39, 73±0.1, 70.67±1.48 and 70.2±1.04 for fresh fish respectively on 11th day, so the TVB-N contents increased with increasing storage time and the all four methods were showed some deviations (Figures 1 and 2) also direct water vapor distillation with MgO method presented relatively higher results than other methods (6.72±0.37  and 7.71±0.58 mg/100g of fresh meat  and fresh fish samples respectively) but Conway  Microdiffusion method  produce the lowest results (4.03±0.152 and 5.03±1.12 mg/100g of fresh meat  and fresh fish samples respectively) at first day of storage. Homogenization of samples with trichloroacetic acid produces jelly like fluid which is difficult to be filtered and may need centrifugation.  Cann (1974) have found the increase in TVB-N to be low during the initial period of storage, with a rapid increase noted afterwards. Connell (1975) stated that TVBN content in shrimp has highly positive and highly negative correlation with storage time indicating that TVB-N is a good indicator of spoilage. .  Boee et al. (1982) working on the storage of shrimp and has observed that TVB-N increased evenly. Matches (1982) working on shrimp stored at 5 different temperature, found that TVB-N increased both with increase in time and temperature.  Clancy et al. 1995 reported that the TVN level increased during storage as monitored by all methods, especially after 8 – 9 days. The values after 15 days of storage ranged from 80 to 114 mg N/100g fish depending upon the method employed. Etienne, (2005) found that The TVB-N content increased slightly during the first days of storage, this slight increase may reflect the amines production by autolytic processes. Nevertheless in some experiments on small fishes as plaice or whiting during the first week of iced storage a decrease of TVB-N content has been observed, the some volatile amines, mainly ammonia, were leached out by the melting ice (Oehlenschläger, 1997 b).  After the early days of iced storage, the TVB-N content increases with a larger scattering of the values mostly produced by spoilage bacteria. TVB analyses reflect only stages of advanced spoilage of fish, they are considered unreliable for the evaluation of the fish freshness in the early stage of storage and they don't reflect the mode of spoilage, bacterial or autolytic (Oehlenschläger, 1992, 1997a, b, ;  Nunes et al., 1992, ; Huss, 1995  and Baixas-Nogueras et al. 2002). TVB is considered as useful parameter although it does not fully satisfy sanitarians and is therefore subjected to certain valid criticisms (Malle and Poumeyrol, 1989).  Gao, (2007) aimed to analyzed the influences of different pre-cooling methods, i.e. slurry ice (group B), CBC, (group C) (combined blast and contact freezing) and usage of cooling mats (group D), on the quality of fresh cod fillets during further storage at -1.5 ˚C and found that the comparison of TVN as a quality parameters of fresh cod showed that there was a good correlations with the evaluation of the quality of fresh cod. An increase in TVN was obtained throughout storage time in the four groups but there was not much difference in TVN observed at first 6 day in all groups. The formation of TVN was delayed during the 10 days of storage in groups B, C and D compared to group E. The highest TVN values were measured after10th day of storage. Liu et al., (2011) mentioned that the TVB-N content in meat samples was an important indicator for estimating meat freshness. During the storage, the changes of TVB-N content in four kinds of meat samples were increased and the samples stored for less than 7 days in decompression room. After 10 days, the rapid increase of TVB-N content suggested that the quality of all samples depressed significantly.

Martin, (1979) described the determination of volatile amines by distillation of the sample with magnesium oxide using kjeldahl macro-distillation unit and Conways diffusion cell and by semi-micro kjeldahl distillation apparatus using trichloracetic acid.  Botta et al., (1984) reported that the microdiffusion method with its low cost, simplicity and speed of use without loss of precision was the method of choice for TVN measurement, and found poor agreement among six published TVB procedures. Most depend upon either steam distillation of volatile amines or microdiffusion of an extract (Conway, 1962); the latter method is the most popular in Japan.  Clancy et al. (1995) analyzed herring for total volatile nitrogen (TVN) by each of four methods included microdiffusion with K2CO3 or KOH, steam distillation with NaOH, and with direct distillation with MgO and found a high correlation between methods (0.985 – 0.994) and the direct distillation  with MgO gave consistently higher values than other three methods, these may have occurred as a result of protein breakdown during atmospheric distillation (Pearson and Muslemuddin, 1968 ; 1969 ; Botta et al., 1984). Huss, (1995) said that although TVB analyses are relatively simple to perform, they generally reflect only later stages of advanced spoilage and results depend to a great extent on the method of analysis. Riquixo, (1998) investigated the suitable chemical methods for seafood products with respect to their accuracy and suitability for determination of freshness of fish in Mozambique. and found a good correlation between MgO and TCA-extract steam distillation methods for TVB determination also reported that the level of TVBN for white fish is generally considered to be fresh if the TVB is less 20 mg N/100 g sample. If the TVB reaches 30 mg N/100 g most authorities consider the fish to be stale, whilst at level of 40 mg N/100 g the fish is regarded as unfit for consumption. Erkan,(2005)  determined the  total volatile basic nitrogen (TVB-N) using6%perchloric acid and the  results were expressed as mg TVB-N per 100 g of wet sample.

Nitrogen Recovery Verification:

Quality control analysis was performed and analysis of standards with each procedure. The standards available from Sigma Aldrich Co., the ammonium sulfate serve as a check on distillation efficiency and accuracy in titration steps. Run nitrogen recoveries to check accuracy of each procedure and equipment using 1g ammonium sulfate dissolved in 100ml distilled  water,(100ml of water contain 210.9 mg nitrogen)  (Thiex and Manson, 2002) and Riquixo,  (1998)  all other reagents were added as stated in test portion preparation for each method.

% Recovery = Actual % Nitrogen x 100 /210.9

This experiment repeated 12 times, and the average was taken.

 

 

Table (2): Nitrogen Recovery Verification (n = 12):

 

Method 1

Method 2

Method 3

Method 4

Mean mg nitrogen

 recovered

136.74±1.33

142.2±1.08

210.5±0.36

212.44±2.6

Accuracy %

64.84

69.43

99.81

100.73

Table (2) and Fig (3) show the amount of nitrogen in mg/100g detected  from 100ml standard solution contained 210.9 mg nitrogen using four different methods  (Conway  Microdiffusion; Direct water vapor distillation with MgO;  water vapour distillation of an acidic extract using Perchloric acid 6% and vapour distillation of an acidic extract using trichloroacetic acid 7.5%  methods)  were 136.74±1.33, 142.2±1.08, 210.5±0.36 and 212.44±2.6 which produce  64.84,  69.43, 99.81 and 100.73 recovery and accuracy % respectively, where accuracy  is the closeness of the obtained  standards  to the true value and is usually stated in terms of recovery. Riquixo, (1998), European Commission (2005), Erkan, (2005)

CONCLUSION

In the comparison of four methods (Conway  Microdiffusion; Direct water vapor distillation with MgO;  water vapour distillation of an acidic extract using Perchloric acid 6% and vapour distillation of an acidic extract using trichloroacetic acid 7.5%  methods), it was found that all methods were sensitive need an experience personnel. Water vapour distillation of an acidic extract using Perchloric acid 6% is the quickest of the methods but using Perchloric acid need some precaution and application of chemical safety roles and the EuropeanUnion reported that the reference method to be used for checking the TVB-N limit is the method involving distillation of an extract deproteinized by perchloric acid.

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