Usage of HPLC explained

Picture of a HPLC system

Several analytical methods for quantitative detection of melamine using High Performance Liquid Chromatography have been developed and proposed as it has been proven to be a widely accepted for the analysis of biological matrices, pharmaceutical preparations due to its high efficiency and good reproducibility. Thus, it can be used for quantitative detection of most other compounds and not only melamine, making it extremely useful in the food safety industry. 

It is suitable for a variety of complex food and environmental material, has high sensitivity, high specificity, short detection time, low cost and requires minimal sample preparation. In this case, an ion exchange chromatography is performed for separation of charged molecules. HPLC also allows for analysis of large number of samples without degradation in column performance. Low noise is observed which proves its effective clean-up procedure for complicated matrices. As such, it is a highly useful tool for real-time analysis of routine melamine contamination monitoring.

To add on to the above, melamine is non-volatile, able to dissolve in aqueous solvent and thermally unstable (degrades upon heating) which fulfils the HPLC sample criteria.

The UV detector also had a set optimal wavelength of 240nm which gives a satisfactory retention of melamine, good peak shape and high sensitivity.

It should be noted that liquid chromatography/mass spectrometry (LCMS), gas chromatography (GC) and gas chromatography/mass spectrophotometry (GCMS) and capillary electrophoresis can also be used to detect melamine in infant formula and milk-based products but most of the aforementioned methods require expensive, complicated instruments and time-consuming sample pre-treatment (e.g. derivatisation or extraction).

Reference:
>> Der Pharma Chemica, 2012. Identification and Determination of Melamine in Milk by High Performance 
Liquid Chromatography – UV Detector. [online] Available at: <http://derpharmachemica.com/vol4-iss2/DPC-2012-4-2-737-748.pdf> [Accessed 27 January 2013]

Image obtained from:
>> https://us.vwr.com/store/catalog/product.jsp?product_id=6957154

How was the melamine detected?

Melamine in milk products were detected using High Performance Liquid Chromatography (HPLC) coupled with a UV detector. The protocol is as follows:

Apparatus:

1. HPLC-UV detector

2. HPLC Symmetry C18 (5 um, 3.9X 20 mm) Guard Column

3. HPLC Symmetry C18 (5 um, 4.6X 250 mm) Analytical Column

4. Solid-phase extraction (SPE) column

5. 100ml Volumetric Flask

6. 25ml Volumetric Flask

7. 50ml Centrifuge Tube

8. Vortex Shaking Machine

9. Ultrasonic bath

10. Centrifuge Machine

11. Filter Paper

Reagents:

1. Milk powder (e.g. 7 different varieties of powdered milk samples collected in this experiment)

2. Melamine (50% v/v)

3. Sodium 1-octane sulfonate (HPLC grade)

4. Methanol (HPLC grade)

5. Trichloroacetic acid

6. Citric acid monohydrate

7. Ammonia solution

8. Acetonitrile

9. DI water

HPLC system of Analysis (Summary)

Quantitative analysis:

- HPLC Waters system equipped with pump, guard column and analytical column.

- Water column heater with water temperature control system, UV-Vis Detector and waters automated gradient controller associate with computer system using Empower software

à Run and control all the calculations for the instrument.

The concentrations of the products were determined from the peak areas under the curve using the software for instrument control and data collection and processing. Solid phase extraction was performed thereafter. Before the quantitative and qualitative determination of melamine in the milk (infant milk samples), standard solutions of different standard concentrations were prepared. With those standard solutions of different melamine, calibration lines were constructed for each one of the melamine, which were later used for assessing the concentration corresponding to the different peaks in the chromatograms.

HPLC operating conditions:

v  Column used: HPLC Symmetry C18 (5 um, 3.9X 20 mm) Guard Column, HPLC Symmetry C18 (5 um, 4.6X 250 mm) Analytical Column

v  Column Temp: 50^oC

v  Flow Rate of mobile phase: 1ml/min

v  Injection Volume: 20ul

v  UV Detection: 240nm

v  Oven Temperature: 50 ^oC

Methods:

1. Preparation of standard of Melamine:

1.       100g of Melamine was dissolved with aqueous methanol in a 100ml volumetric flask. This forms  1000ug/ml melamine stock standards. Label as 'Melamine Stock Standard'.

2.       For calibration graph, stock standard was diluted appropriately to prepare working standards with concentrations of:

v  0.01ug/ml (10 000x dilution)

v  1.00ug/ml (1000x dilution)

v  2.00ug/ml (500x dilution)

v  5.00ug/ml (200x dilution)

v  10.00ug/ml (100x dilution)

v  50.00ug/ml (20x dilution)

2. Preparation of mobile phase:

1.      Buffer of 2.10 g citric acid and 2.16 g HPLC grade sodium 1-octane sulfonate were dissolved in 980 ml DI water and two ranges of pH were tested 4.5 and 3.0 the volume brought to one litter after the pH was adjusted by sodium hydroxide.

2.       920 ml of the list solution was taken and mixed with 80 ml Acetonitrile. The ratio is 92:8 (volume to volume) used for the isocratic separation mode for melamine.

3.       In the same manner, another ratio of the mobile phase buffer solution to acetonitrile (85:15) was  prepared and studied as well.

3. Sample preparations

- Food samples are typically complex matrices that are difficult to analyze due to abundance of proteins and carbohydrates

à These complex matrixes may affect the detection and enrichment of analytes

à Isolation and extraction of melamine and analogs from complex matrices is hence necessary prior to melamine determination.

- Main objectives of sample treatment (i.e. extraction, pre-concentration, and derivatization):

à To achieve lower limits of detection by removing matrix constituent

à Most sample-preparation procedures require extraction followed by one or more clean-up steps that can take from ten minutes to hours due to the complexity of the matrices.

1.       Milk powder sample blank control, free from any addition of melamine.

Label Sample ___ BLANK.

2.       Sample is spiked with 20 ul of stock standard solution and is accurately weighed into 50-ml centrifuge tubes.

3.       Add 15 ml of aqueous trichloroacetic acid and 5 ml acetonitrile into sample.

4.       Vortex sample for 1 minute.

5.       Sonicate sample in ultrasonic bath for 30 minutes.

6.       Vortex sample for 15 minutes.

7.       Centrifuge sample for 30mins @ 6000 RPM.

8.       Filter supernatants into 25 ml volumetric flasks through filter paper.

9.       Samples were brought to volume of 25ml with DI water. Label Sample ___ SPIKED.

10.       Repeat steps with all 7 milk powder samples.

4. Fortified Sample Preparation

1.       Weigh 1g milk powder sample into 50ml centrifuge tube

2.       Add 5 ml of HPLC methanol and 5 ml of DI water into the sample centrifuge tube.

3.       Vortex sample for 1 minute.

4.       Sonicate sample in ultrasonic bath for 30 minutes.

5.       Add 10 ml of 1% trichloroacetic acid to sample (1 gram in 100 ml DI water).

6.       Vortex sample for 1 minute.

7.       Sonicate sample in ultrasonic bath for 15 minutes.

8.       Centrifuge sample for 30mins @ 6000 RPM.

9.       Transfer supernatants to 25 ml volumetric flasks and fill flask to 25ml with DI water.

10.   Filter solution through a 0.45 um desk filter.

11.   Same dilution was made to bring the concentration of the sample within the range of the calibration curve.

12.   Repeat steps with all 7 milk powder samples.

5. Solid-phase extraction (SPC) for milk samples

1.       SPE column was activated prior usage by passing 3 ml of methanol and 5ml water in turn.

2.       Mixture of 5 ml sample extract and 5 ml DI water was passed through the activated SPE.

3.       Wash SPE with 3 ml methanol, then 3 ml DI water.

4.       Filter samples with 0.45 um desk filter before injection.

5.       The elution carried out with 6 ml aminated methanol solution freshly papered by mixing of 5 ml ammonia solution and 95 ml methanol.

6.       Collect eluent and dry at 50 ^oC

7.       Re-dissolve eluent in 1 ml of the mobile phase.

8.       Repeat steps with all 7 milk powder samples.

Reference:
>> Der Pharma Chemica, 2012. Identification and Determination of Melamine in Milk by High Performance 
Liquid Chromatography – UV Detector. [online] Available at: <http://derpharmachemica.com/vol4-iss2/DPC-2012-4-2-737-748.pdf> [Accessed 21 January 2013]

Melamine - the nitty-gritty (FAQs)

What is melamine?

Chemical structure of melamine 

Melamine (1,3,5-triazine-2,4,6-triamine) is a commercial organic basic constructed from urea with an intermediate step that produces cyanic acid and other by-products including cyanuric acid, ammeline and ammelid. It is 66% nitrogen by molecular weight and usually combined with formaldehyde to produce melamine resin (durable plastic) and melamine foam (polymeric cleanser) in the industry. Products that contain melamine include countertops, dry erase boards, fabrics, glues, housewares and flame retardants, inks among many others. In addition, it is a derivative of arsenical drugs (e.g. Melarsoprol – used to treat trypanosomiasis) and can be used in fertilizers. Cattle were once fed feed containing melamine as a nitrogen source but it has since been proven to be ineffective due to slow hydrolysis in ruminants.

Why was melamine added to milk products?

This was done in order to boost protein content of milk products when tested by the Kjeldahl method which tests nitrogen in all organic nitrogenous compounds. With every addition of 1g of melamine to 1L of milk, the protein content is falsely increase by 0.4%. This can be used to pass quality checks of such products before consumer market distribution even if the milk product produced itself does not have a high protein content.

Workings of the Kjeldahl method: nitrogen in the assay reacts with sulfuric acid to form ammonium sulfate. Small amounts of sodium hydroxide are added to covert ammonium salt back to ammonia. Ammonia is reacted with sulfuric acid again, and the remaining acid is quantified by adding sodium carbonate with a methyl orange pH indicator to quantify the amount of ammonium salt.

How does it adversely affect consumers?

While some remained asymptomatic, most had urinary stones, dysuria, difficulty in urination, renal coli and hematuria while more severe cases experiences hypertension, edema and oliguria. However, when combined with cyanuric acid (may also be present in melamine powder as it is a by-product of melamine synthesis), gives rise to crystals that lead to development of kidney stones that block the small tubes in the kidney and stop production of urine which lead to kidney failure and eventually, death. It is also interesting to note that while melamine has also been proven to have carcinogenic effects in animals, there is no sufficient evidence that it affects humans in the same way.

Dilated distal cat tubule with melamine/cyanuric acid crystals (A) and fragmented crystals (B) respectively

Is there treatment for kidney stones and kidney failure?

Depending on the severity of the effects, treatment may include infusion of fluids, urine alkalinisation, correction of electrolyte and acid-base disturbance, haemodialysis, peritoneal dialysis or surgical removal of kidney stones.

References:
>> Journal of the American Society of Nephrology, 2009. Melamine Toxicity and the Kidney. [online] Available at: <http://jasn.asnjournals.org/content/20/2/245.full?sid=301c79ef-7aab-4d0a-8981-a5994124434c> [Accessed 25 January 2013]
>> World Health Organization, 2013. Questions and Answers on Melamine. [online] Available at: <http://www.who.int/csr/media/faq/QAmelamine/en/index.html> [Accessed 25 January 2013]
>> U.S. Food and Drug Administration, 2011. Melamine in Tableware: Questions and Answers. [online] Available at: <http://www.fda.gov/Food/ResourcesForYou/Consumers/ucm199525.htm> [Accessed 25 January 2013]

Images obtained from:
>>http://jasn.asnjournals.org/content/20/2/245.full?sid=301c79ef-7aab-4d0a-8981-a5994124434c

Melamilk - the scandal

In 2008, China made an extra headline news (besides the Beijing Olympic Games) it was not expected to make.

It all started with a sudden increase among babies becoming ill and having signs of kidney damage and kidney stones. It was later found out that these babies had something in common - drinking Sanlu milk powder, a product in the Chinese market that was cheap and popular.

Sanlu infant formula on shelves before scandal

The company producing the milk powder, Sanlu Group, eventually admitted the formula contained toxic chemical melamine, added to make a formula with higher protein content. To make matters worse, around 50,000 people fell ill and four infant deaths were reported as a result of the contamination along with the snowballing scandal.

However, the scandal did not just end at Sanlu milk powder. A thorough inspection by the Chinese health officials were carried out over a wide spectrum of baby milk powder makers and other dairy products (e.g. liquid milk, eggs) which turned up traces of melamine in 22 companies. Many of such popular products included Cadbury chocolate and White Rabbit sweets. These products were called off the shelves. Enraged consumers who have lost their children to melamine contamination also took matters into their own hands by holding protests and suing companies for compensation.

Protesters with signs that read 'return my child' and 'request for justice'.

It eventually amounted to the United Nations issuing a report urging China to better educate and train food industry officials and government enforcement agencies. Several countries have also gone as far as to terminate imports of all Chinese dairy products.

To counter worldwide lash back, new dairy safety standards were released by China limiting the amount of melamine in products to 1mg of melamine per kg of infant formula and 2.5mg of melamine per kg of liquid milk, milk powder and food products containing at least 15% milk. When U.S. Food and Drug Administration (FDA) stated that no amount of melamine is safe in baby formula, the Chinese government said that no melamine has been found in products after the release of new quality standards.

References:
>> About.com, 2008. Summary of China's Tainted Milk Scandal. [online] Available at: <http://chineseculture.about.com/od/2008milkscandal/a/Milksummary.htm> [Accessed 25 January 2013]
>> BBC, 2010. Timeline: China Milk Scandal. [online] Available at: <http://news.bbc.co.uk/2/hi/7720404.stm> [Accessed 25 January 2013]

Images obtained from:
>> http://www.vanblumreich.com/blog/2009/03/31/why-people-steal-music/comment-page-1/
>> http://english.cri.cn/4026/2008/09/13/1481s405175.htm
>> http://s.wsj.net/public/resources/images/OB-CZ641_cmilk0_D_20090122045711.jpg