Chromium speciation analysis for samples containing organic materials
(05.09.2024)
Chromium speciation analysis is crucial because Cr(VI) is highly toxic and carcinogenic, whereas trivalent chromium (Cr(III)) is generally considered less harmful and, in some cases, beneficial for the glucose metabolism. The toxicity of Cr(VI) is the reason for legislation meant to limit the human exposure. For this reason, different kind of samples from the human environment are analyzed for the presence of Cr(VI). As it is the case with all oxidation species, these species can be easily converted by changing pH and redox conditions during sampling and sample pretreatment. Sample pretreatment is challenging for solid samples, since chromium has to be extracted for most speciation techniques calling for liquid samples.
The speciation analysis of hexavalent chromium (Cr(VI)) in presence of organic materials is especially complex and challenging due to several factors:
1. Matrix Effects
Complex Organic Matrices: Organic materials, such as biological tissues, plants, or complex environmental samples (like soils rich in organic matter), contain a variety of organic compounds that can interfere with the extraction and detection of Cr(VI). These matrix components can bind to Cr(VI) or Cr(III), altering their speciation and making accurate quantification difficult.
Interference from Organic Compounds: Organic compounds in the sample can lead to various polyatomic interferences affecting chromium signal of ICP-MS detection.
2. Instability of Cr(VI)
Redox Instability: Cr(VI) is highly reactive and can be easily reduced to Cr(III) in the presence of reducing agents found in organic materials. This redox instability means that Cr(VI) can change its oxidation state during sample handling, storage, or analysis, leading to an underestimation of Cr(VI) levels.
pH Sensitivity: The speciation of chromium is pH-dependent. In organic matrices, pH variations can cause Cr(VI) to convert to Cr(III), especially under acidic conditions. Maintaining a consistent and appropriate pH during the extraction and analysis is challenging but crucial for accurate speciation.
Control of Environmental Factors: Temperature, light, and oxygen levels can affect the stability of Cr(VI) during sample preparation and analysis. Ensuring consistent environmental conditions is difficult but necessary to prevent speciation changes.
Storage Conditions: Cr(VI) can be unstable during storage, particularly in organic matrices that may contain reducing agents. Ensuring the preservation of Cr(VI) during storage (e.g., by freezing or adding stabilizers) is essential, but not always straightforward.
3. Analytical Challenges
Extraction Efficiency: Extracting Cr(VI) from organic materials without altering its speciation is challenging. Conventional extraction methods, such as using alkaline solutions, might not be effective for all types of organic matrices, or they may cause partial reduction of Cr(VI) to Cr(III).
Specificity of Analytical Techniques: The selectivity of extraction methods is not sufficient for differentiating Cr(III) from Cr(VI). Techniques like ion chromatography (IC) coupled with UV detection, or high-performance liquid chromatography (HPLC) coupled with inductively coupled plasma mass spectrometry (ICP-MS), are commonly used for Cr(VI) analysis. However, these techniques require careful calibration and method validation to distinguish between Cr(VI) and Cr(III) in complex organic matrices.
Detection Limits and Sensitivity: The sensitivity of the analytical method is critical, particularly when Cr(VI) is present at low concentrations in the presence of large amounts of Cr(III). Achieving low detection limits without compromising accuracy is a significant challenge.
Contamination and Analyte Loss: During sample preparation, contamination from laboratory equipment (e.g. metallic parts of the HPLC system) or reagents can introduce Cr(VI) or reduce Cr(VI) to Cr(III), skewing results. Additionally, improper handling can lead to the loss of Cr(VI) through volatilization or adsorption onto surfaces.
Lack of Certified Reference Materials: There is a shortage of certified reference materials for Cr(VI) in organic matrices. This lack of standards makes it difficult to validate methods and ensure accurate and reproducible results.
Summary
In summary, the speciation analysis of hexavalent chromium in organic materials faces significant challenges due to matrix effects, the instability of Cr(VI), analytical limitations, and issues related to sample preparation, storage, and method validation. Addressing these challenges requires careful optimization of extraction methods, strict control of environmental conditions, and the development of standardized protocols and reference materials.
Reports about the presence of Cr(VI) in biological materials such as body fluids (blood, milk, urine), food, plant materials, organic fertilizers, etc. often lack the necessary selectivity and fail to address the challenges mentioned above. On the other hand, researchers having used sophisticated methods for speciation analysis taking care for possible interconversions were often not able to detect Cr(VI) in such materials above the detection limit. Actually, spiking experiment have shown, that Cr(VI) added to such sample types gets reduced to Cr(III) in short time.
Michael Sperling
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