Summary

Quantification of Metal Leaching in Immobilized Metal Affinity Chromatography

Published: January 17, 2020
doi:

Summary

We present an assay for easy quantification of metals introduced to samples prepared using immobilized metal affinity chromatography. The method uses hydroxynaphthol blue as the colorimetric metal indicator and a UV-Vis spectrophotometer as the detector.

Abstract

Contamination of enzymes with metals leached from immobilized metal affinity chromatography (IMAC) columns poses a major concern for enzymologists, as many of the common di-and trivalent cations used in IMAC resins have an inhibitory effect on enzymes. However, the extent of metal leaching and the impact of various eluting and reducing reagents are poorly understood in large part due to the absence of simple and practical transition metal quantification protocols that use equipment typically available in biochemistry labs. To address this problem, we have developed a protocol to quickly quantify the amount of metal contamination in samples prepared using IMAC as a purification step. The method uses hydroxynaphthol blue (HNB) as a colorimetric indicator for metal cation content in a sample solution and UV-Vis spectroscopy as a means to quantify the amount of metal present, into the nanomolar range, based on the change in the HNB spectrum at 647 nm. While metal content in a solution has historically been determined using atomic absorption spectroscopy or inductively coupled plasma techniques, these methods require specialized equipment and training outside the scope of a typical biochemistry laboratory. The method proposed here provides a simple and fast way for biochemists to determine the metal content of samples using existing equipment and knowledge without sacrificing accuracy.

Introduction

Since its inception by Porath and co-workers1, immobilized metal affinity chromatography (IMAC) has become a method of choice to quickly separate proteins based on their ability to bond with transition metal ions such as Zn2+, Ni2+, Cu2+, and Co2+. This is most commonly done via engineered poly-histidine tags and is now one of the most common chromatographic purification techniques for the isolation of recombinant proteins2. IMAC has also found applications beyond recombinant protein purification as a way to isolate quinolones, tetracyclines, aminoglycosides, macrolides, and β-lactams for food sample analysis3 and as a step in identifying blood-serum protein markers for liver and pancreatic cancers4,5. Not surprisingly, IMAC has also become a method of choice for the isolation of a number of native bioenergetics enzymes6,7,8,9,10. However, successful implementation of these purification methods for studies on enzymatically active bioenergetic proteins is dependent on the presence of negligible levels of metal cations leached from the column matrix into the eluate. The divalent metal cations commonly used in IMAC have known pathologic biological significance, even at low concentrations11,12. The physiological effect of these metals is most pronounced in bioenergetic systems, where they can prove lethal as inhibitors of cellular respiration or photosynthesis13,14,15. Similar issues are unavoidable for the majority of protein classes where residual contaminant metals can interfere with a protein's biological functions or characterization with biochemical and biophysical techniques.

While the levels of metal contamination under oxidizing conditions and using imidazole as an eluant are typically low16, protein isolations performed in the presence of cysteine reducing agents (DTT, β-mercaptoethanol, etc.) or with stronger chelators like histidine17,18 or ethylenediaminetetraacetic acid (EDTA) result in much higher levels of metal contamination19,20. Similarly, since metal ions in IMAC resins are frequently coordinated by carboxylic groups, protein elutions performed under acidic conditions are also likely to have much higher levels of metal contamination. Metal content in solutions can be assessed using atomic absorption spectroscopy (AAS) and inductively coupled plasma-mass spectrometry (ICP-MS) down to a limit of detection in the ppb-ppt range21,22,23,24. Unfortunately, AAS and ICP-MS are not realistic means for detection in a traditional biochemistry lab as those methods would require access to specialized equipment and training.

Previous work by Brittain25,26 investigated the use of hydroxynaphthol blue (HNB) as a way to identify the presence of transition metals in solution. However, there were several internal contradictions in the data20 and those works failed to offer an adequate protocol. Studies by Temel et al.27 and Ferreira et al.28 expanded on Brittain's work with HNB as a potential metal indicator. However, Temel developed a protocol that makes use of AAS for sample analysis, using HNB only as a chelating agent. Ferreira's study used the change in the HNB absorbance spectra at 563 nm, a region of the free-dye HNB spectra that overlaps heavily with the spectra of HNB-metal complexes at pH 5.7, making the assay sensitivity fairly low as well as resulting in relatively weak metal binding affinity20. To address issues in our own lab with Ni2+ leaching from IMAC, we have expanded the work done by Brittain25,26 and Ferreria28 to develop an easy assay capable of detecting nanomolar levels of several transition metals. We showed that HNB binds nickel and other common for IMAC metals with sub-nanomolar binding affinities and form 1:1 complex over a wide range of pH values20. The assay reported here is based on these findings and utilizes absorbance changes in the HNB spectrum at 647 nm for metal quantification. The assay can be performed in the physiological pH range using common buffers and instrumentation found in a typical biochemistry lab by using colorimetric detection and quantification of metal-dye complexes and the associated change in absorbance of the free-dye when it binds to metal.

Protocol

1. Assay component preparation

  1. Determine the chromatography fractions to be assayed using optical absorbance at 280 nm or alternative methods of protein quantification to identify the protein enriched fractions.
    NOTE: For this work, we used a diode array UV-Vis spectrophotometer. To increase throughput, a plate reader capable of measuring UV-Vis absorbance can be used.
  2. Preparation of necessary assay components
    1. Prepare or obtain 10-100 mM buffer ("Sample Buffer") with a pH between 7 and 12.
      NOTE: Common biochemical buffers such as Tris, HEPES, MOPS, and phosphate at neutral or basic pH are all acceptable for the assay. Tricine and histidine can be used but will require calibration curves as they both substantially chelate metal ions. An example of calibration for histidine is shown in reference20.
    2. Prepare a 12% w/v (20-fold concentrated) solution of hydroxynaphthol blue (HNB) dispersion in the Sample Buffer using 120 mg of HNB reagent for each milliliter of stock solution prepared.
      CAUTION: Exposure of HNB to the eye can cause serious damage and irritation. Eye protection should be used when handling HNB and hands should be washed thoroughly after handling.
      NOTE: HNB is sold as a dispersion on KCl by major suppliers of scientific reagents. As such, actual concentration in solution will vary from different manufactures, batches, and where in the bottle the HNB dispersion is taken from. Ideally, an absorbance between 0.5-0.8 at 647 nm after 20-fold dilution of the stock should be achieved.

2. Sample preparation and measurement

  1. Preparation of the spectrophotometer for data collection
    1. Turn on and warm up the UV-Vis spectrophotometer. Set the spectrophotometer to collect data at 647 nm.
      NOTE: If the spectrophotometer allows, additionally collect data at 850 nm, or some other wavelength without significant changes related to the dye-metal and dye spectra, to be used for a baseline correction.
    2. Blank the spectrophotometer using the Sample Buffer.
      NOTE: Quartz or disposable plastic cuvettes may be used. Quartz cuvettes are preferred for quantitative analysis as they will allow higher accuracy and precision over disposable plastic cuvettes. However, plastic cuvettes block UV light, which may be present in the measuring beams of some diode-array spectrophotometers. Exposure of HNB to intense UV light causes notable dye degradation and an unwanted slow absorbance decrease that can be confused with slow metal binding (for example, see Figure 1 in Supporting Information of Reference 20).
  2. Preparation and absorbance measurement of control
    1. Prepare a control solution containing 50 μL of HNB stock per milliliter of total assay volume. To ensure good mixing of all samples, pipette the small volumes first then add the Sample Buffer followed by mixing by pipetting. Diluted HNB solution should be prepared fresh but HNB stocks can be stored at 4 °C and shielded from light for weeks without significant degradation.
    2. Allow the control to incubate for a minimum of 3 min at room temperature.
      NOTE: A longer incubation time may be necessary for samples at alkaline pH or in the presence of phosphate due to formation of poorly soluble metal complexes resulting in slower equilibration.
    3. Measure and record the absorbance at 647 nm for the control sample.
  3. Preparation and absorbance measurement of samples
    1. Prepare the assay samples by mixing 50 μL of HNB stock with 950 µL of appropriately diluted protein fractions with the Sample Buffer.
      NOTE: Since metal contamination levels reported in literature vary by a factor of more than 1000 depending on elution conditions16,20, it may be necessary to try a few dilutions of the assayed protein fractions with the Sample Buffer (see step 1.2.1 above) to achieve absorbance changes within the dynamic range of the assay.
      CAUTION: Nickel and other metals used in IMAC are known skin irritant, suspected of being carcinogenic, and are capable of damaging the kidneys and blood after prolonged exposure. Gloves and eye protection should be used when handling protein samples prepared with IMAC.
    2. Allow the sample to incubate for a minimum of 3 min at room temperature and measure absorbances at 647 nm.
      NOTE: The limiting step of the assay in terms of time invested is the incubation step. The data for this paper was collected using a single quartz cuvette that was carefully washed between each sample. Even with the added washing time and preparation of the HNB stock, data collection for 14 samples and the control took approximately an hour and a half and as such, the protocol can be easily completed without the need for interruption.
    3. Repeat steps 2.3.1 and 2.3.2 for each fraction that will be measured.
      NOTE: If several cuvettes will be used for multiple samples, samples should be prepared in a way that allows for comparable incubation time and exposure to ambient light.

3. Metal quantification

  1. Determining the concentration of metal in each sample
    1. Find the difference of each sample absorbance at 647 nm from the HNB control.
    2. Determine the metal concentration (in µM) using the formula below:

      Equation 1

      where DF is the dilution factor for the assay fraction, ΔAbs647 is the absorbance change at 647 nm, 3.65×10-2 represents the extinction coefficient of HNB (ε=36.5 mM-1·cm-1 see Reference20 for more details) and l is cuvette's optical path in cm.

Representative Results

The spectrum of free HNB at neutral pH (black line) and representative spectra of fractions assayed for Ni2+ from the isolation of MSP1E3D129 are shown in Figure 2. A successful assay series should demonstrate a decreased absorbance at 647 nm compared to the HNB control, which corresponds to the formation of HNB complexes in the presence of a transition metal. A failed assay would be indicated by an increase in absorbance at 647 nm. Alternatively, more than 90% decrease from initial absorbance at 647 nm would indicate too high metal content and a need to assay more diluted fractions. An assay with no absorbance changes from the free HNB control does not necessarily indicate a failure. It is possible that samples contain essentially no leached metals. However, this is unlikely and any sample showing no absorbance change should be prepared and measured again, preferably with less dilution, to confirm the result. In total, most failures to observe the expected absorbance change can be attributed to improper pipetting during sample preparation, an inadequate incubation time prior to measurement, or pH values outside the recommended 7-12 range.

To demonstrate the application of this assay, we analyzed 2 His-tag membrane scaffold proteins MSP1E3D1 (isolated as in Denisov, I. G. et al.29), MSP2N2 (isolated as in Grinkova, Y. V.30), and a novel 3-heme c-type cytochrome GSU0105 from Geobacter sulfurreducens, which was recombinantly expressed in E.coli and eluted with 500 mM imidazole. The elution profiles of Ni2+ from a Ni-NTA resin column (see Table of Materials) and the associated protein elution profiles for these 3 proteins are shown in Figure 3. Any protein will have a unique nickel elution that may or may not align with the protein elution profile as measured at 280 nm. For example, Figure 3C shows that the protein and Ni2+ content of each fraction for GSU0105 are significantly shifted from one another while the fractions for MSP1E3D1 and MSP2N2 (Figure 3A,B) that contain the most protein also have the highest Ni2+ content. Figure 3A,B also illustrate that metal content may not be evenly distributed among fractions collected using IMAC. Depending on column packing, the composition of the elution buffer, pumping equipment and conditions, it is possible to have metal elute in consecutive fractions at very different concentrations independent of the protein content of those fractions.

Figure 1
Figure 1: Structure of hydroxynaphthol blue (HNB). In the functional pH range of the assay, all sulfonate groups and one of the hydroxyl groups are ionized. Please click here to view a larger version of this figure.

Figure 2
Figure 2: Absorbance spectra for selected MSP1E3D1 fractions and HNB. The relative absorbance of three fractions of MSP1E3D1 (colors) compared to an HNB control (black thick line) are shown. Samples were prepared in 20 mM Tris, pH 7.5. Please click here to view a larger version of this figure.

Figure 3
Figure 3: Ni2+ quantification for 3 representative His-tag proteins. Protein and Ni2+ elution profiles for (A) MSP1E3D1, (B) MSP2N2, and (C) GSU0105. Protein elution was performed using 300 mM, 300 mM, and 500 mM imidazole, respectively. Ni2+ quantification was performed in 20 mM Tris, pH 7.5. Please click here to view a larger version of this figure.

Discussion

Colorimetric detection of metals using HNB provides a simple way to quantify the degree of protein contamination by transition metal ions from IMAC resins. As we established in Ref. 20, Ni2+ binds to HNB with 1:1 stoichiometry and the dissociation constant for the Ni-HNB complex changes with pH. However, the complex Kd is in the sub-nM range for all recommended (7-12) pH values. In practical terms, it means that all Ni2+ in any tested fractions will bind to HNB as long as no other strong chelating reagents, like EDTA, are present. All these properties together result in linear Ni2+ titration curves, which we experimentally observed. In that report20, we also established that the spectral changes due to metal-dye complex formation will be the same over the entire 7-12 pH range. The detection is limited by the minimal reliable absorbance change measurements (10-4 – 10-3 OD depending on the spectrophotometer used) corresponding to 2.7-27 nM Ni2+. The upper range is limited by the amount of HNB present. In our work, we use ~15 µM, corresponding to ~0.6 OD at 647 nm. However, this can be increased up to 50-80 µM HNB, if needed. Practically, we observed Ni2+ contamination levels in chromatographic fractions comparable or higher than the upper limit forcing us to make 10- to 50-fold dilutions of assayed fractions. However, this additional dilution step can increase relative errors while determining the nickel concentration in a fraction.

Though we have not investigated the details, it appeared that binding of other metals used in IMAC resins (Co, Zn, Fe) also has sub-µM dissociation constants and virtually no overlap between dye and dye-metal absorbance spectra at 647 nm, the peak wavelength of free HNB. Therefore, complete metal binding to the dye and the associated spectral changes of the dye can be used for absolute metal determination over the entire recommended pH range.

Execution of the protocol is straightforward and depends most heavily on proper laboratory technique. Modern spectrophotometers have highly linear responses and dynamic ranges of 3-4 orders of magnitude. Consequently, the most likely place for the introduction of error in the method is through the pipetting steps for sample preparation. As described in this text, the method is based on the quantification of metal content based on the difference in the HNB absorbance peak at 647 nm from a free HNB control and samples with HNB complexed with a metal. If care is not taken to accurately pipette the HNB aliquots or the buffer volumes, comparison of the control and sample absorbances at 647 nm becomes a point of error. Similarly, poor pipetting of protein fractions for sample preparation can skew the perceived concentration of metal in a fraction. It is recommended that, due to the sensitivity of the assay, any pipettes being used for analyses where precise quantification is required be calibrated prior to use.

The primary limitations of the method come with the functional pH range of the assay and the presence of strong chelating agents. The assay is best utilized in a pH range from 7-12. Below pH 7, the spectrum of the free HNB dye changes, losing the peak at 647 nm used for quantification20. Above pH 12, many metal hydroxides begin to precipitate, including those of metals commonly found in IMAC resins, making quantification slower and less reproducible. While the alkaline maximum does not pose a significant problem as purification procedures rarely call for such a high pH, the acidic minimum is more likely to be a limiting factor. Since the detection limits for Ni2+ and other transition metals are approximately 1000-fold lower than metal contamination levels demonstrated above (Figure 3), the low pH limit for the assay can be circumvented by dilution of the assayed acidic protein fractions in buffers with neutral pH values and sufficiently high buffering capacity. Alternatively, the pH of analyzed fractions can be adjusted or the HNB stock solution can be more strongly buffered to maintain the desired pH after mixing.

If the isolation procedure for the protein being purified requires the use of reagents with known or suspected transition metal chelating properties, a modification of the method would be necessary to allow for proper quantification of leached metals. A standard curve would need to be prepared using the chelating agent used for protein elution and known concentrations of metal standards to accurately quantify the concentration of leached metal in the presence of the chelator. An example of metal quantification in the presence of histidine is available in Kokhan & Marzolf20.

Accurate quantification of metals in biological samples is still largely dependent on the use of analytical techniques and instrumentation, such as AAS and ICP-MS, that remain outside the realm of the typical biochemist31,32. Bonta et al. have described the simple preparation of biologic samples on common filter paper for analysis by ICP-MS, however, their method still relies on non-standard instrumentation for a biochemist31. The method we describe allows for the measurement of metal content in a sample to be taken without additional training on new instrumentation or outsourcing to others. Similar colorimetric protocols have been developed for metal analysis in biological samples33. However, the method described by Shaymal et al.33 relies on a fluorescence assay using a commercially unavailable fluorescent probe that gives a higher limit of detection than that in this paper. Considering the relative ease by which the described method can be performed and the recent interest in the development of portable metal detecting protocols for aqueous samples34,35, it could be easily adapted for field testing of water samples. As a portable test, our method could be modified for use with a portable spectrophotometer for quantification or as a qualitative measure to identify samples for further analysis at a fixed testing location.

Divulgations

The authors have nothing to disclose.

Acknowledgements

This material is based upon work supported by the National Science Foundation under Grant MCB-1817448 and by an award from the Thomas F. and Kate Miller Jeffress Memorial Trust, Bank of America, Trustee and specified donor Hazel Thorpe Carman and George Gay Carman Trust.

Materials

2xYT broth Fisher Scientific BP9743-500 media for E.coli growth
HEPES, free acid BioBasic HB0264 alternative buffer
HisPur Ni-NTA resin Thermo Scientific 88222
Hydroxynaphthol blue disoidum salt Sigma-Aldrich 219916-5g
Imidazole Fisher Scientific O3196-500
Imidazole BioBasic IB0277
MOPS, free acid BioBasic MB0360 alternative buffer
Sodium chloride Fisher Scientific S271-500
Sodium phosphate Fisher Scientific S369-500 alternative buffer
Tricine Gold Bio T870-100
Tris base Fisher Scientific BP152-500
Triton X-100 Sigma-Aldrich T9284-500

References

  1. Porath, J., Carlsson, J. A. N., Olsson, I., Belfrage, G. Metal chelate affinity chromatography, a new approach to protein fractionation. Nature. 258 (5536), 598-599 (1975).
  2. Block, H., et al. Immobilized-Metal Affinity Chromatography (IMAC): A Review. Methods in Enzymology. 463, 439-473 (2009).
  3. Takeda, N., Matsuoka, T., Gotoh, M. Potentiality of IMAC as sample pretreatment tool in food analysis for veterinary drugs. Chromatographia. 72 (1/2), 127-131 (2010).
  4. Felix, K., et al. Identification of serum proteins involved in pancreatic cancer cachexia. Life sciences. 88 (5-6), 218-225 (2011).
  5. Wu, C., et al. Surface enhanced laser desorption/ionization profiling: New diagnostic method of HBV-related hepatocellular carcinoma. Journal of Gastroenterology and Hepatology. 24 (1), 55-62 (2009).
  6. Goldsmith, J. O., Boxer, S. G. Rapid isolation of bacterial photosynthetic reaction centers with an engineered poly-histidine tag. Biochimica et Biophysica Acta (BBA) – Bioenergetics. 1276 (3), 171-175 (1996).
  7. Guergova-Kuras, M., et al. Expression and one-step purification of a fully active polyhistidine-tagged cytochrome bc1 complex from Rhodobacter sphaeroides. Protein Expression and Purification. 15 (3), 370-380 (1999).
  8. Mitchell, D. M., Gennis, R. B. Rapid purification of wildtype and mutant cytochrome c oxidase from Rhodobacter sphaeroides by Ni(2+)-NTA affinity chromatography. FEBS Letters. 368 (1), 148-150 (1995).
  9. Tian, H., White, S., Yu, L., Yu, C. A. Evidence for the head domain movement of the rieske iron-sulfur protein in electron transfer reaction of the cytochrome bc1 complex. Journal of Biological Chemistry. 274 (11), 7146-7152 (1999).
  10. Tian, H., Yu, L., Mather, M. W., Yu, C. A. Flexibility of the neck region of the rieske iron-sulfur protein is functionally important in the cytochrome bc1 complex. Journal of Biological Chemistry. 273 (43), 27953-27959 (1998).
  11. Louie, A. Y., Meade, T. J. Metal complexes as enzyme inhibitors. Chemical Reviews. 99 (9), 2711-2734 (1999).
  12. Tamás, M. J., Sharma, S. K., Ibstedt, S., Jacobson, T., Christen, P. Heavy Metals and Metalloids As a Cause for Protein Misfolding and Aggregation. Biomolecules. 4 (1), 252-267 (2014).
  13. Gerencser, L., Maroti, P. Retardation of proton transfer caused by binding of the transition metal ion to the bacterial reaction center is due to pKa shifts of key protonatable residues. Biochimie. 40 (6), 1850-1860 (2001).
  14. Klishin, S. S., Junge, W., Mulkidjanian, A. Y. Flash-induced turnover of the cytochrome bc1 complex in chromatophores of Rhodobacter capsulatus: binding of Zn2+ decelerates likewise the oxidation of cytochrome b, the reduction of cytochrome c1 and the voltage generation. Biochimica et Biophysica Acta (BBA) – Bioenergetics. 1553 (3), 177-182 (2002).
  15. Link, T. A., von Jagow, G. Zinc ions inhibit the QP center of bovine heart mitochondrial bc1 complex by blocking a protonatable group. Journal of Biological Chemistry. 270 (42), 25001-25006 (1995).
  16. Block, H., Kubicek, J., Labahn, J., Roth, U., Schäfer, F. Production and comprehensive quality control of recombinant human Interleukin-1beta: a case study for a process development strategy. Protein Expression and Purification. 57 (2), 244-254 (2008).
  17. Kokhan, O., Shinkarev, V. P., Wraight, C. A. Binding of imidazole to the heme of cytochrome c1 and inhibition of the bc1 complex from Rhodobacter sphaeroides: II. Kinetics and mechanism of binding. Journal of Biological Chemistry. 285 (29), 22522-22531 (2010).
  18. Kokhan, O., Shinkarev, V. P., Wraight, C. A. Binding of imidazole to the heme of cytochrome c1 and inhibition of the bc1 complex from Rhodobacter sphaeroides: I. Equilibrium and modeling studies. Journal of Biological Chemistry. 285 (29), 22513-22521 (2010).
  19. Bornhorst, J. A., Falke, J. J. Purification of proteins using polyhistidine affinity tags. Methods in Enzymology. 326, 245-254 (2000).
  20. Kokhan, O., Marzolf, D. R. Detection and quantification of transition metal leaching in metal affinity chromatography with hydroxynaphthol blue. Analytical Biochemistry. 582, 113347 (2019).
  21. Doyle, C., Naser, D., Bauman, H., Rumfeldt, J., Meiering, E. Spectrophotometric method for simultaneous measurement of zinc and copper in metalloproteins using 4-(2-pyridylazo)resorcinol. Analytical Biochemistry. 579, 44-56 (2019).
  22. Furrer, J., Smith, G. S., Therrien, B., Gasser, G. . Inorganic Chemical Biology. , (2014).
  23. Hogeling, S. M., Cox, M. T., Bradshaw, R. M., Smith, D. P., Duckett, C. J. Quantification of proteins in whole blood, plasma and DBS, with element-labelled antibody detection by ICP-MS. Analytical Biochemistry. 575, 10-16 (2019).
  24. Yamasaki, S., Tsumura, A., Takaku, Y. Ultratrace Elements in Terrestrial Water as Determined by High-Resolution ICP-MS. Microchemical Journal. 49 (2), 305-318 (1994).
  25. Brittain, H. G. Complex Formation Between Hydroxy Naphthol Blue and First Row Transition Metal Cyanide Complexes. Analytical Letters. 10 (13), 1105-1113 (1977).
  26. Brittain, H. G. Binding of Transition Metal Ions by the Calcium Indicator Hydroxy Naphthol Blue. Analytical Letters. 11 (4), 355-362 (1978).
  27. Temel, N. K., Sertakan, K., Gürkan, R. Preconcentration and Determination of Trace Nickel and Cobalt in Milk-Based Samples by Ultrasound-Assisted Cloud Point Extraction Coupled with Flame Atomic Absorption Spectrometry. Biological Trace Element Research. 186 (2), 597-607 (2018).
  28. Ferreira, S. L. C., Santos, B. F., de Andrade, J. B., Costa, A. C. S. Spectrophotometric and derivative spectrophotometric determination of nickel with hydroxynaphthol blue. Microchimica Acta. 122 (1), 109-115 (1996).
  29. Denisov, I. G., Grinkova, Y. V., Lazarides, A. A., Sligar, S. G. Directed Self-Assembly of Monodisperse Phospholipid Bilayer Nanodiscs with Controlled Size. Journal of the American Chemical Society. 126 (11), 3477-3487 (2004).
  30. Grinkova, Y. V., Denisov, I. G., Sligar, S. G. Engineering extended membrane scaffold proteins for self-assembly of soluble nanoscale lipid bilayers. Protein Engineering, Design and Selection. 23 (11), 843-848 (2010).
  31. Bonta, M., Hegedus, B., Limbeck, A. Application of dried-droplets deposited on pre-cut filter paper disks for quantitative LA-ICP-MS imaging of biologically relevant minor and trace elements in tissue samples. Analytica Chimica Acta. 908, 54-62 (2016).
  32. Olmedo, P., et al. Validation of a method to quantify chromium, cadmium, manganese, nickel and lead in human whole blood, urine, saliva and hair samples by electrothermal atomic absorption spectrometry. Analytica Chimica Acta. 659 (1), 60-67 (2010).
  33. Shyamal, M., et al. Highly Selective Turn-On Fluorogenic Chemosensor for Robust Quantification of Zn(II) Based on Aggregation Induced Emission Enhancement Feature. ACS Sensors. 1 (6), 739-747 (2016).
  34. Kudo, H., Yamada, K., Watanabe, D., Suzuki, K., Citterio, D. Paper-Based Analytical Device for Zinc Ion Quantification in Water Samples with Power-Free Analyte Concentration. Micromachines. 8 (4), 127 (2017).
  35. Liu, R., Zhang, P., Li, H., Zhang, C. Lab-on-cloth integrated with gravity/capillary flow chemiluminescence (GCF-CL): towards simple, inexpensive, portable, flow system for measuring trivalent chromium in water. Sensors and Actuators B: Chemical. 236 (C), 35-43 (2016).

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Swaim, C. M., Brittain, T. J., Marzolf, D. R., Kokhan, O. Quantification of Metal Leaching in Immobilized Metal Affinity Chromatography. J. Vis. Exp. (155), e60690, doi:10.3791/60690 (2020).

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