Versatile Dual-Inlet Sample Introduction System for Multi-Mode Single Particle Inductively Coupled Plasma Mass Spectrometry Analysis and Validation

1. Assembly of the dual-inlet sample introduction setup NOTE: Details about different parts are shown in Table 1. Components Part 1 Glass female spherical ball joint with approximately 10 mm shank length Glass male ball joint with approximately 10 mm shank length Metal T-piece (dimensions: 1/4 in) Glass to metal adhesive Two clamps for spherical glass joints Part 2 ICP-MS spray chamber (suggested type: impact bead spray chamber, cyclonic spray chamber or similar) Pneumatic nebulizer (suggested type: concentric nebulizer) Clamp Part 3 O-ring free quartz torch Gas line connector closed-end Gas line connector open-end Conductive and flexible silicone tube Part 4 Piezoelectric Micro droplet generation unit Part 5 Micro droplet control unit Table 1: List of Components used to build up the dual-inlet setup. Construction of a T-piece connector unit (Figure 1 Part 1). NOTE: This part connects the conventional sample introduction system (step 1.2) and the µDG transport unit (step 1.3). Insert a male and female ball joints to the opposite openings of a T-piece connector. Secure the male and female ball joints by using a glass to metal adhesive (e.g., silicon glue). Connect the female ball joint to the injector of the ICP-MS using a clamp. Attachment of a conventional sample introduction system (Figure 1 Part 2) NOTE: This part is connected to the T-piece connector unit (step 1.1) Combine an ICP-MS spray chamber with a pneumatic nebulizer (PN), which fits into the spray chamber being used. Use a clamp to connect the spray chamber outlet to the male ball joint of the T-piece connector (described in step 1.1). NOTE: The spray chamber outlet is usually equipped with a female ball joint connector. The combination shown in Figure 1 consists of a nebulizer and an impact bead spray chamber. Instead of the impact bead spray chamber other spray chambers with transport efficiencies in range of 2 to 10% or higher can be used. Construction of the microdroplet transport unit (Figure 1 Part 3) NOTE: This part connects the T-piece connector unit (step 1.1) and the µDG unit (step 1.4). Attach a demountable quartz torch, with its injector tube removed, to a laboratory stand with the torch inlet on the top using appropriate clamps. Block the torch plasma/auxiliary gas inlet by closed end gas connectors. NOTE: The sample is transported using a peristaltic pump to the nebulizer. Argon gas is used for sample nebulization into the spray chamber and further transportation into the plasma. Connect a helium gas line to the torch via its cooling gas inlet by using an appropriate gas connector. NOTE: The applied helium gas is used for the desolvation of generated droplets and act as a sheath gas preventing the droplet from a collision with the walls of the setup and in preventing the ICP-MS instrument from atmospheric oxygen insertion while the sample inlet head of the µDG has to be removed for cleaning and sample exchange. Connect a 30 cm long conductive and flexible silicone tube (i.d. 0.75 cm), using an adapter, to the exit end of the torch (bottom of torch). Connect the downward end of the silicone tubing to the T-piece connector unit by stretching the flexible silicone tubing over its remaining vertical metal connection. NOTE: The flexible silicone tubing allows x-y-z tuning of the ICP-MS instrument with the connected setup. Connection of the microdroplet generation unit and microdroplet generation control unit (Figure 1 Part 4, Part 5) NOTE: This part is connected to the µDG transport unit (step 1.3) Connect the prepared µDG unit to the microdroplet transport unit by inserting the µDG head into the sample inlet end of the torch. Connect the power supply to the µDG control unit. NOTE: The setup described here consists of a commercially available µDG head and µDG power supply. Depending on µDG head used the setup must be adapted accordingly. 2. Quantification of droplet size Use a stroboscope light and a CCD camera (e.g., in an open configuration, see Figure 1 size measurement configuration) for taking images of produced droplets by the µDG. Calibrate the CCD camera by taking images of an object of known size in µm range (e.g., copper wire with a diameter of 150 µm). Take images of at least 1, 000 drops at the settings used for the experiment (see Table 2). Use an appropriate graphical software program (see Table of Materials) to evaluate the images concerning the object and drop size in the following steps: Click File and Open to load the image of the object. Click Image | Adjust | Threshold to define the area of the object by moving the scroll bars. Click Apply to apply the settings. Click on the Straight segment button. Click and hold the left mouse button to draw a line alongside the object. Press Ctrl + M to measure the object size. Measure the diameter of the object at 5 different points. Copy and Paste the “Results” table in a spreadsheet software. Calculate the arithmetic mean of the column “Length”. Calculate the pixel aspect ratio (PAR): actual object size (µm)/mean object size in the image (px). Click File | Import | Image Sequence to import and load the images of the droplets. Click Rectangular and mark the droplet of the first image. Perform the right click on the mouse pad and choose Duplicate to separate the droplets of the image sequence from the rest of the image. Separate the droplets from the background as specified in step 2.4.2. Click Process | Binary | Erode to remove reflections of light on the droplet surface. Click Process | Binary | Dilate to reverse the “Erode” step. Click Analyze | Analyze Particles | Ok to measure all droplets. Copy and Paste the “Summary” or “Result” table into a spreadsheet software. Calculate the arithmetic mean of the ferret diameter in px. Use the PAR to transform the diameter in µm: ferret diameter in px/PAR. NOTE: The size of the droplets formed by the µDG varies depending on the selected length and duration of the current pulse applied to the piezo element7. 3. Sample preparation Prepare an ionic calibration solution of the analyte to be measured in the concentration range of 0.2 to 20 µg/L in dilute acid (e.g., HCl (0.5 v/v), HNO3 (3.5 v/v)). Prepare an ionic solution for the one-point calibration in the concentration range between 1 and 10 µg/L in dilute acid. Prepare the NP standard suspensions according to the manufacturer's instructions or in-house protocols. NOTE: Steps 3.3.1 – 3.3.4 explain the preparation of the NP standard suspensions considering Ag, Au, CeO2 NPs as example. Prepare 10 mL of 0.05 µg/L AuNP solution for the PN and 1 µg/L AuNP solution in ultrapure water for µDG. Vortex for 20–60s before using. Prepare 0.05 µg/L AgNP solution for the PN and 2 µg/L AgNP solution, both in ultrapure water, for µDG. Shake well for 20–60s before using15. Prepare CeO2 NP solutions to be used as described previously for metal oxides16,17. Prepare 0.05 µg/L CeO2 NP solution for the PN and 1 µg/L solution for the µDG. Weigh 25.6 mg/mL CeO2 NP in a glass vessel of 15 mL – 20 mL total and add 10 mL of 0.05 (v/v) BSA solution prepared in ultrapure water. Use a fingertip sonicator with a power of 7.35 W to homogenize the particle solution for 309 s. 4. Instrumental tuning and parameters Make sure the MDG generator is turned off and connect the dual-inlet sample introduction setup which was built in step 1 with the injector of the ICP-MS instrument with a clamp. Flush the inlet system for 5 – 10 min with the nebulizer gas (Ar) and the droplet transportation gas (He). NOTE: The ICP-MS instrument has to be protected against the penetration of high levels of oxygen into the plasma room. Turn off the droplet transportation gas (He) and start the ICP-MS system Tune the instrument in the measurement mode which one wants to utilize using the instrument standard tuning solution that is specified by the manufacturer of the ICP-MS system. NOTE: A standard tuning solution consist of, for example barium, cerium, indium, uranium, bismuth, cobalt, lithium (all 1 µg/L) in a mixture of 2.5% (v/v) nitric acid and 0.5% (v/v) hydrochloric acid. Determination of the sample uptake rate of the PN. Fill a vessel with 15 mL of water. Weigh the vessel. Connect the vessel to the tubing of the PN. Start the peristaltic pump by click on the peristaltic pump start button in the instrument software. Start a 5 min timer. Remove the uptake line from the vessel exactly after 5 min. Weigh the vessel again. Calculate the sample uptake rate (mL/min) using the formula: vessel weight before – vessel weight after / time duration. Optimize instrumental parameters to improve analyte sensitivity if necessary, e.g., nebulizer gas flow rate, sampling depth, plasma power. NOTE: See Table 2 as an example of instrumental parameters that can be optimized in an ICP-MS system. Adjust the He gas flow until a constant signal rate can be detected as a function of the drop formation rate. Parameter Value ICP – MS: Plasma Power (W) 1600 Sampling Depth (mm) 4 Flow rates (L min-1): Auxiliary Gas 0.65 Cooling Gas 14 Times (s) Data acqusition (s) 1200 Dwell time (s) 0.01 Interface: PN Sample uptake rate (mL min-1) 0.21 Nebulizer Gas (L min-1) 0.92 µDG: Capillary diameter (µm) 75 Drop rate (Hz) 10 He makeup gas (L min-1) 0.27 Operation mode Triple pulse   Set1 Set2 Set3 Voltage (V) 53 51 47 Pulse width (µs) 20 25 12 Pulse delay (µs) 4 2 1 Table 2: Values of instrumental parameters used. 5. Multi-mode measurement of nanoparticle samples Prepare the µDG control unit Turn on the power supply switch of the µDG control unit. Click Start on the first screen to start up the control unit. Click Global Settings to choose the pulse mode to be used. Click on the right graphical button at pulse mode to choose the triple pulse mode. NOTE: The settings for the triple pulse mode are given in Table 2. Prepare the µDG unit Click On/Off to start the µDG. Fill the sample vessel with the sample solution to be measured. Connect the sample vessel to the µDG unit. Using a 10 mL syringe to purge air through the vessel and the µDG unit. Connect the syringe to the syringe port on the sample container vessel. Push the syringe plunger until a constant liquid stream is observed coming out the µDG head. Maintain the pressure for 10 s. Remove the syringe. Place the µDG unit into the focus zone of the CCD camera to observe the formed droplets. Connect the CCD camera to a PC or laptop. Start the CCD camera software to observe the formed droplets Click Start to get a live view of the droplets. Observe constant droplet formation. Place the µDG head onto the inverted torch on the dual-inlet sample introduction system. Validate both, the µDG unit and the PN for each element of interest by measuring repeated multi point-calibrations. NOTE: For ICP-MS data acquisition, use the software associated with the instrument. Determine the linear range of the multi-point calibration by importing the experimental data into a spreadsheet software. Calculate the arithmetic mean of each calibration point. Determine the intercept, slope and correlation coefficient. NOTE: For sp-ICP-MS the correlation coefficient should be >0.9918. Choose a concentration within the linear range of the calibration curves for one-point calibrations later on. Following the steps below for measurement and validation (by using reference materials like NIST 8012, NIST 8013 or NIST 8017 or similar) of the multi-mode nanomaterial quantification (Figure 2). Select a nanoparticle and an ionic standard according to the analyte of interest. Prepare the µDG unit according to 5.2 with an ionic standard solution. Add a diluted acid solution (e.g., 0.5% v/v HCl) via the PN. Start the measurement of the ICP-MS system in time resolved mode. Click On/Off after 120 s to stop the µDG and exchange the dilute acid solution at the PN with the ionic standard. After 330 s once again exchange the ionic standard at the PN with a dilute acid solution. Meanwhile remove the µDG unit from the setup. Exchange the sample vessel (glass vial) of the µDG unit with a vessel containing a diluted acid solution (e.g., 3.5% HNO3) in order to clean the µDG unit. Fill a 10 mL syringe with air. Connect the syringe to the injection port of the µDG unit and empty the syringe until a jet of liquid appears from the µDG head and maintain pressure for 30 s. Prepare the µDG as specified in step 5.2 with the NP sample and attach the µDG unit back to the setup at 510 s. Click On/Off after 810 s to stop the µDG. Exchange the dilute acid solution at the PN with the NP sample and measure for another 300 s. Stop the measurement after approx. 1,200 s. Clean the µDG unit as specified in step 5.5.8. Figure 2: Measurement strategy for multi-mode nanomaterial quantification. Please click here to view a larger version of this figure. 6. Data analysis NOTE: To simplify all calculation steps, a corresponding spreadsheet was prepared (see Supplementary File). Use a spreadsheet or software which can handle data frames to process the data and import the measured data. Paste the intensity values of the entire measurement in the spreadsheet software (included in the electronic supplement) in column A, the data will be visualized. Enter all necessary experimental parameters for calculation into the table “Input Parameter”. Define the regions of interest (ROI) for µDG ionic (I), PN ionic (II), µDG NP (III) and PN NP (IV) by selecting the appropriate spreadsheet cells. Using the graph in the prepared sheet to define the boundaries of the ROIs and enter the values into the “Determination of the Region of Interest” table (cells C1:E7). Copy and paste the each data set in a separate column. Press the button Copy ROI in the prepared sheet to split the measurement into the four ROIs (column M:P). Calculate the arithmetic mean of I and II. Apply the iterative approach to separate particle or droplet signals and background for III and IV. Calculate the arithmetic mean and standard deviation of all measured values. Calculate a limit or cut-off value by mean value + 5*standard deviation. Remove all signals smaller than the limit value of III and IV by using the Cut command on the identified particle signals. Use Paste to paste them in a separate column. Repeat steps 1-3 until the mean value and standard deviation are constant. NOTE: In columns Q to BD of the prepared sheet, the iterative approach to separate background and particle signals is performed five times. Calculate the arithmetic mean of the identified particle signals of III and IV. Calculate the minimum detectable particle size (LODsize – nm) for µDG NP and PN NP by using the instrumental limit of detection of the analyte (LOD – counts), the analyte sensitivity (SC,ionic – counts/(µg/L)), the sample uptake rate (qs – mL/min), the transport efficiency (η – relative unit) and the bulk material density (ρ – g/cm³): Calculate the mass (ma,p) and particle size (d – nm, assuming the particles are spherical) of identified particle signals for µDG NP and PN NP according to the three analysis modes applied by taking the ionic metal concentration of a standard solution (ca – µg/L) and the ion flux in the plasma (counts/s) into account: Mass: Size: Calculate the specific transport efficiency of the analysis modes by using the number of particles detected (qp), the particle concentration of the sample (cp,used – 1/mL), the analyte sensitivity of the PN and MDG (Sm,ionic,PN, Sm,ionic,MDG – counts/(µg/L)), the volume of the droplet (Vdrop – pL), the dwell time (td – ms), the transport efficiency of the PN (ηPN), the transport efficiency of the µDG (ηµDG), the intensity of the ionic solutions measured by the PN and µDG ( Iionc, PN, Iionic,µDG – counts) and the concentration of the ionic solution used for both injection systems (cionic,PN, cionic,µDG – µg/L): Mode I: Mode II: Assume that the transport efficiency of µDG is equal to 1:19 Calculate the particle number concentration of the NP solution analyzied by taking into account the injected sample volume during the measurement (Vinjected): NOTE: In the prepared sheet all calculations are performed automatically after the splitting. The results are shown in table “Output Parameters” (cells BH7:BR35) and contains the formulas described above including individual calculation steps.