Improving throughput for assessing nephelometric turbidity units (NTUs) using the NEPHELOstar Plus

Carl Peters BMG LABTECH Inc., NC, USA 06/2017
  • The NEPHELOstar Plus is able to detect NTU’s to an LOD comparable with industry standard instrumentation
  • A significant savings in time, effort and sample can be achieved using this approach

Table of contents


Turbidity is a fairly general concept that is used to describe the dispersion of particulate matter within a liquid phase. Measurement of turbidity is classically important in water quality testing where turbidity is often expressed in NTUs (nephelometric turbidity units). Assessing turbidity is also beneficial in other applications including biological samples where quantifying turbidity is important for measuring bacteria cell growth or antibody precipitation.

NTU values can be derived from a calibrated nephelometer or turbidimeter such as the HACH® 2100N turbidimeter; however, collecting turbidity data with a turbidimeter is a time consuming, multistep process that employs large sample volumes. Here, we provide a higher throughput, simplified, low volume approach to the collection of NTU data using the NEPHELOstar Plus. We present data directly comparing the NEPHELOstar Plus, expressed in RNUs (relative nephelometry units), to the NTU results from a HACH® turbidimeter.

Assay Principle

The nephelometry method determines the cloudiness of a solution by passing a light beam through the sample. The light is scattered by the suspended particles and the forward scattered light measured to indicate the amount of suspended particles in the solution.

The NEPHELOstar Plus uses a laser diode at 635 nm with adjustable diameter and intensity as a light source. Light scattered by an angle of up to 80 degree is collected using an Ulbricht sphere (Figure 1). 

Materials & Methods

  • NEPHELOstar Plus microplate reader from BMG LABTECH
  • UV-star 96-well clear microplates from Greiner
  • HACH® 2100N Turbidimeter
  • StabCal® Calibration Set 0 to 4000 NTU
  • Sample cells for ratio turbidimeter
  • Silicone oil
  • Deionized (demineralized) water
  • Stabilized formazin turbidity standards (0.063 –1000 NTU)


The turbidimeter was calibrated per instrument instructions. Blank (water) or formazin standard NTU values were recorded after the value stabilized for approximately one minute following the instrument instructions. The sample volume for turbidimeter measurements was approximately 30 ml. For experiments using the NEPHELOstar Plus, 200 µl of water or turbidity standards were pipetted into microplates and read using the following settings.


Instrument settings


Measurement mode: Endpoint
Measurement interval: 1 second
Laser intensity: 80% (or as indicated)
Beam focus: 2.5 mm
Settling time: 1 second 

Data analysis
For each formazin standard, eight replicate readings using the turbidimeter were averaged with Excel. These data were used to generate a standard curve. Like-wise, averaged NTU data from eight replicates of the different formazin standards were used for calculating the standard curve with the MARS analysis software. LOD was calculated from at least 20 blanks using the formula:

Results & Discussion

We first sought to determine the limit of detection or LOD for the turbidimeter using water as a blank (n = 20) and 8 replicate readings from 8 different formazin standards (0.063 to 100 NTUs). The readings in the applied range resulted in a linear standard curve with a r² of 0.9999. The limit of detection was calculated to be 0.119 NTUs for the Turbidimeter (Figure 2).

We then determined the NTU LOD for the microplate reader NEPHELOstar Plus using water as a blank (n = 32) and 8 replicates of formazin standards (NTU values ranged from 0.057 to 97.912 based on the turbidimeter results from the HACH®). Outliers were detected using Grubbs’ test. Figure 3 shows that the data conforms to a linear fit. 

From these tests a comparison can be made based on performance, experimental reading time and sample volume (see Table 1). The NEPHELOstar Plus is competitive in terms of sensitivity and is superior in all other metrics.

Tab. 1: NEPHELOstar Plus vs. Turbidimeter.


  LOD (NTU) Read-time Sample volume
NEPHELOstar Plus 0.363 2 seconds per well 200 µl
Turbmidimeter 0.119 ~ 1 minute per sample ~ 30 mL


Our final tests were intended to explore the range of detection of the NEPHELOstar Plus at higher NTUs. Once again we first assessed the average NTU values on the turbidimeter for formazin standards and compared these results to replicate readings of the same standard on the nephelometric microplate reader (figure 4). 

As figure 3 shows, a linear relationship (r2 = 0.995) is maintained to at least the standard that measured ~194 NTUs. We also assessed whether decreasing laser intensity improved linear correlation and did not see a positive impact (data not shown).


The NEPHELOstar Plus can detect NTUs with an LOD of <0.4 NTU, while having a linear relationship between RNUs and NTUs to ~200 NTUs (r2 =0.995). These results can be obtained with a read time of less than 2 seconds per sample, compared to over 1 minute per sample on a turbidimeter. While using 0.2 ml on the NEPHELOstar Plus, the turbidimeter required 30 ml per sample. 

Lecteurs compatibles