Bruker’s nanoElute UHPLC shows excellent performance and ease of use for proteomics

Keywords:  
LC-MS, nanoElute, 
nanoflow, peak area 
reproducibility, 
retention time 
stability, peak width, 
peak capacity

Bruker’s nanoElute UHPLC shows  
excellent performance and ease of use  
for proteomics

Authors: Thomas Kosinski 1, Matt Willets 2, Pierre-Olivier Schmit 3, Gary Kruppa 2
 1

 Bruker Daltonik GmbH, Bremen, Germany; 2 Bruker Daltonics Inc., Billerica, MA, USA; 3 BrukerDaltonique S.A., Wissembourg, France

Abstract

Bruker’s new nanoElute nanoflow 
UHPLC offers excellent chromato-
graphic performance in terms 
of separation and reproducibility 
with different gradient lengths, 
and with or without a trap column.

Introduction

Samples in shotgun proteom-
ics are often highly complex and 
can easily contain thousands of 
peptides in a narrow mass range 
which leads to analytical chal-
lenges. Therefore peptide sepa-
ration is commonly performed by 
nano-flow UHPLC, which brings 

several advantages, including high 
peak capacity and ESI compatible 
solvent composition and flow rate. 
Despite the increasing speed and 
sensitivity of mass spectrometers, 
enhancing their ability to analyze 
more ions eluting from the column 
at any given time, an improvement 
of chromatographic separation 
still provides a tremendous boost 

in the number of identified proteins. 
Furthermore, highly reproducible peak 
areas and retention times are crucial 
for more sophisticated quantitative 
analyses. To cover all these demands, 
a reliable HPLC system is essential.

In this study we evaluated the four 
essential chromatographic perfor-
mance indicators of the Bruker nano-
Elute: retention time variation, peak 
area variation, peak width and peak 
capacity, to test the nanoElute for the 
challenging requirements of sophisti-
cated proteomic analytics. 

Experimental

Samples
Aliquots of a commercially available 
tryptic digest of HeLa cells were 
diluted with 0.1 % formic acid in water 
to a concentration of 100 ng/µL.

For chromatographic separation a 
curved gradient with three different 
lengths was used, as shown in the 
table below. The gradient consists of 
solvent A, 0.1 % formic acid in water 
and solvent B, 0.1 % formic acid in 
acetonitrile with the temperature of 
the separation column maintained at 
50 °C and a flow rate of 400 nL/min.

Four technical replicates were made 
with the 90 min gradient and five tech-
nical replicates with the 120 min gra-
dient and the 240 min gradient, each 
measured using a setup without a 
trap column, and with a trap column. 
Switching between setups with and 
without a trap column is conveniently 
and easily done in the software. 

For MS detection an Impact II QTOF 
mass spectrometer equipped with 
a CaptiveSpray nanoBooster Source 

with pure ACN was used. The instru-
ment was operated in ESI positive 
mode acquiring full scan MS and MS/
MS data using the InstantExpertise™ 
routine. This is a self-adapting auto 
MS/MS method which is designed 
to obtain highest quality results inde-
pendently of the complexity and con-
centration of the sample. It uses an 
advanced parent ion selection proce-
dure combined with a variable MS/MS 
acquisition rate [1] and is pre-installed 
in the impact II instrument control 
software (otofControl).

Data Analysis
For analyzing the chromatographic 
data Bruker’s Compass DataAnalysis 
was used. Eight peptides, which were 
evenly distributed in time through the 
gradient, were selected from the HeLa 
chromatogram. EICs were made for 
these peptide masses and the peak 

Mass Spectrometry

Instrument:

Bruker impact II QTOF  

mass spectrometer

Dry Gas:

3.0 L/min

Ion source:

CaptiveSpray nanoBooster in  

positive ion mode

Dry Temperature:

150 °C

Capillary:

1600 V

nanoBooster:

0.20 Bar

Liquid chromatography

Instrument:

Bruker nanoElute™

Gradient  

Conditions:

90 min 

Gradient

120 min 

Gradient

240 min 

Gradient

Composition 

B

Column:

Acclaim PepMap™ RSLC;  

75 µm x 50 cm

0 min

0 min

0 min

2 % B

Mobile phase A: Water, 0.1 % formic acid

60 min

90 min

180 min

15 % B

Mobile phase B: ACN, 0.1 % formic acid

90 min

120 min

240 min

25 % B

Trap column 

loading:

100 % mobile phase A

100 min

130 min

250 min

35 % B

Flow rate:

400 nL/min

110 min

140 min

260 min

95 % B

Injection 

volume:

2 µL

120 min

150 min

270 min

95 % B

Column oven:

50 °C

area, retention time and peak widths 
were compared between the technical 
replicates.

Results and Discussion

The gradient length in shotgun pro-
teomics typically varies between 
90 min to 240 min. With the pressure 
limit of the new nanoElute of 1000 bar, 
combined with a column oven, 50 cm 
column lengths are possible. The 
nanoElute Method Editor allows any 

gradient to be generated with only a 
few mouse clicks and all typical wash 
and equilibration steps are added auto-
matically.

Performance
Highly reproducible chromatographic 
separation is essential in any quanti-
tative analysis. The LC must provide 
an eluent flow, the gradient mixture 
and the injection volume precisely 
to ensure the reproducibility of each 
chromatographic run. To evaluate the 

instrument performance, we have 
compared multiple technical replicates 
with a 90 min, 120 min and 240 min 
gradient and determined the most 
important performance criteria.

As is shown in Figure 2, no matter 
which setup was used, base peak chro-
matograms were consistent across all 
gradient lengths with a time shift only 
due to the higher dead volume when a 
trap column was used.

High retention time stability and peak 
area reproducibility were achieved 
with both column configurations 
(Figure 3). Retention time drifts of 
only a few seconds were obtained 
even with the long 240 min gradient. 
With all gradient lengths the retention 
time variation was less than 0.5 %. 
Also the peak area reproducibility was 
extremely good with variations of less 
than 10 % for most of the comparisons 
and ≤5 % for all experiments using a 
trap column (Table 1). 

As expected the 90 minute gradient 
produced the narrowest peaks for 
both column setups, 11 s full width 
half maximum (FWHM) (Figure 4). 
The FWHM values increased propor-
tionally with the gradients length and 
resulted in a peak capacity between 
500 and 700 (Figure 5). This ensures 
the best separation to enable the mass 
spectrometer to analyze as many pre-
cursors as possible.

Fig. 1: Bruker nanoElute Method Editor

Fig. 2: Representative Base Peak Chromatograms for all gradient lengths and column setups. Chromatograms in the upper row are obtained by using a trap column 
and in the lower row without a trap column.

0

2

4

6

0

2

4

6

8

20

40

60

80

100

0

Time [s]

Intens. x10

7

0

0.5

1.0

1.5

2.0

0

0.5

1.0

2.0
1.5

2.5

20

40

60

80

100

120

140

0

Time [s]

Intens. x10

7

0

0.5

1.0

1.5

0

0.5

1.0

1.5

25

50

75

100

125

150

175

200

225

250

0

Time [s]

90 min Gradient

120 min Gradient

240 min Gradient

Intens. x10

7

w/o trap

w/ trap

w/o trap

w/ trap

w/o trap

w/ trap

Fig. 3: Extracted Ion Chromatograms showing retention time reproducibility of selected peptides across 5 technical replicates using a 120 min gradient.

0

2

4

6

8

9

9

9 9

10

10

10 10

10

11

11 11

13 13

13

12

12

12

12

12

6800

6850

6900

6950

7000

Time [s]

7050

7100

7150

7200

7250

Intens. x10

6

90 min

120 min

240 min

0

5

10

15

20

25

30

Median Peak FWHM (seconds)

w/o trap

w/ trap

90 min

120 min

240 min

0

100

200

300

400

500

600

700

800

Observed Peak Capacity

w/o trap

w/ trap

Fig. 5: Peak Capacity of 12 peptides across each gradient

Fig. 4: Median Peak FWHM of 8 peptides across each gradient

Conclusion

The nanoElute is the perfect companion to the impact II to perform high performance proteomics experiments. It 
outperforms state of the art nano-UHPLC systems in terms of performance and reliability combination. At the same 
time the nanoElute offers easy to use method configuration and sophisticated diagnostic procedures with a push of 
a button.

It allows for:
•  High retention time stability
•  High Peak Area reproducibility
•  Narrow peaks
•  High peak capacity

•  Simple gradient configuration
•  Automatic diagnostic tool
•  Trap column switchable with 
 

a push of a button

Median Retention Time Variation

90 min

120 min

240 min

w/o trap

w/ trap

w/o trap

w/ trap

w/o trap

w/ trap

0.16%

0.05%

0.18%

0.35%

0.11%

0.26%

Median Area Variation

90 min

120 min

240 min

w/o trap

w/ trap

w/o trap

w/ trap

w/o trap

w/ trap

13%

4%

8%

5%

3%

4%

Median Peak FWHM (seconds)

90 min

120 min

240 min

w/o trap

w/ trap

w/o trap

w/ trap

w/o trap

w/ trap

11

11

15

16

26

28

Observed Peak Capacity

90 min

120 min

240 min

w/o trap

w/ trap

w/o trap

w/ trap

w/o trap

w/ trap

514

546

577

676

581

620

Table 1: Summery of chromatographic performance values

For research use only. Not for use in diagnostic procedures.

References
[1] Bruker App Note LC-MS 81
Introducing New Proteomics Acquisition Strategies with the compact™ –  
Towards the Universal Proteomics Acquisition Method

[email protected] - www.bruker.com

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