ARTICLE

Journal of Circulating Biomarkers

The Role of Isolation Methods on a
Nanoscale Surface Structure and Its
Effect on the Size of Exosomes
Original Research Article

JungReem Woo1#, Shivani Sharma2*# and James Gimzewski1,2#

1 Department of Chemistry and Biochemistry, University of California, Los Angeles, USA
2 California NanoSystems Institute, University of California, Los Angeles, California, USA
#These authors contributed equally to this work
*Corresponding author(s) E-mail: sharmas@cnsi.ucla.edu

Received 09 March 2016; Accepted 09 May 2016

DOI: 10.5772/64148

© 2016 Author(s). Licensee InTech. This is an open access article distributed under the terms of the Creative Commons Attribution License
(http://creativecommons.org/licenses/by/3.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the
original work is properly cited.

Abstract

Exosomes are ~100 nanometre diameter vesicles secreted
by mammalian cells. These emerging disease biomarkers
carry nucleic acids, proteins and lipids specific to the
parental cells that secrete them. Exosomes are typically
isolated in bulk by ultracentrifugation, filtration or immu‐
noaffinity precipitation for downstream proteomic,
genomic, or lipidomic analysis. However, the structural
properties and heterogeneity of isolated exosomes at the
single vesicle level are not well characterized due to their
small size. In this paper, by using high-resolution atomic
force microscope imaging, we show the nanoscale mor‐
phology and structural heterogeneity in exosomes derived
from U87 cells. Quantitative assessment of single exosomes
reveals nanoscale variations in morphology, surface
roughness and counts isolated by ultracentrifugation (UC)
and immunoaffinity (IA) purification. Both methods
produce intact globular, 30-120 nm sized vesicles when
imaged under fluid and in air. However, IA exosomes had
higher surface roughness and bimodal size population
compared to UC exosomes. The study highlights the
differences in size and surface topography of exosomes
purified from a single cell type using different isolation
methods.

Keywords AFM, Exosome, Nanoparticles, Immunoaffini‐
ty, Surface Roughness, Vesicles, Isolation Method

Abbreviations

AFM: atomic force microscopy;

TEM: transmission electron microscopy

UC: ultracentrifugation

IA: immunoaffinity

1. Introduction

Cells utilize vesicles for the intercellular signalling, trans‐
porting and trafficking of metabolites [1-2]. A more
collective term, “extracellular vesicle” (EV), is often used as
a synonym for “membrane vesicles”, which includes
microvesicles, exosomes, apoptic bodies and other vesicles.
In this paper, we use the term “exosomes” due to the

1J Circ Biomark, 2016, 5:11 | doi: 10.5772/64148



characteristic size, morphology and specific surface
markers present.

Exosomes, which are 30-120 nm-sized vesicles, are of
particular interest for potential disease diagnostic markers.
Due to their small size, it was once believed that exosomes
were random cell debris, but it is now known that they are
actively secreted from cells with specific markers [3-6].
Exosomes carry nucleic acids [7], proteins [8] and lipids [9],
and can deliver these diverse components to distant
recipient cells and thus hold potential as emerging bio‐
markers for diseases including cancers [10-12]. Neverthe‐
less, the isolation and characterization of purified
exosomes from bodily fluids, tissues, or cells of origin are
crucial aspects for any downstream biomarker discovery
research.

Many isolation procedures and commercially available kits
are currently being actively researched in a bid to optimize
the enrichment and isolation of purified exosomes in bulk
[13]. For the isolation of exosomes, conventional methods
utilize sequential centrifugation and ultracentrifugation
(UC) to spin down exosomes in cell culture media or bodily
fluids [14]. Sucrose density gradient ultracentrifugation is
required for additional purification and to minimize
protein contamination [15]. Size exclusion chromatography
is also employed to purify exosomes based on their
physical dimensions [16]. In addition, antibodies targeting
exosome surface markers such as CD9, CD63, CD81 and
EpCAM are attached to magnetic beads (immunoaffinity;
IA) to capture and purify exosomes [15,17]. After isolation,
the purified exosome samples are characterized using
various imaging and biochemical techniques. It is difficult
to characterize the 3D structure of single exosomes due to
their nanometric dimensions. The particle size distribution
of extracellular vesicles has been analysed with transmis‐
sion electron microscopy (TEM), flow cytometry, resistive
pulse sensing and nanoparticle tracking analysis [18]. TEM
provides standard size distribution information, but
suffers from fixation artefacts and non-biocompatible
conditions such as low temperature and high vacuum.
Flow cytometry is not optimal for exosomes, due to its poor
resolution when particle diameters are less than 100 nm.
Resistive pulse sensing and nanoparticle tracking analysis
resolves particles with diameters ranging from 10-1000 nm,
but is limited in terms of resolving heterogeneous vesicle
populations. The first structural characterization of
exosomes was effected using TEM with immunogold
nanoparticle labelling [19]. Based on EM images, exosomes
were thought to have 'cup-shaped structures'. However,
atomic force microscope (AFM) and field emission scan‐
ning electron microscope images subsequently revealed
that exosomes are globular vesicles, similar to other vesicles
present in cells [20].

One of the limitations of these bulk isolation methods is that
they preclude identification of heterogeneity among
exosome sub-populations. It is known that exosomes
secreted by the same originating tissues, cell types and
single cells, may vary in terms of composition, size and

density [21], which can have significant implications for
studies in exosome biology and their role as disease
biomarkers in various pathologies [22]. The commonly
used NanoSight tracking analysis (NTA) is a comparable
non-microscopic method for measuring exosome sizes and
distributions. Many researchers have utilized and com‐
pared both microscopic and non-microscopic methods for
obtaining exosome sizes [23]. However, NTA does not
provide quantitative surface information at sub-nm
resolutions. Recently, we reported high-resolution images
of glioblastoma exosomes using PeakForce AFM imaging
and showed that their nanofilament structure may influ‐
ence the delivery of exosomes into recipient cells [24]. Here,
using high-resolution AFM imaging, we investigate the
nanoscale morphology and structural heterogeneity in
exosomes isolated from glioblastoma U87 cell lines, and the
influence of particular isolation methods. Quantitative
assessment of exosomes at the single vesicle level reveal
nanoscale variations in morphology, surface roughness
and counts of exosomes isolated using two methods, i.e.,
ultracentrifugation (UC) and immunoaffinity (IA) bead
purification with widely used exosomal markers (CD9,
CD63, CD81 and EpCAM). Our AFM imaging data on
single vesicles reveals differences in the size and surface
topography of exosomes purified from the same cell type
but using different isolation methods. We attribute the
observed variations in size and surface roughness of
isolated exosomes to the selection and/or reassembly of
receptors on the surface of isolated exosomes.

2. Results

2.1 Single exosome images show differences in structure
depending on purification method

We investigated the structural differences among isolated
exosomes at the single vesicle level between those purified
using two different methods, i.e., UC and IA (Fig. 1). The
antibodies on the magnetic beads were against four
different antigens: CD9, CD63, CD81 and EpCAM. Each
antibody is immobilized on separate bead solutions; then,
the individual antibody-beads are mixed together. Since
the antibodies select exosomes according to their surface
proteins, it is possible that exosomes with specific surface
markers may result in the size selection of the entire
exosome population. On the other hand, ultracentrifuge
utilizes the density difference in the sample to purify
exosomes. Ultracentrifugation [14] is the most commonly
used method for concentrating exosomes that include
differential centrifugation steps up to 100 000 × g. Though
the method is time consuming (4-5 hours), requires an
ultracentrifuge and is inefficient with regard to exosome
yield (5-25% recovery), it nevertheless enables label-free
isolation of exosomes.

2.1.1 The structural characterization of native exosomes in fluid:
Peak force imaging

Peak force mode is a recently developed AFM imaging
mode enabling very low imaging forces (less than 1 nN) for

2 J Circ Biomark, 2016, 5:11 | doi: 10.5772/64148



the detection of exosomes in fluid. Figure 2 (a) shows IA
exosomes imaged using AFM in fluid. IA exosomes show
globular structures of varying sizes with an average
diameter of 39 ± 22 nm in width and an average height of
4.3 ± 3.7 nm. Figure 2 (b) shows a close-up image of the
smaller IA exosomes and cross-sections of the exosomes in
Figure 2 (c). The smaller IA exosomes have a diameter of
~30 nm and a height of ~2.5 nm. On the other hand, the
bigger IA exosomes are shown in Figure 2 (d) and their
cross-sections are displayed in Figure 2 (e). The bigger IA
exosomes have a diameter of ~80 nm and a height of ~10-12
nm. Both cross-sections from smaller and bigger exosomes
confirm their globular shapes, as expected under native
conditions. When compared to air AFM imaging, the size
distributions remain similar.

UC exosomes also show a globular shape in AFM images
in fluid (Figure 3 (a)). UC exosomes showed a single

Figure 1. (a) The scheme of exosome isolation by immunoaffinity magnetic
beads kit method. For capturing exosomes, antibodies against four different
surface markers (CD9, CD63, CD81 and EpCAM) were immobilized on the
surface of 3 µm magnetic beads. Each antibody was modified separately on
the beads and the mixture of the antibody-beads used to capture antibodies
from cell culture media (not drawn in scale). After capture and elution,
isolated exosomes were diluted and dialyzed against PBS prior to
characterization/storage; (b) flowchart of exosome isolation by ultracentri‐
fugation method. The exosome-containing media was centrifuged
sequentially to remove particles denser than exosomes, then centrifuged to
pellet down exosomes (exosome buoyant density of 1.10-1.24 g/mL). The
flowchart indicates each centrifugation step and the location of exosomes.
Exosomes were pelleted following ultracentrifugation at 100 000 g and the
pellet was washed with PBS, then ultra centrifuged again. The final exosome
pellet was re-suspended in either deionized water or PBS and characterized/
stored.

population with an average diameter of 49 ± 9 nm and an
average height of 7.8 ± 2.8 nm. A smaller scan area of the
UC exosomes are shown in Figure 3 (b) and their cross-
sections are shown in Figure 3 (c). The UC exosomes have
a diameter of ~60 nm and a height of ~10 nm.

2.1.2 The structural characterization of native exosomes in air:
Tapping mode imaging

Exosomes were isolated using the IA method and their
nanoscale structure was obtained using tapping mode
AFM imaging in air. Figure 4 (a)-(c) shows the detailed
structure of single exosomes isolated by the IA method.
Single exosomes show a globular structure with a diameter
of 76 nm and a height of 9.3 nm. The dimensions of the
exosomes are similar to the values previously reported [21].
The detailed structure of a single exosome is shown in
Figure 4 (d)-(e). Surface roughness of the exosomes within

Figure 2. Detection of IA exosomes by peak force AFM imaging in fluid; (a)
representative topographic image of exosomes showing varying vesicle size;
(b) close-up of smaller IA exosomes. The smaller IA exosomes were 22.5 ±
3.5 nm in diameter and 1.8 ± 0.3 nm in height; (c) cross-section of (b) shows
IA exosome dimensions to be approximately 30 nm in diameter and with a
height of 2.3 nm; (d) close-up of larger IA exosomes. The dimensions of
bigger IA exosomes are a diameter of 64.6 ± 9.2 nm and a height of 8.1 ± 3.1
nm; (e) the cross-section of (d) show IA exosome dimensions of approxi‐
mately 80 nm in diameter and a height of 12 nm.

3JungReem Woo, Shivani Sharma and James Gimzewski:
The Role of Isolation Methods on a Nanoscale Surface Structure and Its Effect on the Size of Exosomes



a 40 nm x 40 nm area, shown as a box in Figure 4 (d), were
measured as Ra (arithmetic average of the absolute values,
1.48 nm) and Rq (root mean squared, 1.17 nm). The
roughness of the exosome surface is clearly evident in the

Figure 3. Detection of UC exosomes by peak force AFM imaging in fluid; (a)
representative topographic image of UC exosomes. UC exosomes showed a
single Gaussian population in fluid imaging; (b) close-up of UC exosomes
showing a diameter of 49 ± 9 nm and a height of 7.8 ± 2.8 nm; (c) the cross-
section of (b) shows UC exosome dimensions of approximately 60 nm in
diameter and with a height of 10 nm.

phase channel in Figure 4 (f). The phase image is deter‐
mined by the lag between incident resonant oscillations
and the output signal oscillations, which are sensitive to
surface properties such as elasticity, adhesion and friction.

Figure 5. High-resolution images of UC exosomes obtained by AFM
imaging in air; (a) representative topography, (b) amplitude and (c) phase
images of exosomes. Inset (a) is the cross-section of the exosome for the
height channel. The dimensions of the exosome in (a) are a diameter of 79
nm and a height of 6.2 nm. The phase channel shows the smooth surface of
the exosome.

2.2 Exosomes show different size distributions depending on
purification methods

We measured the dimensions of IA and UC (Fig. 5)
exosomes to determine if their size distributions depended
on the purification method. The diameter and height were
measured for more than 100 exosomes. The average
diameter was 68.1 ± 26.5 nm and 45.9 ± 10.3 nm for IA and
UC, respectively. The average height was 9.6 ± 7.7 nm and
5.5 ± 2.4 nm for IA and UC, respectively. In the average
values, the dimensions of the exosomes seemed to be
similar, while IA exosomes were ~30% bigger than UC
exosomes. Figure 6 shows a histogram of (a) the diameter
and (b) the height of IA and UC exosomes, which are
markedly different. While the UC exosomes show normal
distribution (solid lines) in diameters and heights, the IA

Figure 4. High-resolution images of IA exosomes obtained by AFM imaging in air; (a) representative topography, (b) amplitude and (c) phase images of
exosomes shown while the boxed exosome is magnified in (d) topography, (e) amplitude and (f) phase images. The diameter and height of the exosome in
(d) is 76 nm and 9.3 nm, respectively. The phase channel shows the rough surface of the exosome.

4 J Circ Biomark, 2016, 5:11 | doi: 10.5772/64148



exosomes display bimodal distribution (dashed line). The
IA exosomes show wider bimodal distributions. The first
peak was observed at 23.9 ± 3.2 nm in width and 3.2 ± 0.5
nm in height, and the second peak at 54 ± 18 nm in width.
In the case of UC exosomes, it shows relatively narrow
singular distributions with a peak at 45.2 ± 0.1 nm in width
and 3.2 ± 0.5 nm in height. The difference in size distribution
may stem from the isolation mechanism employed. For the
UC method, exosomes were isolated based on buoyant
density and likelihood of resulting in a single Gaussian
population. However, the IA method selects exosomes
based on surface antigens. As an IA kit contains four
different antibodies, during purification, exosomes are
affinity-purified based on surface markers, which may
result in wider bimodal size distributions.

Figure 6. The size distributions of exosomes depending on isolation
methods. The width distributions (a) and the height distributions (b) are
shown with Gaussian fits. The width distribution of exosomes isolated by
IA show a bimodal population, with the first peak at 23.9 ± 3.2 nm and the
second peak at 54 ± 18 nm. The width distribution of exosomes isolated by
UC show a single Gaussian population with the peak at 45.2 ± 0.1 nm. The
height distribution of exosomes show a single Gaussian population for both
methods, with the peak at 3.2 ± 0.5 nm for IA and 5.0 ± 0.3 nm for UC. The
width and the height of exosomes from IA and UC were significantly
different at p<0.05.

3. Discussion

Exosomes have the potential to be utilized as disease
biomarkers that carry signature biomolecules (nucleic
acids, proteins and lipids) from the secreting cells of origin
[7, 9, 25-29]. However, due to their sub-100 nm size and low
abundance (~106-9 vesicles per ml) in extracellular environ‐
ments, it is challenging to isolate and characterize single
exosomes. During a special workshop presented by the
International Society for Extracellular Vesicles (ISEV),
researchers and experts discussed the standardization of
exosome isolation, handling and characterization. Al‐
though a consensus was not reached [13], Lötvall et al. later
proposed basic experimental requirements for defining
exosomes [30]. The proteomic and genomic contents of
exosomes, depending on the isolation method, have since
been compared and evaluated [15,26,31-33]. In addition,
evaluation of the structural integrity and morphology of
isolated exosomes is important for standardization and
downstream biomolecular analysis. In this paper we focus
on single exosome characterization using ultracentrifuga‐
tion and immunoaffinity capture to elucidate their nano‐
scale structure on an individual basis. This was achieved

using high-resolution AFM imaging of U87 cell-derived
exosomes. We discovered that quantitative assessment of
exosomes at the single vesicle level reveals nanoscale
variations in the morphology, surface roughness and
counts of exosomes isolated, which differ depending on the
extraction method used – ultracentrifugation (UC) or
immunoaffinity (IA) bead purification using exosomal
markers (CD9, CD63, CD81 and EpCAM). Our study is the
first to reveal the high-resolution structural variations
(morphology and size) and surface inhomogeneity (topo‐
graphic roughness) of exosome populations at the single
vesicle level.

Our results indicate distinct differences between UC and
IA exosomes purified at the single exosome level. Although
both methods yield globular vesicles, we found that UC
exosomes have smooth surface, whereas IA exosomes
exhibit a distinct roughness. Secondly, the size distribu‐
tions were different. UC exosomes showed a single
Gaussian distribution, whereas IA exosomes showed a
broader bimodal distribution. Furthermore, peaks in IA
exosome size histograms clearly indicate that IA exosomes
are either smaller or larger than UC exosomes. This was
observed under both AFM imaging techniques and
environments, i.e., tapping mode in air and peak force
mode in fluid. We attribute the measured variations to the
specific isolation protocol. Table S 1 summarizes the
differences in two exosome isolation methods, showing a
side-by-side comparison and the pros and cons of each
method, including the experimental details such as time,
yield, sample starting/final volumes and equipment used.
On the one hand, UC relies on the size and density
(1.12-1.19 g/ml) of the vesicles to precipitate, at high
centrifugal forces, intact unlabelled exosomes from the
solution (Figure 3 and 5). On the other hand, IA-isolated
exosomes result from a combination of the selective sorting
of vesicles enriched in either of the four targeted exosomal
markers, varying in binding affinities, as well as the process
of exosome elution from magnetic beads. Affinity purifica‐
tion involves specific non-covalent binding interactions
between immobilized target exosomal marker antibodies
(CD9, CD63, CD81 and EpCAM) on beads with ligands on
the exosome surface. Addition of the cell culture superna‐
tant (a complex mixture containing exosomes) allows
exosomes to bind according to their specific affinity to the
immobilized antibody molecules. However, to elute
exosomes from the beads, it is necessary to break the
antigen-antibody binding. The binding force differs for
each specific antibody-antigen, ranging from 50-500 pN
[34-35] compared to the covalent binding force ranges of
1-2 nN [36-38]. Although appropriate buffer conditions for
binding in affinity purification vary, antibody-antigen
binding is generally most efficient in aqueous buffers at a
physiological pH and ionic strength, such as phosphate-
buffered saline (PBS), which was employed in our protocol.
After washing away the non-bound components of the
complex mixture, the captured exosomes are released and
recovered (i.e., eluted) from the “bead-immobilized
antibody” using buffer conditions that disrupt the affinity

5JungReem Woo, Shivani Sharma and James Gimzewski:
The Role of Isolation Methods on a Nanoscale Surface Structure and Its Effect on the Size of Exosomes



interaction. Methods such as raising or lowering the pH,
adding a mildly active detergent, or altering the ionization
state are commonly used. The proprietary exosome elution
buffer (Exocap, JSR Life Science) enabled the recovery of
intact exosomes, as confirmed by AFM images (Figure 2
and 4).

There are some possibilities that can explain the observed
differences in exosome distribution and surface structure
at the single vesicle level. First, the surfactant on the
magnetic bead may transfer to the exosome surface. While
this might explain the increase in roughness and size of the
exosome, it cannot explain their shrinkage (width and
height) as observed in the bimodal distribution (see Figure
6). Another possibility is that the IA exosomes are altered
during the elution step (Figure 7). When exosome-bead
complexes are incubated with an elution buffer, not only is
antigen-antibody interaction affected, but also the exosome
itself, as well as antibody-bead linkers. To minimize such
unwarranted effects, the elution buffer was diluted and
immediately dialyzed against PBS. However, the antibody-
bead linker may nonetheless be disrupted and few anti‐
bodies will remain on the exosome resulting in the
increased apparent size of the extracted exosome (Figure
7(a)). Additionally, it is possible for tetraspanins to be
extracted from the exosome surface, resulting in the
reassembly of exosomes by the active detergents in the
elution buffer, which will lead to the underestimation of
exosome dimensions (Figure 7 (c)). Furthermore, UC-
isolated exosomes showed a smoother surface (Ra; 1.16 nm
and Rq; 0.95 nm, see also Figure 5 (c)) and narrower size
distributions. In contrast, in the case of IA exosomes, we
observed a wider bimodal distribution of dimensions both
in diameter and height (Figure 6), and accompanied by a
higher surface roughness compared to UC exosomes (Ra;
1.48 nm and Rq; 1.17 nm, see also Figure 4 (c), (f)). All of
these observed differences are consistent with our inter‐
pretation that using the IA method results in subtle changes
in the exosome surface layer.

Figure 7. Three possible IA exosomes eluted from beads; (a) antigen-
antibody interaction may remain intact, while the antibody-bead linkers are
disrupted during elution. Thus, antibodies are attached on the eluted IA
exosomes, resulting in expanded sizes; (b) ideally, only the antigen-antibody
interaction is affected and eluted IA exosomes will be the same as UC
exosomes; (c) tetraspanins (CD9, CD63 and CD 81) are pulled out during the
elution, causing IA exosomes' lost volume and partial contents.

In summary, our AFM images of IA- and UC-isolated
exosomes confirm in both cases high stability, non-
aggregation and vesicle integrity, suggesting the retention
of bio-functionality and suitability for downstream
analysis, which is required for thorough investigation in
future functional, microRNA and/or protein assays.
Exosomes are heterogeneous vesicles with various surface

markers [39]. Since exosomes show sub-populations with
different markers and sizes, it is desirable to perform more
analysis on single vesicle levels than ensemble qualifica‐
tions. In the past few years, nanotechnology-based isola‐
tion techniques [40] have been developed for isolating
exosomes. Such advances make it further evident that
detailed characterizations of exosomes are essential in
order to advance a biological understanding and the
biotechnological exploitation of exosomes, at the single
vesicle and sub-vesicular level [41-42]. Although the
limitations of current technologies do not support the
sorting of exosomes according to sizes, it nonetheless
provides insight about the analysis of exosome ensemble
data when sub-populations are acknowledged.

Both the UC and IA methods produce intact globular
exosomes at the single vesicle level. The advantage of the
IA method is speed and ease of use. In the current study, a
mixture of four capture antibodies (anti-CD9, CD63, CD81
and EpCAM) was used for IA purification; hence, we
cannot exclude the co-purification of various exosome
subpopulations. On the other hand, purification by UC is
based on the size and density of exosomes and as such, can
be expected to yield a more homogeneous size distribution.
In future, evaluating the size distribution of exosomes
obtained from single capture antibodies will be addition‐
ally advantageous. However, this clearly indicates that the
nanoscale characterization of isolated exosomes is advisa‐
ble, particularly in detailed proteomic investigations such
as mass spectroscopy studies, where biological purity and
the chemical properties of a sample greatly influence
protein identification [43]. In addition, our data presents
more implications pertaining to cell biological functions
[44], as UC exosomes and IA exosomes display different
sub-populations. For example, UC exosomes with smooth‐
er topographic surfaces may have distinct physical charac‐
teristics for cell binding and activation, whereas some of
the epitopes of surface markers on IA exosomes may not be
accessible, due to their rough surface. In addition, exo‐
somes isolated from each individual surface marker may
have different biochemical, genomic, or proteomic proper‐
ties and may have the potential for being employed as
diagnostic biomarkers.

4. Materials and Methods

4.1 U87 cell culture

U87 cells were cultured in Dulbecco's Modified Eagle
Medium (DMEM) and supplemented with 10% heat
inactivated fetal bovine serum (FBS), 100 units/mL Penicil‐
lin G, and 100 µg/mL Streptomycin. Cells were incubated
at 37°C and 5% carbon dioxide. At approximately 80%
confluence, cells were washed with PBS and passaged
using a 0.25% trypsin-EDTA treatment for dissociation.

4.2 Exosome isolation

U87 cells were cultured in six 60 mm Petri dishes (falcon)
with FBS-originated-exosome-free media (as instructed in

6 J Circ Biomark, 2016, 5:11 | doi: 10.5772/64148



the protocol by Théry; FBS was ultracentrifuged at 100 000
g for 2 hours at 4ºC, then filtered with a 0.22 µm sterile filter)
for 48 hours; after 48 hours, the media containing U87
exosomes was isolated. Total cell count was 2x107 and 24
mL of U87-exosome-containing media was obtained. For
the following isolation methods, the same batch of media
was used.

4.3 Isolation of exosomes using immunoaffinity (IA) magnetic
beads kit method

The procedure suggested in the manufacturer’s manual
(JSR Life Science, Tokyo, Japan) was followed; 200 µL of
U87 exosome-containing media was incubated with 100 µL
of capture beads for 60 min at room temperature (RT) on a
shaker. Beads were separated from the supernatant by a
magnet and washed with a 0.5mL wash buffer three times;
50 µL of elution buffer was added to the beads and the
beads were gently re-suspended, then incubated without
mixing for 3 min at RT. Beads were separated and the
supernatant was transferred to a Slide-A-Lyzer™ Dialysis
Cassette (Thermo Fisher Scientific, MA, USA), then
dialyzed against PBS. Purified exosomes were stored at 4°C
until AFM imaging.

4.4 Isolation of exosomes using the ultracentrifugation (UC)
method

Exosome isolation using ultracentrifugation was followed
by a previously published protocol (Figure 1) [14]. To
remove cells/debris, the exosome-containing media was
centrifuged at 2000g for 20 min at 4°C and supernatant 1
was isolated. Then, supernatant 1 was centrifuged at 10
000g for 30 min at 4°C to remove microvesicles and again,
supernatant 2 was carefully isolated. To isolate exosomes,
supernatant 2 was ultracentrifuged at 100 000g for 2 hours
at 4°C and supernatant 3 was discarded. To wash exo‐
somes, the pellet was re-suspended in 1 mL PBS and the
mixture was ultracentrifuged at 100 000g for 1 hour at 4°C,
and supernatant 4 was discarded. Purified exosomes were
re-suspended in 100 µL of PBS and stored at 4°C until AFM
imaging.

4.5 Sample preparation and air imaging

Exosome samples purified from U87 were incubated on
freshly cleaved mica for 5 min, washed with deionized
water to remove any unbound exosomes and air-dried
overnight. Samples were imaged by Dimension ICON
(Bruker Instruments, CA, USA) using the tapping mode via
TESP cantilever (Bruker Instruments, CA, USA) and
images were recorded at 1024 samples per line at 1 Hz.
Image processing was done using SPIPTM software. For
exosome yield calculation, images at a size of 1 µm x 1 µm
and a resolution of 512 samples per line, at 1 Hz, were used.
For exosome surface roughness measurements, images
were processed with SPIPTM to obtain Ra (arithmetic
average of the absolute values) and Rq (root mean squared)
values.

4.6 Sample preparation and fluid imaging

To anchor exosomes on the surface, (3-Aminopropyl)
triethoxysilane (APTES) modified mica was prepared; 10
µL of 10% APTES solution was incubated with clean,
freshly cleaved mica discs in a vacuum chamber overnight.
Nitrogen gas was purged and the mica discs were stored in
a nitrogen gas chamber; 50 µL of the exosome sample was
incubated on an APTES modified mica disc for 10 min. To
remove unbound exosomes, mica was washed with
deionized water four times; 50 µL of deionized water was
added on mica prior to imaging. Samples were imaged
using Dimension Icon (Bruker Instruments, CA, USA) with
MLCT-E cantilevers (Bruker) for fluid imaging in QNM
peak force mode [38,45]. AFM probes were calibrated using
a thermal method and images were taken at 256 samples
per line, at 0.6 Hz, then processed by SPIPTM.

5. Conflict of Interest

The authors report no conflict of interest.

6. Acknowledgements

This work was supported by International Center for
Materials Nanoarchitectonics Satellite (MANA) at the
National Institute for Materials Science (NIMS), Tsukuba,
Japan. We acknowledge the use of AFMs at the Nano and
Pico Characterization Laboratory at California NanoSys‐
tems Institute. We also acknowledge JSR Life Science for
providing an ExoCap kit for isolating exosomes. We thank
to Dr. K. Das at UCLA Medical Centre for providing the
U87 cell line and Dr. E. Reisler at Department of Chemistry
and Biochemistry and Molecular Biology Institute at UCLA
for using the ultracentrifugation facility.

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