Subscriber access provided by UNIVERSITY OF TOLEDO LIBRARIES
Functional Structure/Activity Relationships
Characterization of endogenous nanoparticles from roasted chicken breasts Xunyu Song, Lin Cao, Shuang Cong, Yukun Song, and Mingqian Tan J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.8b01988 • Publication Date (Web): 22 Jun 2018 Downloaded from http://pubs.acs.org on June 23, 2018
Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.
is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.
Page 1 of 34
Journal of Agricultural and Food Chemistry
1
Characterization of endogenous nanoparticles from roasted chicken breasts
2
3
Xunyu Song,1,2 Lin Cao,1,2 Shuang Cong,1,2 Yukun Song,1,2 and Mingqian
4
Tan1,2*
5 6 7
1
School of Food Science and Technology, National Engineering Research Center of
8
Seafood, Dalian Polytechnic University, Qinggongyuan1, Ganjingzi District,
9
Dalian116034, Liaoning, China
10 11
2
Engineering Research Center of Seafood of Ministry of Education of China,
Dalian116034, Liaoning, China
12 13
*Corresponding author (Tel& Fax: +86-411-86318657, E-mail:
[email protected],
14
ORCID: 0000000275350035).
15 16 17 18 19
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
20
Abstract
21
Emergence of endogenous nanoparticles in thermally processed food has aroused
22
much attention due to their unique properties and potential biological impact. The aim
23
of this study was to investigate the presence of fluorescence nanoparticles in roasted
24
chicken breasts, elemental composition, physico-chemical properties and their
25
molecular interaction with human serum albumin (HSA). Transmission electron
26
microscopy analysis revealed that the foodborne nanoparticles from roasted chicken
27
were nearly spherical with an average particle size of 1.7 ± 0.4 nm. The elemental
28
analysis of X-ray photoelectron spectroscopy showed the composition of
29
nanoparticles as 47.4% C, 25.8% O and 26.1% N. The fluorescence of HSA was
30
quenched by the nanoparticles following a static mode, and the molecular interaction
31
of nanoparticles with HSA was spontaneous (∆G0<0), where hydrogen bonding and
32
van der Waals forces played an important role during HSA-nanoparticles complex
33
stabilization through thermodynamic analysis by isothermal titration calorimetry. The
34
principal location of the nanoparticles binding site on HSA was primarily in site I as
35
determined by site-specific marker competition. The conformational of HSA was also
36
changed and ɑ-helical structure decreased in the presence of nanoparticles. Our
37
studies revealed that fluorescent nanoparticles were produced after roasting of chicken
38
breast at 230 oC for 30 min for the first time. The obtained nanoparticles can interact
39
with HSA in a spontaneous manner, thus providing valuable insight into foodborne
40
NPs as well as their effects to human albumin protein.
41
Keywords: roasted chicken breasts, fluorescent nanoparticles, human serum albumin,
ACS Paragon Plus Environment
Page 2 of 34
Page 3 of 34
Journal of Agricultural and Food Chemistry
42
thermodynamics, food thermal processing
43
44
1. Introduction
45
Chicken meat is one of the most widely accepted foods with high nutritional
46
value. As an excellent source of protein, chicken meat has a favourable ratio of
47
unsaturated to saturated fatty acids in its lipids, and provides the necessary vitamins
48
and minerals.1 The roasted chicken breast (RCB) is a popular meat product all over
49
the world because of its wonderful flavor and savory taste. The U.S. annual per capita
50
consumption of chicken is more than 40 kg.2 In recent years, an increased number of
51
studies on RCB has attracted public concern due to the potential health risks
52
associated with high temperature processing.3 These studies focused on the
53
unsaturated
54
hazardous substance like acrylamide, benzopyrene and heterocyclic amines formed
55
during roasting.4-7 These compounds are known to cause several major diseases. From
56
a nutritional point of view, the roasting method can cause significant change of
57
the safety and nutritional quality of the chicken.4 Actually, Maillard and a series of
58
chemical reactions in the chicken roasting process not only produce the
59
above-mentioned harmful substances, but also generate some nanoparticles (NPs)
60
with unknown characteristics and potential health effects.
fatty
acids
content
decreased and formation of a class of
61
Recently, a growing number of studies have described the existence of NPs in the
62
daily food containing Maillard reaction products. For example, Sk et al.8 reported the
63
presence of NPs in some high-carbohydrate food in which the preparation processes
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
64
included heating of the raw material and caramelization reaction. We have reported
65
the fluorescent NPs in several commercial beverages,9 which were spherical in shape
66
and well dispersed with a 1-40 nm size and exhibiting an excitation-dependent
67
emission behaviour. In the meantime, we also found a class of carbon nanodots
68
collected in roasted fish which were amorphous nanoparticles.10 The above-mentioned
69
NPs in food samples are usually very small, highly water soluble and strongly
70
fluorescent under light excitation. Therefore, they can pass through the cell membrane
71
into the human body and will inevitably contact with the proteins in the blood.
72
However, the thermodynamic properties of molecular interaction between NPs and
73
plasma protein are less studied and our knowledge in this field is still in its infancy.
74
Human serum albumin (HSA), the most abundant protein in human blood plasma,
75
has complex chemical properties and a series of functional groups that allow
76
multifunctional chemical derivatization.11 Thus, HSA has been studied for its
77
interaction with nano-sized poly(amidoamine) dendrimers and titanium dioxide as a
78
model serum protein.12,13 Xu et al.14 reported the interaction between synthetic carbon
79
nanodots with HSA through hydrophobic and van der Waals forces and their effects
80
on the transportation function. Huang et al.15 studied the in vitro molecular interaction
81
between synthetic nanomaterials and HSA using a spectroscopic method, and found
82
significant binding between them. we recently reported the presence of nanoparticles
83
could cause fluorescence quenching of HSA via the electrostatic interaction16. These
84
studies demonstrated the possible interactions between many exogenous NPs and
85
HSA, causing unpredictable impacts on the function of HSA. These results offered us
ACS Paragon Plus Environment
Page 4 of 34
Page 5 of 34
Journal of Agricultural and Food Chemistry
86
some insight and motivated us to explore the interaction between endogenous NPs
87
from food and HSA.
88
In this study, the presence of fluorescent NPs in RCB at 230 oC was investigated.
89
The extracted NPs were highly fluorescent, nano-sized, and their physicochemical
90
properties thoroughly characterized. Importantly, we demonstrated the in vitro
91
molecular interaction between the NPs and HSA for the first time using a
92
spectroscopic method and thermodynamic analysis technique. In addition, the binding
93
site of the NPs from roasted chicken breast and HSA was confirmed by competition
94
experiments to gain a deeper understanding of the interaction, and Fourier transform
95
infrared (FTIR) spectroscopy experiments were used to further prove the changes of
96
the nanoparticles to the HSA structure. The most important observation is that the
97
endogenous NPs derived from the roasted chicken breast could bind within site I of
98
HSA and result in a static fluorescence quenching and a conformational change of
99
HSA at the same time. The foodborne NPs from the roasted breasts is likely to attract
100
people’s attention to their influence of human albumin protein.
101
2. Materials and Methods
102
2.1 Materials
103
Chicken breasts was purchased at a local market in Dalian, China. HSA was
104
procured from Beijing Solarbio Science & Technology Co., Ltd. (Beijing, China).
105
Ibuprofen and warfarin were bought from Adamas-beta Co. Ltd. (Shanghai, China).
106
Unless otherwise stated, all other chemicals and reagents were of analytical reagent
107
grade and purchased from local suppliers.
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
108
2.2 Instrumentation
109
Transmission electron microscopy (TEM) analysis was performed using a
110
transmission electron microscope (JEM-2100, JEOL, Tokyo, Japan) at a voltage of
111
200 kV. The molecular weight of the NPs was determined by matrix-assisted laser
112
desorption
113
Autoflex III, Bruker Daltonics, Bremen, Germany), employing 2,5-dihydroxybenzoic
114
acid as the matrix. X-ray diffraction (XRD) data were collected on a diffractometer
115
(XRD-6100, Shimadzu, Kyoto, Japan) with a Cu Kα (λ =1.54060 Å) radiation source
116
from 5 to 60° at 5° min-1 scanning speed. FTIR spectra were obtained by using a FTIR
117
spectrometer (PerkinElmer, Norwalk, CT, U.S.A.). X-ray photoelectron spectroscopy
118
(XPS) spectra of the prepared NPs from RCB were procured using an ESCALAB250
119
XPS system (Thermo VG, Waltham, MA, USA). Absorption spectra were recorded by
120
an ultraviolet-visible (UV-vis) light spectrophotometer (Lambda 35, PerkinElmer,
121
Norwalk, CT, USA), while fluorescence spectra were carried out on a fluorescence
122
spectrometer (F-2700, Hitachi, Tokyo, Japan) at room temperature. Isothermal
123
titration calorimetry (ITC) analyses were obtained by an isothermal titration
124
calorimeter (Affinity ITC SV, TA Instruments, USA). Circular dichroism (CD) spectra
125
were recorded using a JASCO J-1500 CD spectrometer (JASCO, Tokyo, Japan).
126
2.3 Purification of NPs from roasted chicken breast
ionization
time-of-flight
mass
spectrometry (MALDI-TOF-MS,
127
Chicken breasts (190 g) was cut into 1 x 1 x 1 cm pieces after being washed
128
several times with distilled water. Then, they were roasted in an electric heating oven
129
(Rational, SCC-WE-101, Bavaria, Germany) at 230 oC for 30 min. After cooling to
ACS Paragon Plus Environment
Page 6 of 34
Page 7 of 34
Journal of Agricultural and Food Chemistry
130
room temperature, the scorched parts were stripped from the surface of the roasted
131
chicken, crushed and extracted with 1200 mL ethanol (100%) at room temperature for
132
36h. After removing the solid precipitate, the ethanol solution was evaporated to
133
remove the solvent. The obtained sticky product was dissolved in 100 mL distilled
134
water and extracted with chloroform (3 × 250 mL). The water phase was subjected to
135
dialysis using a membrane with a molecular weight cutoff of 500 Da against distilled
136
water for 3 days to remove the impurities. The yield of the NPs after lyophilization
137
was approximately 1 g [MALDI-TOF (m/z, [M + H]+): 1033.041 (observed)].
138
2.4 Fluorescence analysis of interaction
139 140 141
To unravel fluorescence quenching mechanism, the fluorescence data were calculated by using the Stern-Volmer equation: F0 = 1 + K q τ 0 [Q ] = 1 + K sv [Q ] F
(1)
142
Where F0 and F are the fluorescence intensity values of the protein HSA in the
143
absence and presence of NPs, respectively. KSV is the Stern-Volmer quenching
144
constant, and [Q] is the molar concentration of the quencher NPs. Kq represents the
145
bimolecular quenching rate, and τ0 is the average fluorescence lifetime of the HSA in
146
the absence of quencher, and its value was taken as 10 ns for biomacromolecules.
147 148
For static quenching procedure, the modified Stern-Volmer equation was used for calculating the quenching data.17
149
F0 F 1 1 1 = 0 = + F0 − F ∆F f a K a [Q] f a
150
Where fa represents the fraction of accessible fluorescence, and Ka represents the
151
effective quenching constant for the accessible fluorophore.
ACS Paragon Plus Environment
(2)
Journal of Agricultural and Food Chemistry
152
3. Results and discussion
153
3.1 Characterization of the NPs extracted from the roasted chicken breast
154
Production of endogenous NPs during food heat processing is a very interesting
155
topic because they may render unknown biological effects after oral absorption. To
156
confirm the presence and formation of NPs after roasting, the extraction products
157
from RCB were dissolved with distilled water, and characterized by TEM using that
158
from raw chicken breast powder (RCBP) as a control. The photographs of raw and
159
roasted chicken breast are shown in Figure 1b and their corresponding images of
160
aqueous solution under UV illumination are displayed in Figure 1c. TEM image of the
161
NPs from RCB shows that they were nearly spherical with excellent monodispersity
162
(Figure 1d). The inset represents the high resolution transmission electron microscopy
163
image and no lattice planes were observed, revealing an amorphous structure of NPs
164
as observed previously.18 The size distribution of NPs is relatively narrow falling
165
within 0.6-2.8 nm with an average particle size of 1.7±0.4 nm (Figure 1d and 1e).
166
However, TEM analysis showed that no NPs were formed from the extract of raw
167
chicken breast without roasting (Figure S1). The XRD measurements indicated that
168
there was a broad peak around 2θ =22.6° with a d-spacing of 0.39 nm, which
169
demonstrated that the NPs had an amorphous structure (Figure 1f). This result is
170
consistent with that of the high resolution transmission electron microscopy image.
171
The mean molecular weight of NPs was 1033 as indicated by the MALDI-TOF-MS
172
result (Figure S2), confirming that the single nanoparticle might have about 74 -CH2-
173
units, or a small number of structures containing carbon, hydrogen, oxygen and
ACS Paragon Plus Environment
Page 8 of 34
Page 9 of 34
Journal of Agricultural and Food Chemistry
174
nitrogen. A reasonable assumption is that the protein and carbohydrates of the chicken
175
breasts were decomposed into amorphous carbon-dot-like nanoparticles during the
176
roasting process.
177
Surface function compositions of the NPs derived from the roasted chicken
178
breasts were further examined by FTIR spectroscopy using RCBP as a control. As
179
depicted in Figure 2a, the NPs and RCBP both show a broad absorption peak in the
180
range of 3302-3411 cm-1 ascribed to the O-H stretching vibration of a large number of
181
hydroxyl groups. The large number of hydroxyl groups of NPs may play an important
182
role during the interaction with other proteins. The sharp peaks around 2925-2927
183
cm-1 correspond to the C-H vibrations of methylene. Unlike the RCBP, the NPs show
184
predominance of carboxyl groups and aromatic C=C or CONH2 groups at 1652 cm-1
185
and C-N groups at 1400 cm-1. The peak at 1109 cm-1 indicates the existence of
186
aromatic alkoxy (C-O-C) bonds of the NPs. However, the RCBP shows the
187
characteristic strong absorption peaks at 1538 cm-1, which is assigned to the N-H
188
stretching vibrations.19 The decline of amide functional group strength of NPs might
189
be ascribed to the dissociation of the N-H bond and all of these semaphores reveal
190
that the molecular structures of the NPs mainly contain hydrophilic and polycyclic
191
groups which are connected with the nanostructures.20
192
XPS spectrum in Figure 2b shows two predominant peaks at around 284.8 and
193
531.9 eV as well as a weaker peak at 399.6 eV of NPs, which is associated with three
194
elements namely C, O and N, respectively. The compositions of the NPs were
195
measured to be 69.87% C, 19.81% O and 9.91% N. Compared with the XPS result of
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
Page 10 of 34
196
RCBP (Figure S3), the NPs from the RCB are probably a kind of N-doped NPs with a
197
higher amount of elemental oxygen after oxidation at high temperature (Table S1).
198
The increase in the content of nitrogen and oxygen of NPs during roasting suggests
199
that the proteins underwent thermal decomposition and air oxidation. The pyrolysis is
200
quite similar to that of carbon dots derived from N-acetylcysteine and diamine via
201
hydrothermal treatment.21, 22 The high-resolution XPS spectra further confirmed the
202
presence of different functional groups on the NPs. The C1s spectrum of NPs can be
203
deconvoluted into three peak components with binding energies (Bes) at 284.4, 285.9
204
and 288.1 eV that belong to the C=C, C-O-C/C=N and O-C=C groups, respectively
205
(Figure 2c).23 The N1s core-level spectrum of NPs (Figure 2d) can also be split into
206
three peaks with BEs at 398.9, 399.9 and 400.5, corresponding to the pyridinic
207
nitrogen
208
respectively.24 These data show that the NPs obtained from the RCB are mostly
209
composed of graphitic carbon (sp2) and carbon defects (sp3), and contain an
210
abundance of hydroxy and carbonyl/carboxylate groups at their surfaces.
(C=N-C),
amines
and
amides,
and
H-bonded/protonated
amine,
211
The optical performance of NPs was first analyzed by UV-vis absorption and
212
fluorescence spectroscopy, respectively. Figure 3a shows the typical absorption and
213
fluorescence emission spectra of the NPs in aqueous solution. The UV-vis absorption
214
spectrum exhibits only one weak peak at around 250 nm and extends to 600 nm
215
without noticeable fine structures, demonstrating the presence of aromatic π orbitals.
216
The absorption bands in the region of 250-300 nm are due to the n-π* electronic
217
transitions of the p-π.25 The fluorescence emission spectrum displays a highest value
ACS Paragon Plus Environment
Page 11 of 34
Journal of Agricultural and Food Chemistry
218
of 385 nm under the excitation at 320 nm, and the emission wavelength and intensity
219
show clear excitation wavelength dependency. The bathochromic emission
220
phenomenon is consistent with previous reports on NPs.18 This complex behavior
221
might be associated with various emitting centers and the different surface states
222
present in the suspension and attributed to the different surface states of the NPs.26 In
223
short, the decay of fluorescence emission was non-monoexponential for the NPs
224
soliquoid with a lifetime approximately 4.80 ns (Figure 3b). The quantum yield of
225
NPs was 10.8% at the excitation wavelength of 320 nm, by calibrating against quinine
226
sulfate as a reference. The relatively high quantum yield of NPs may originate from
227
the high nitrogen contents that lead to the formation of more trapping excitons under
228
excitation, and it is similar to different NPs found in carbohydrate based food.8, 9
229
It is noteworthy that the fluorescence intensity of NPs could be affected by
230
certain metal ions. As shown in Figure 3c, an equal amount of Ca (II), Mg (I), Mn (I),
231
Co (II), Ni (II) and Fe (II) ions performed a negligible quenching effect. Interestingly,
232
Cu (II) resulted in a weak growth and Fe (III) displayed a significant quenching effect
233
that nearly 90% fluorescence intensity of NPs was declined. The results are attributed
234
to the fact that ions of Cu (II) and Fe (III), etc. are oxidants, and the charges on the NP
235
surface will most likely be captured by these ions. The oxidation-reduction may
236
promote the recombination of non-radiative electrons/holes from the NPs by an
237
electron transfer process.27 It also displayed a pH-dependent fluorescence behavior
238
when the pH ranged from 2 to 11 (Figure 3d). Fluorescence intensity of NPs increases
239
with the increase of pH, and reaches its maximum at pH 5. When the pH is in extreme
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
240
conditions (at pH 2 or 11), the fluorescence intensity is reduced by about 20 %. Such
241
pH-dependent behaviour is probably due to the dissociation of different functional
242
groups on the surface of the NPs, which may participate in electron-withdrawing and
243
electron-accepting processes.28 Moreover, the influence of NaCl concentration on
244
fluorescence intensity of the NPs was also investigated (Figure S4). When the NaCl
245
concentration increased from 0 to 0.9 mol L-1, the fluorescence intensity of NPs
246
remained unchanged. The bleaching experiment of the NPs in aqueous solution under
247
the UV excitation light showed that the NPs had excellent photostability and no signs
248
of attenuation were displayed for 60 minutes (Figure S5). Thus, these stability
249
properties may require more attention if the NPs can interact with proteins.
250
HSA acts as an important vehicle for transporting hormones, fatty acids, and
251
other compounds and maintains oncotic pressure, among other functions, which
252
possesses three intrinsic fluorophores: tryptophan, tyrosine and phenylalanine
253
residues.29 The variations of fluorescence intensity for HSA could be attributed to the
254
change of amino acid residues. Figure 4a displays the fluorescence spectra of HSA
255
before and after addition of increasing concentrations of NPs derived from RCB. The
256
HSA shows a typical fluorescence emission at 338 nm, originating from Tryptophan.
257
After adding NPs, the fluorescent intensity of HSA decreased significantly,
258
demonstrating that the addition of NPs quenched the intrinsic fluorescence of HSA
259
molecules. An apparent red shift (from 338 to 343 nm) was observed with increasing
260
NPs concentration. This may possibly suggest that the fluorophores of HSA were
261
moved to a more hydrophilic environment after interacting with NPs.30 A linear
ACS Paragon Plus Environment
Page 12 of 34
Page 13 of 34
Journal of Agricultural and Food Chemistry
262
relationship was found with respect to F0/F-1 values and the tested NPs concentration
263
(Figure 4b), in good agreement with the Stern-Volmer equation.
264
Generally speaking, the mechanism of fluorescence quenching can be ascribed to
265
dynamic and static quenching model. Dynamic quenching merely changes the excited
266
states of the fluorophores, while static fluorescence quenching usually results from
267
non-luminous ground-state complexes formed.31 UV-vis absorption spectrum of
268
fluorophore has been considered as one of the reliable tools to illustrate the
269
fluorescence quenching mechanism of HSA and the protein-ligand complex formation
270
in detail.32 Figure 4c shows the UV-vis absorption spectra of HSA, NPs, HSA-NPs
271
and [HSA-NPs]-NPs (the difference of the absorption spectrum between HSA-NPs
272
and NPs). The spectrum of [HSA-NPs]-NPs does not coincide well with the
273
absorption spectrum of HSA at 210-300 nm, indicating that the absorption spectrum
274
of HSA was affected after the addition of NPs. The result revealed a static quenching
275
mechanism of the HSA-NPs system.
276
Time-resolved fluorescence spectrometry is another highly valuable method to
277
straightly illuminate the precise fluorescence quenching mechanism by analyzing the
278
change of the fluorescence lifetime of a protein complex. In time-resolved
279
fluorescence measurements (Figure 4d), the fluorescence decay curves could be best
280
fitted with biexponential equation and the average fluorescence lifetime of HSA alone
281
and HSA in HSA-NPs system were approximately 4.91 and 4.50 ns, respectively.
282
Thus, the observed change is less than 9%, hence the fluorescence lifetime of HSA
283
was considered to be constant. Moreover, the variety of fluorescence lifetime of NPs
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
284
with the presence of HSA was surveyed to further confirm the fluorescence quenching
285
mechanism. The average fluorescence lifetime of NPs was 4.64 ns in the presence of
286
HSA which was altered only slightly (Figure S6) as compared with that of NPs (4.80
287
ns, Figure 3b). Therefore, we believe that the fluorescence quenching of HSA was
288
induced by the formed complex of HSA-NPs and the liability of static quenching was
289
the major mechanism.
290
3.2 Thermodynamic analysis
291
Over the years, various molecular association mechanisms such as electrostatic,
292
hydrophobic, hydrogen bonding or van der Waals interactions have been proposed for
293
the interaction between protein and NPs.33-36 Specifically, ITC has been extensively
294
used to determine interactions of NPs with HSA and the stoichiometry of proteins
295
bound per nanoparticle derived from the binding curves. Thermodynamic parameters
296
including changes in the enthalpy (∆H), free energy (∆G) and entropy (∆S) can be
297
used to calculate molecular interactions using calorimetric techniques.37, 38 Herein, the
298
sign and dimensions of thermodynamic parameters were employed to provide a
299
comprehensive understanding of the molecular-level interaction mechanism between
300
NPs and HSA. Figure 4e displays the calorimetric profile for the titration of NPs with
301
HSA at ambient temperature. One can see that the correct heat rate of NPs and buffer
302
remained unchanged, while that of the HSA after the addition of NPs increased first
303
then decreased continuously. The heat change per molecule of NPs against the mole
304
ratio (NPs: HSA) at each injection after correcting the heat change for dilution is
305
shown in Figure 4f. The independent site binding model was used to determine the
ACS Paragon Plus Environment
Page 14 of 34
Page 15 of 34
Journal of Agricultural and Food Chemistry
306
thermodynamic parameters, and the fitted parameters were summarized in Table 1.
307
The dissociation constant (Kd) between NPs and HSA was estimated to be 1.29±0.52
308
× 10-4 L mol and the association constant (Ka) was 7.73 × 103 mol L-1 at 298K, which
309
is similar to the previously reported values for different NP-protein complexes.39 This
310
indicates that NPs has binding affinity towards HSA under physiological conditions.
311
The binding stoichiometry (n) per HSA molecule to NP was 1.47±0.11, which is
312
reasonable when considering their sizes. The overall association process between NPs
313
and HSA was spontaneous with a negative standard free energy change (∆G0=-22.20
314
kJ mol-1). Moreover, the process was characterized by a negative standard enthalpy
315
change (∆H0=-3.50±0.33 kJ mol-1) and positive standard entropy change (∆S0=62.71 J
316
mol-1 K-1). Firstly, the process of hydrophobic triggering of the interaction between
317
proteins and ligands is accompanied by a large enthalpy change and a positive entropy
318
change. Therefore, the result cannot be explained by this mechanism. Many cases of
319
relatively larger negative enthalpy change and positive entropy change are usually
320
caused by electrostatic interactions.16 In case of small negative enthalpy change, the
321
binding reaction between HSA and NPs can be ascribed to the interaction of hydrogen
322
bonds or van der Waals. Hence, it is important to carry out further studies at the size
323
and surface charge of NPs and HSA to confirm the major interaction forces between
324
them. The domain I and II of HSA contain most of the negatively charged aspartate
325
and glutamate residues and the isoelectric point of HSA at pH 7.4 is about 4.7.
326
However, the mean zeta potential of NPs of about -4.6 mV is quite small for
327
electrostatic interactions. Moreover, the average particle size of NPs was only 1.7±0.4
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
328
nm, and the surface of NPs is encapsulated by various functional groups like -CONH2
329
and -OH with high oxygen content which is also beneficial to the hydrogen bond
330
interaction between NPs and HSA.15, 39 This results is different from the previously
331
reported mechanism of interaction between nanoparticles derived from roast duck and
332
proteins,16 and the divergence may be due to the different surface groups of NPs.
333
Taken together, it is suggested that the main mechanism of their association process
334
involves hydrogen bonding and van der Waals force interactions between surface
335
amide and hydroxyl groups (-CONH2 and -OH) of NPs with carboxylate groups
336
(-COO-) of Glu and Asp residues of HSA.
337
3.3 Identification of binding sites of NPs on HSA
338
The binding regions of HSA with other nanostructures are site I (subdomain IIA)
339
and site II (subdomain IIIA), which were reported to be located in the hydrophobic
340
cavities of subdomains. Hence, it is important to further confirm the binding site of
341
HSA with NPs derived from RCB. Warfarin and ibuprofen have usually been regarded
342
as typical site-specific probe for Sudlow’s site I and II of HSA, respectively. Herein,
343
the HSA and warfarin (site I marker) and ibuprofen (site II marker) in equimolar
344
concentration (2 × 10-6 mol L-1) were used for the competitive displacement
345
experiments to identify the NPs binding site on HSA. As shown in Figure 5a, when
346
warfarin was added to HSA, the maximum emission showed a significant red shift,
347
but no change was observed for HSA with the addition of ibuprofen (Figure 5b). To
348
explore the effects of site markers on the binding of HSA-NPs system more directly,
349
the binding constant for the system was analyzed using the modified Stern-Volmer
ACS Paragon Plus Environment
Page 16 of 34
Page 17 of 34
Journal of Agricultural and Food Chemistry
350
equation (Figure 5c). The value of binding constant in the presence of warfarin was
351
obviously variable, whereas a lesser effect of ibuprofen was noted. These results
352
implied that there was a more extensive competition between the NPs and warfarin,
353
and the binding sites for NPs were primarily located in site I (sub-domain IIA) of
354
HSA (Figure 5d).
355
3.4 Conformational change investigation
356
FT-IR spectrometry is a powerful analytical tool to examine the conformational
357
variation in the secondary structure of protein and the interactions with NPs. As
358
shown in Figure 5e, the absorption band of amide I appeared in the region 1600-1650
359
cm-1 (C=O stretch) and amide II band in the region 1500-1550 cm-1 (N-H bending and
360
C-N stretching vibrations), which was compatible with the previous reports.15, 40 The
361
position of the amide I peak shifted slightly from 1646 to 1642 cm-1 and that of the
362
amide II band shifted from 1548 to 1543 cm-1. It is noteworthy that a peak appeared in
363
1581
364
C=O stretching vibration, N-H bending and stretching vibration bands of C-N groups
365
in the polypeptides of HSA were influenced by NPs. Therefore, the secondary
366
structure of the HSA has been induced the rearrangement with the addition of NPs,
367
which is in agreement with the results obtained from ITC experiments.
cm-1 after
the
addition
of
NPs.
The
result
suggested
that
the
368
CD spectroscopy is also regarded as a sensitive and valuable method to study the
369
structure and stability of proteins. It has been reported that the CD spectra of HSA
370
displays two negative absorption bands at 208 and 222 nm, which are contributed by
371
the peptide bond of the α-helix.41 As illustrated in Figure 5f, the relative band
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
372
intensities of curves 1 to 5 decreased at regular intervals with addition of different
373
concentrations of NPs, indicating a distinct conformational change of the protein with
374
the loss of α-helix content. CD data were computed using Jasco Secondary Structure
375
Estimation (SSE) software and the results are listed in Table 2. The more change of
376
α-helix content is due to the higher concentration of NPs. When the mole ratio of
377
HSA to NPs reaches 1: 100, the content of α-helix decreases from 54.7 to 50.7%. As
378
mentioned above, the binding of NPs may result in the loosening and unfolding of the
379
HSA skeleton and the stronger structural change may affect biological function of
380
protein with the polypeptide chain destabilized.42 These changes clearly demonstrate
381
that NPs were bound with amino acid residues of the main protein chain and wrecked
382
their hydrogen bond network and the suggestion is in good agreement with the results
383
procured by FTIR spectrometry.
384
This work demonstrated the presence of a foodborne NPs specimen generated
385
during the roasting of chicken breast. The strongly fluorescent NPs exhibited an
386
excitation-dependent emission behavior and excellent photostability. Under
387
physiological pH, the intrinsic fluorescence of HSA was quenched by NPs through
388
static mechanism, due to the interaction between HSA and NPs. Thermodynamic
389
parameters revealed that the molecular interaction of NPs with HSA was spontaneous
390
(∆G0<0), possibly due to the presence of hydrogen bond and van der Waals forces.
391
The binding sites for NPs were basically located in site I of HSA and the secondary
392
structures of HSA changed with the addition of NPs. Thus, this work contributes to
393
drawing attention to the presence of foodborne NPs and their influence on human
ACS Paragon Plus Environment
Page 18 of 34
Page 19 of 34
Journal of Agricultural and Food Chemistry
394
albumin protein.
395 396
ASSOCIATED CONTENT
397
Supporting Information
398
The Supporting Information is available free of charge on the ACS Publications
399
website at DOI: XXXXXXX.
400
TEM image, XPS spectrum of the extract from raw chicken breast powder without
401
roasting; MALDI-TOF-MS spectral data, photostability, fluorescence decay curve,
402
effect of NaCl solution concentration on the fluorescence intensity of the
403
nanoparticles derived from RCB; composition analysis of the nanoparticles derived
404
from RCB at 230 oC and raw chicken breast powder.
405
406
Acknowledgement
407
This work was supported by the National Key Research and Development
408
Program of China (2017YFD0400103, 2016YFD0400404). We thank Prof. F. Shahidi
409
and Prof. Dayong Zhou for correcting and spelling grammar mistakes.
410
References
411
(1) P. Konieczka, A. J.; Rozbicka-Wieczorek, M.; Czauderna; Smulikowska, S.
412
Beneficial effects of enrichment of chicken meat with n-3 polyunsaturated
413
fatty acids, vitamin E and selenium on health parameters: a study on male
414
rats. Animal 2016, 11, 1412-1420.
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
415
(2) Enns, D. K.; Crandall, P. G.; O'Bryan, C. A.; Griffis, C. L.; Martin, E. M. A
416
2-step cooking method of searing and hot water pasteurization to maximize
417
the safety of refrigerated, vacuum packaged, chicken breast meat. J. Food Sci.
418
2007, 72, 113-119.
419
(3) Wen, S.; Zhou, G.; Li, L.; Xu, X.; Yu, X.; Bai, Y.; and C. Li, J. Agric. Effect
420
of cooking on in vitro digestion of pork proteins: a peptidomic perspective.
421
Food Chem. 2015, 63, 250-261.
422
(4) Gonçalves, A. T.; Oliveira, M. B.; Sanches-Silva, A.; Cristina, B. A.; Costa,
423
H. S. The impact of cooking methods on the nutritional quality and safety of
424
chicken breaded nuggets. Food Funct. 2016, 7, 2736-2746.
425 426
(5) Hogervorst, J. Epidemiological findings on health risks associated with dietary acrylamide. Toxicol Lett. 2014, 229, S27-S27.
427
(6) Kalkhof, S.; Dautel, F.; Loguercio, S.; Baumann, S.; Trump, S.; Jungnickel,
428
H.; Otto, W.; Rudzok, S.; Potratz. S.; Luch, A. Establishing the pathway and
429
time resolved benzo[a]pyrene toxicity on Hepa1c1c7 cells at toxic and
430
subtoxic exposure. J. Proteome Res. 2015, 14, 164-182.
431
(7) Oz, F.; Yuzer, M. O. The effects of cooking on wire and stone barbecue at
432
different cooking levels on the formation of heterocyclic aromatic amines and
433
polycyclic aromatic hydrocarbons in beef steak. Food Chem. 2016, 203,
434
59-66.
435 436
(8) Sk, M. P.; Jaiswal, A.; Paul, A.; Ghosh S. S.; Chattopadhyay, A. Presence of amorphous carbon nanoparticles in food caramels. Sci Rep-UK 2012, 2, 383.
ACS Paragon Plus Environment
Page 20 of 34
Page 21 of 34
Journal of Agricultural and Food Chemistry
437
(9) Liao, H.; Jiang, C.; Liu, W.; Vera, J. M.; Seni, O. D.; Demera, K.; Yu C.;
438
Tan, M. Fluorescent nanoparticles from several commercial beverages: their
439
properties and potential application for bio-imaging. J. Agric. Food Chem.
440
2015, 63, 8527-8533.
441
(10)Bi, J.; Li, Y.; Wang, H.; Song, Y.; Cong, S.; Li, D.; Zhou, D.; Zhu, B. W.;
442
Tan, M. Physicochemical properties and cytotoxicity of carbon dots in grilled
443
fish. New J. Chem. 2017, 41, 8490-8496.
444 445
(11)Hu, Y. J.; Liu Y.; Xiao, X. H. Investigation of the interaction between berberine and human serum albumin. Biomacromolecules 2009, 10, 517-521.
446
(12)Giri, J.; Diallo, M. S.; Simpson, A. J.; Liu, Y.; Goddard, W. A.; Kumar R.;
447
Woods, G. C. Interactions of poly (amidoamine) dendrimers with human
448
serum albumin: binding constants and mechanisms. Acs Nano 2011, 5,
449
3456-3468.
450
(13)Vergaro, V.; Carlucci, C.; Cascione, M.; Lorusso, C.; Conciauro, F.; Scremin,
451
B. F.; Congedo, P. M.; Cannazza, G.; Citti C.; Ciccarella, G. Interaction
452
between human serum albumin and different anatase TiO2 nanoparticles: a
453
nano-bio interface study. Nanomater. Nanotechnol. 2015, 5, 30.
454
(14)Xu, Z.Q.; Yang, Q.Q.; Lan, J.Y.; Zhang, J.Q.; Peng, W.; Jin, J.C.; Jiang, F.L.;
455
Liu, Y. Interactions between carbon nanodots with human serum albumin and
456
γ-globulins: The effects on the transportation function. J. Hazard. Mater.
457
2016, 301, 242-249.
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
458
(15)Huang, S.; Qiu, H.; Xie, J.; Huang, C.; Su, W.; Hu B.; Xiao, Q. Systematical
459
investigation of in vitro molecular interaction between fluorescent carbon
460
dots and human serum albumin. Rsc Adv. 2016, 6, 44531-44542.
461
(16)Cong, S.; Bi, J.; Song, X.; Yu, C.; Tan, M. Ultrasmall fluorescent
462
nanoparticles derived from roast duck: their physicochemical characteristics
463
and interaction with human serum albumin. Food Funct. 2018, 9, 2490-2495.
464
(17)Lehrer, S.; Braune, A.; Blaut, M. Corrections-solute perturbation of protein
465
fluorescence. the quenching of the tryptophyl fluorescence of model
466
compounds and lysozyme by iodide ion. Biochemistry 1971, 10, 3254-3263.
467
(18)Jiang, C.; Wu, H.; Song, X.; Ma, X.; Wang J.; Tan, M. Presence of
468
photoluminescent carbon dots in Nescafe® original instant coffee:
469
applications to bio-imaging. Talanta 2014, 127, 68-74.
470
(19)Liu, Y.; Chen, Y.R.; Ozaki, Y. Two-dimensional visible/near-infrared
471
correlation spectroscopy study of thermal treatment of chicken meats. J.
472
Agric. Food Chem. 2000, 48, 901-908.
473
(20)Li, Y.; Bi, J.; Liu, S.; Wang, H.; Yu, C.; Li, D.; Zhu, B.W.; Tan, M. Presence
474
and formation of fluorescence carbon dots in grilled hamburger. Food Funct.
475
2017, 8, 2558-2565.
476 477
(21)Hu, S.L. One-step synthesis of fluorescent carbon nanoparticles by laser irradiation. J. Mater. Chem. 2008, 19, 484-488.
ACS Paragon Plus Environment
Page 22 of 34
Page 23 of 34
Journal of Agricultural and Food Chemistry
478
(22)Sk, M.P.; Chattopadhyay, A. Induction coil heater prepared highly
479
fluorescent carbon dots as invisible ink and explosive sensor. Rsc Adv. 2014,
480
4, 31994.
481
(23)Wang, D.; Zhu, L.; Mccleese, C.; Bruda, C.; Chen, J.F.; Dai, L. Fluorescent
482
carbon dots from milk by microwave cooking. Rsc Adv. 2016, 6,
483
41516-41521.
484
(24)Briscoe, J.; Marinovic, A.; Sevilla, M.; Dunn, S.; Titirici, M. Biomas-derived
485
carbon quantum dot sensitizers for solid-state nanostructured solar cells.
486
Angew. Chem. Int. Edit. 2015, 54, 4463-4468.
487
(25)Wang, Z.; Liao, H.; Wu, H.; Wang, B.; Zhao, H.; Tan, M. Fluorescent carbon
488
dots from beer for breast cancer cell imaging and drug delivery. Anal
489
Methods-UK. 2015, 7, 8911-8917.
490
(26)Liu, C.; Zhang, P.; Zhai, X.; Tian, F.; Li, W.; Yang, J.; Liu, Y.; Wang, H.;
491
Wang, W.; Liu, W. Nano-carrier for gene delivery and bio-imaging based on
492
carbon dots with PEI-passivation enhanced fluorescence. Biomaterials 2012,
493
33, 3604-3613.
494
(27)Zu, Y.; Bi, J.; Yan, H.; Wang, H.; Song, Y.; Zhu, B.W. Tan, M.
495
Nanostructures
derived
from
starch
496
bio-imaging. Nanomaterials 2016, 6, 130.
and
chitosan
for
fluorescence
497
(28)Jia, X.; Li, J.; Wang, E. One-pot green synthesis of optically pH-sensitive
498
carbon dots with upconversion luminescence. Nanoscale 2012, 4, 5572-5575.
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
499
(29)Javaherian, A.D.; Yusifov, T.; Pantazis, A.; Franklin, S.; Gandhi, C.S.;
500
Olcese, R. Metal-driven operation of the human large-conductance voltage-
501
and Ca2+-dependent potassium channel (BK) gating ring apparatus. J. Biol.
502
Chem. 2011, 286, 20701-20709.
503
(30)Sheng, F.; Wang, Y.; Zhao, X.; Tian, N.; Hu, H.; Li, P. Separation and
504
identification of anthocyanin extracted from mulberry fruit and the pigment
505
binding properties toward human serum albumin. J. Agric. Food Chem. 2014,
506
62, 6813-6819.
507 508 509 510
(31)Eftink, M.R.; Ghiron, C.A. Fluorescence quenching studies with proteins. Anal. Biochem. 1981, 114, 199-227. (32)Chi, Z.; Liu, R. Phenotypic characterization of the binding of tetracycline to human serum albumin. Biomacromolecules 2011, 12, 203-209.
511
(33)Chen, K.; Xu, Y.; Rana, S.; Miranda, O.R.; Dubin, P.L.; Rotello, V.M.; Sun,
512
L.; Guo, X. Electrostatic selectivity in protein-nanoparticle interactions.
513
Biomacromolecules 2011, 12, 2552-2561.
514
(34)Zuo, G.; Huang, Q.; Wei, G.; Zhou, R.; Fang, H. Plugging into proteins:
515
poisoning protein function by a hydrophobic nanoparticle. Acs Nano. 2010, 4,
516
7508-7514.
517
(35)Chatterjee, S.; Mukherjee, T.K. Spectroscopic investigation of interaction
518
between bovine serum albumin and amine-functionalized silicon quantum
519
dots. Phys. Chem. Chem. Phys. 2014, 16, 8400-8408.
ACS Paragon Plus Environment
Page 24 of 34
Page 25 of 34
Journal of Agricultural and Food Chemistry
520
(36)Sun, W.; Du, Y.; Chen, J.; Kou, J.; Yu, B. Interaction between titanium
521
dioxide nanoparticles and human serum albumin revealed by fluorescence
522
spectroscopy in the absence of photoactivation. J. Lumin. 2009, 129, 778-783.
523
(37)Hartvig, R.A.; Weert, M.V.D.; Østergaard, J.; Jorgensen, L.; Jensen, H.
524
Protein adsorption at charged surfaces: the role of electrostatic interactions
525
and interfacial charge regulation. Langmuir. 2011, 27, 2634-2643.
526
(38)Marangon, M.; Van Sluyter, S.C.; Haynes, P.A.; Waters, E.J. Grape and wine
527
proteins: their fractionation by hydrophobic interaction chromatography and
528
identification by chromatographic and proteomic analysis. J. Agric. Food
529
Chem. 2009, 57, 4415-4425.
530
(39)Bhattacharya, A.; Das, S.; Mukherjee, T.K. Insights into the thermodynamics
531
of polymer nanodot–human serum albumin association: a spectroscopic and
532
calorimetric approach. Langmuir. 2016, 32, 12067-12077.
533
(40)Zhang, G.; Wang, L.; Pan, J. Probing the binding of the flavonoid diosmetin
534
to human serum albumin by multispectroscopic techniques. J. Agric. Food
535
Chem. 2012, 60, 2721-2729.
536
(41)Huang, S.; Qiu, H.; Lu, S.; Zhu, F.; Xiao, Q. Study on the molecular
537
interaction of graphene quantum dots with human serum albumin: combined
538
spectroscopic and electrochemical approaches. J. Hazard. Mater. 2015, 285,
539
18-26.
540 541
(42)Wei, X.L.; Ge, Z.Q. Effect of graphene oxide on conformation and activity of catalase. Carbon 2013, 60, 401-409.
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
542 543 544
545
Figure captions
546
Figure 1. (a) Schematic illustration of fluorescent NPs derived from roasted chicken
547
breasts. (b) Photograph of the roasted and raw chicken breasts and (c) the NP aqueous
548
solution (left) and water extract (right) of raw chicken breasts under the UV light. (d)
549
TEM image (inset: HR-TEM image, scale bar = 10 nm), (e) corresponding particle
550
size histogram, and (f) XRD pattern of NPs derived from the roasted chicken breasts.
551
Figure 2. (a) FT-IR spectra of raw chicken breast powder (RCBP) and NPs extracted
552
from the roasted chicken breasts, (b) XPS spectrum, and (c) high resolution C1s
553
spectrum of NPs (d) high resolution N1s spectrum of NPs.
554
Figure 3. (a) UV-vis absorption and fluorescence (FL) spectra and (b) fluorescence
555
decay curve of NPs. Effect of metal ions (c) and pH (d) on the fluorescence intensity
556
of the NPs.
557
Figure 4. (a) Fluorescence emission spectra of HSA in the different concentrations of
558
NPs and inserts were the photograph of the HSA and NPs aqueous solution. c (HSA)
559
= 2 × 10 -6 mol L-1, c (NPs), a-h: 0, 0.5, 1, 1.5, 2, 2.5, 3, 4 × 10-4 mol L-1, pH 7.40. (b)
560
Stern-Volmer plots of HSA fluorescence quenched by NPs at 298K. (c) UV-vis
561
absorption spectra of HSA, NPs, HSA-NPs system, and difference of the absorption
562
spectrum between HSA-NPs system and NPs. c (HSA) = 2 × 10-6 mol L-1; c (NPs) = 2
ACS Paragon Plus Environment
Page 26 of 34
Page 27 of 34
Journal of Agricultural and Food Chemistry
563
× 10-4 mol L-1. (d) Fluorescence decay traces of HSA and HSA-NPs system. τ is
564
fluorescence lifetime of HSA and b is pre-exponential factor, respectively. c (HSA) =
565
2 × 10-6 mol L-1; c (NPs) = 2 × 10-4 mol L-1. (e) Heat flow as a function of time per
566
injection of the NPs in the presence of HSA at 298 K measured by ITC technique. (f)
567
Shows the heat evolved against the molar ratio of (NPs: HSA) at 298 K (black dots).
568
The solid line is the fitted curve.
569
Figure 5. Effect of site marker (a) warfarin and (b) ibuprofen on the fluorescence
570
intensity of the HSA-NPs system (T = 298 K, λex = 280 nm). 1-6: molar ratio of
571
[HAS]/[NPs]=0, 0.5, 1, 1.5, 2 and 2.5, respectively. (c) Modified Stern-Volmer plots
572
for the HSA-NPs system in the absence and presence of warfarin and ibuprofen.
573
c(HSA) = c(warfarin) = c(ibuprofen) = 2 × 10-6 mol L-1; c(NPs)/(104 mol L-1). (d)
574
scheme of identification of binding sites of NPs on HAS. (e) FT-IR spectra of HSA
575
and HSA-NPs system. c (HSA) = 2 × 10-6 mol L-1; c (NPs) = 2 × 10-4 mol L-1. (f) CD
576
spectra of HSA in the presence of NPs at different concentrations of 0, 0.2, 0.4, 1.0,
577
2.0 × 10-4 mol L-1 (curves from 1 to 5); c (HSA) = 2 × 10-6 mol L-1; T= 298 K; pH =
578
7.4.
579 580
Table 1. Thermodynamic parameters for the interaction of CNPs with HSA. Kd (×10-4 L
∆G0 (kJ
∆S0 (J mol-1
mol-1)
mol-1)
K-1)
-3.50 ± 0.33
-22.20
62.71
n
T (K) mol) 298
∆H0 (kJ
1.29 ± 0.52
1.47 ± 0.11
ACS Paragon Plus Environment
Journal of Agricultural and Food Chemistry
581 582 583 584
Table 2. ɑ-helix and β-sheet contents of HSA with the addition of different
585
concentrations of NPs. Molar ratio [NPs]:[HSA]
ɑ-helix content (%)
0:1
54.7
10:1
54.2
20:1
53.7
50:1
52.8
100:1
50.7
586
ACS Paragon Plus Environment
Page 28 of 34
Page 29 of 34
Journal of Agricultural and Food Chemistry
a
Roasting Fluorescent NPs
b
c
Raw and roasted chicken breast
d 10 nm
20 nm
f
10 5 0 1.0
587 588
2θ =22.6° ° d=0.39 nm
15
Intensity (a.u.)
Percentage (%)
e
1.5
2.0 Size (nm)
2.5
3.0
10
20
30 40 50 60 2 Theta degree
Figure 1.
589 590 591 592 593 594 595 596 597
ACS Paragon Plus Environment
70
80
Journal of Agricultural and Food Chemistry
a
b
O1s
O-H 3302
C-H 2927
NPs
C-H 2925
O-H 3411
C-N 1391 C=C N-H 1660 1538
C=C or CONH 1652
C-O-C C-N 1109 1400
3500 3000 2500 2000 1500 1000 500 -1 Wavenumber (cm )
Intensity (a.u.)
C=C 284.4 C-O-C/C=N 285.9 O-C=O 288.1
280
284
288
Intensity (a.u.)
C1s
292
N1s
0
200
d Intensity (a.u.)
Transmittance (a.u.)
RCBP
c
400 600 800 Binding Energy (e.V)
1000
Amines and amides 399.9 Pyridinic N 398.9
396
398
H-bonded or Protonated amine 400.5
400
402
Binding Energy (e.V)
Binding Energy (e.V)
598 599
Page 30 of 34
Figure 2.
600 601 602 603 604 605 606 607 608 609 610 611
ACS Paragon Plus Environment
404
Journal of Agricultural and Food Chemistry
Absorbance (a.u.) Absorption (a.u.)
Ex
b
300 310 320 330 340 350 360 370 380 390 400 410 420
Intensity (a.u.)
aa
FL Intensity (a.u.)
Page 31 of 34
0
200 250 300 350 400 450 500 550 600
20
Wavelength (nm)
0.8 0.6 0.4 0.2
80
0.8 0.6 0.4 0.2 0.0
--
Bl ac Zn k (I I C ) a( II M ) g( I M I) n( II C ) o( II N ) i(I I Fe ) (I C I) u( I Fe I) (I II )
0.0
612 613
60
d1.0
1.0
FL Intensity (a.u.)
FL Intensity (a.u.)
cc
40 Time (ns)
2
3
4
Ion species
Figure 3.
614 615 616 617 618 619 620 621 622 623 624
ACS Paragon Plus Environment
5
6
7
pH
8
9
10 11
Journal of Agricultural and Food Chemistry
a
b 0.8
338 nm
298K
(a) FL Intensity (a.u.)
Page 32 of 34
R2=0.998
F0/F-1
0.6
(h) 343 nm
0.4 0.2 4
F0/F-1 =-0.014+1.68×10 [NPs] 0.0
300
350
400
0
450
10
c b
1.0
a
d 1.0
a HSA b NPs c [HSA-NPs] d [HSA-NPs]-[NPs]
Absorbance (a.u.)
Absorbance (a.u.)
1.5
b
c a
d
0.5
d
220
240
260
280
300
Wavelength (nm)
240
t 2 (ns) (b2) (ns)
2.39 (35.37) 6.30 (64.63) 4.91
HSA-NPs 2.17 (42.63) 5.09 (52.99) 4.50
0.6 0.4 0.2
HSA HSA-NPs
270
300
330
360
390
420
0
10
20
30
40
50
60
70
Time (ns)
Wavelength (nm)
e
f
1.6
HSA+NPs Buffer+NPs
1.2 0.8 0.4 0.0 0
800
1600
2400
3200
0.0
Normalized Fit (kJ/mol)
Corrected Heat Rate (µJ/s)
HSA
0.0 210
626
40 -1
Substance t 1 (ns) (b1)
0.8
0.0
625
30
10 [CNPs] (mol L )
Normalized counts
c
20 6
Wavelength (nm)
-0.9 -1.8 -2.7 -3.6 0.0
4000
Time (sec)
0.9 1.8 2.7 Mole Ratio of [NPs]/[HSA]
Figure 4.
627 628 629 630 631 632 633
ACS Paragon Plus Environment
3.6
Page 33 of 34
Journal of Agricultural and Food Chemistry
a
b
(1)
HSA only (1)
FL intensity (a.u.)
FL intensity (a.u.)
HSA only Warfarin+HSA
(6)
(6)
Warfarin only
300
Ibuprofen only
360
420
300
480
360
F0/(F0-F)
d
Blank Warfarin Ibuprofen
20
420
480
Wavelength (nm)
Wavelength (nm)
c
Ibuprofen+HSA
=Ibuprofen
=Warfarin
15
NPs
10 5
HSA 0.5
1.0
1.5
HSA
2.0
-5
10 [CNPs]-1 (mol L-1)
f-25
1646
-30 HSA
CD (mdeg)
Absorbance (a.u.)
e
1548 1642 C=O
HSA-NPs 1542
-35 -40
1581
-45
1
C-N / N-H
1500
634 635
5
1560
1620
1680
1740
-50 205
210
215
220
Wavelength (nm)
-1 )
Wavenumbers (cm
Figure 5.
636 637 638 639 640 641
ACS Paragon Plus Environment
225
230
Journal of Agricultural and Food Chemistry
642 643
TOC Roasting
Roasted Chickenq
Chicken
=Warfarin
Purification
NPs water
=Ibuprofen
10 nm
NPs
644
HSA
Fluorescent nanoparticles (NPs)
HSA
20 nm
ACS Paragon Plus Environment
Page 34 of 34