2.1.

ICG Structure and Optical Properties

The structures of ICG and the tetraoctylammonium chloride (TOAC) and tetradodecylammonium chloride (TDDAC) molecules are shown in Figs. 1(a)–1(c). ICG possesses an amphiphilic structure with aromatic groups, a conjugated backbone, and charged sulfonate groups. Its overall charge is $-1$. Thus, it complexes with the cationic ammonium salts TOAC and TDDAC, which are known as “phase transfer catalysts” with strong interfacial activity.⁴⁰ We use these compounds instead of the more commonly used butyl variant (${\mathrm{C}}_4$) due to their greater hydrophobicity, which we anticipate would increase NC stability against ICG ion exchange. ICG has a broad excitation spectrum [Fig. 1(d)] with emission at 810 to 830 nm depending on the ICG concentration, solvent, and NC encapsulation. An excitation wavelength of 772 nm was used for all experiments. These wavelengths fall into the optical imaging window where maximum optical penetration is possible.

The basic optical properties of free ICG in solution and encapsulated in NC form are shown in Table 1 and Figs. 1(e) and 1(f). The generally accepted QY for free ICG is 1.3%.^11,24 Relative FL measurements with one of our ICG-containing NC systems approximate the apparent QY for the NCs as 0.44%. Figure 1(e) shows that ICG encapsulated with NC systems exhibits lower absorbance values and red-shifting relative to free ICG. This, combined with the lower FL values and redshifting in the FL spectrum in Fig. 1(f), indicates that the formation of ICG molecular aggregates in the NC core. Aggregate formation is a key mechanism of FL quenching.^41,42

Table 1

Optical properties of free ICG and ICG in NCs.

2.2.

NC Formation and Maximizing ICG NC Intrinsic Fluorescence

The key platform underlying NC fabrication is flash nanoprecipitation (FNP), as described by Johnson and Prud’homme.⁴³ The process enables coencapsulation of a variety of drugs,^4,5,44 pesticides,⁴⁵ organic imaging agents,^9,46 nanocrystals,⁴⁷ and metal clusters. In the process, hydrophobic species and an amphiphilic block copolymer in a water-miscible organic stream [often tetrahydrofuran (THF)] are rapidly mixed against an antisolvent stream (usually water). The key to the process is the specially designed micromixing cavities that create supersaturations as high as 10,000 in 1.5 ms.⁵ NCs were formed by making hydrophobic ICG:cationic counter-ion complexes in two ways to form ICG NCs: one consists of preforming the hydrophobic ICG-ammonium salt complex (“premade complex”) then forming NCs and the second consists of forming the ICG-cationic salt hydrophobic complex in situ during nanoprecipitation (“in situ”). The process conditions for each formulation are presented in Sec. 4. Zeta potentials were measured for the NC systems created (shown in Table 2) and were found to range between $-1$ and 0 mV as expected due to the charge screening effects of the PEG shell around each NC.⁴⁸

Table 2

Zeta potential of ICG NCs.

A hydrophobic excipient such as vitamin E (VE) or polystyrene (PS) is often used in the NC formulation to improve the capture and stability of the active ingredient, ICG complex in this case, and to define the NC size. In addition, as explained previously,⁴⁶ the hydrophobic excipients uniformly distribute the dyes within NC cores and reduce quenching. Although increasing the number of dye molecules per NC initially increases the FL per NC, ICG molecular aggregation^24,49 and the rate of Förster resonant energy transfer^46,50,51 increase, causing FL quenching, which results in a decrease in FL per NC (intrinsic FL). Thus, there is an optimum in the NC dye core loading to achieve the maximum FL per NC. As seen in Fig. 2, the ICG complex core loading, which gives the maximum FL for the in situ formed ICG-TOAC ($\mathrm{ICG}\text{-}{\mathrm{C}}_8$) system, is 10 wt. %. The calculation procedure for estimating the number concentration of NCs is given in Ref. 46. The core loading of the ICG complex is defined as

Fig. 2

FL per NC versus ICG complex core loading. The maximum in FL per NC (highest intrinsic FL) for 100 nm NCs was found at $\sim 10\mathrm{wt.}\%$ ICG complex core loading. Subsequent $\mathrm{ICG}\text{-}{\mathrm{C}}_8$ complex NCs were formulated with this optimal loading. A measure of the error is provided at the data point at 0.61 wt. %: $2.54\times {10}^{-14}\pm 2.33\times {10}^{-15}\mathrm{AU}$.

2.3.

ICG NC Loading Limits

While studying $\mathrm{ICG}\text{-}{\mathrm{C}}_8$ complex NC stability with either VE or PS cores, we observed that, at high ICG complex loadings, a glitter-like precipitate formed in the solutions several hours after NC formation. The precipitates were not NC flocculated particles, but rather an ICG crystal phase. The precipitates could be filtered out with a $5\text{-}\mu \mathrm{m}$ filter, and the resulting filtrate contained a single NC population. By measuring the size change and ICG concentration change by absorbance, we determined that each type of NC core had a certain loading threshold above which ICG complex precipitates would form and below which no precipitates would form and NCs would be stable for weeks to months (see Fig. 3).

Fig. 3

NC size change following precipitation of $\mathrm{ICG}\text{-}{\mathrm{C}}_8$ with different core materials and corresponding changes in ICG complex core loading shown at the abscissa: (a) PS core, (b) no cosolute, (c) VE core (solid bars, preprecipitation; striped bars, postprecipitation). The maximum stable loading levels are dependent on the core material.

In the case of PS cores, NCs loaded with 4.1% and 8.7% core loading $\mathrm{ICG}\text{-}{\mathrm{C}}_8$ complex were stable, but those loaded at 38% dropped to a final loading of 9.8% within a few hours. In the case of VE cores, NCs loaded at 32.9%, 58.9%, and 77.7% all dropped to final effective loadings of 31.6%, 30.5%, and 27.8%, respectively. Further formulations with VE below this threshold were all stable (no precipitate formed). In the case of the ICG complex loaded into PS-b-PEG micelles (no cosolute), NCs loaded at 78% dropped to a final loading of about 42%. These measurements indicate that the ICG complex is less compatible with PS than with VE. Since 10 wt. % ICG complex core loading maximizes FL, and since we had experience with VE as a coexcipient for therapeutics in the NC core, we studied only VE core NCs for subsequent experiments. VE core NCs stabilized by PS-b-PEG were found to be size-stable for more than 6 months (data not shown) as long as the ICG loading was below the limits shown in Fig. 3.

2.4.

Size Control and Fluorescence Scaling of ICG NCs

Since NC size is an important design parameter, we demonstrate that these ICG NCs could be produced at different sizes at a constant ICG complex loading (the optimal FL loading determined earlier). The NC size produced by FNP primarily depends on the solution concentration.⁴⁶ We held the ratio of all components constant and varied the total solids from 1 to $100\mathrm{mg}/\mathrm{mL}$ in the feed stream. The size distributions [shown in Fig. 4(a)] become slightly broader at larger sizes, in accordance with mechanism of growth in FNP.⁵² The NC size scales linearly with the total solids concentration up until $70\mathrm{mg}/\mathrm{mL}$, at which point the size plateaus at $\sim 180\mathrm{nm}$ [Fig. 4(b)].

Fig. 4

(a) Size distributions for ICG-TOAC ($\mathrm{ICG}\text{-}{\mathrm{C}}_8$) in situ formed NCs (▪ $1\mathrm{mg}/\mathrm{mL}$, • $10\mathrm{mg}/\mathrm{mL}$, ▴ $40\mathrm{mg}/\mathrm{mL}$, ▾ $70\mathrm{mg}/\mathrm{mL}$, ◂ $100\mathrm{mg}/\mathrm{mL}$), (b) NC sizes versus total solids concentration. (c) FL intensity per NC versus core diameter. The FL per NC (intrinsic NC FL) scales linearly with the core diameter to the third power.

The per-particle FL [Fig. 4(c)] scales linearly with the core volume, i.e., the core diameter to the third power: $\frac{\mathrm{FL}}{\mathrm{NP}}=(5.01\times {10}^{-14})(D^{2.98})$, $R^2=0.98$. This shows that the ICG is encapsulated uniformly in the core of the NCs and not just at the core–shell interface, which would have a $D^2$ scaling. As a result, larger particles are more fluorescent at constant dye loading. We hypothesize that previous studies that loaded ICG into preformed NCs through the aqueous phase would produce NCs with ICG at the NC interface. However, in those studies FL versus size was not reported, so the localization of the dye via these other assembly processes cannot be confirmed.

2.5.

Encapsulation Efficiency and Ion Pairing

Previously, we had successfully created NCs by forming hydrophobic ion pairs of therapeutic drugs using the in situ complexation of anionic and cationic compounds when one was solubilized in the aqueous phase and one in the organic phase.^53,54 To test the ability to make ICG NCs by a similar ion pairing, the ratio of TOAC to ICG was varied and the degree of ICG encapsulation [Fig. 5(b)] was measured with UV–VIS absorbance. The sizes of the NCs were held constant [Fig. 5(a)] except for the micelle sample, which had no VE and no TOAC. However, the ICG core loading was not kept constant across samples. Since the $\mathrm{TOAC}:\mathrm{ICG}$ ratio was varied, and in some cases no TOAC was used, the ICG core loading [Eq. (2)] was kept in a range from 2.5% to 25%. For reference, an ICG complex core loading at the optimal 10 wt. % (with $1:1$ $\mathrm{ICG}:\mathrm{TOAC}$) is equivalent to an ICG core loading at 6.5 wt. %. These data are tabulated in Table 3.

Fig. 5

ICG encapsulation efficiencies as a function of TOAC:ICG ratio (in situ complex formation): (a) size distributions of particles (▪ micelles (0 TOAC, 0 VE),• 0 TOAC, ▴ $1:10$ $\mathrm{TOAC}:\mathrm{ICG}$, ▾ $1:2$ $\mathrm{TOAC}:\mathrm{ICG}$, ◂ $1:1$ $\mathrm{TOAC}:\mathrm{ICG}$, ▸ $2:1$ $\mathrm{TOAC}:\mathrm{ICG}$, ♦ $10:1$ $\mathrm{TOAC}:\mathrm{ICG}$) and (b) the ratio of TOAC to ICG was varied from 0 to $10:1$ for in situ ICG NC precipitation. The number of TOAC equivalents relative to ICG is labeled on the abscissa.

Table 3

ICG encapsulation efficiency, ICG core loading and equivalent complex core loading, and NC diameters for the encapsulation efficiency study in Fig. 6, where the ICG:TOAC ratio was varied. The VE concentration was held constant at 8.9  mg/mL in the THF stream except for the micelle case (0TOAC, 0VE) where no VE was used. VE constituted 40% to 48% of the total NC mass.

For a $1:1$ or higher ratio of $\mathrm{TOAC}:\mathrm{ICG}$, the cationic counter-ion drives essentially complete encapsulation of the ICG into the NC core. However, at only 10 wt. % or less ICG complex core loading, the preponderance of hydrophobic VE and PS-chains in the core still substantially captures the ICG during rapid precipitation. The $0:10$, $1:10$, and $1:2$ ratios of $\mathrm{TOAC}:\mathrm{ICG}$ yield 94%, 89%, and 97% ICG encapsulation, respectively. PS-b-PEG and ICG (no TOAC and no VE) gave encapsulation at 97% in the 25-nm micelle NCs. DeVoiselle et al.²⁶ investigated the complexation of ICG in the presence of various surfactants using tensiometric and FL measurements and found that amphiphilic ICG assembles at interfaces. Kircherr et al. studied the encapsulation of ICG monosodium salt within nonionic surfactant micelles and achieved 90% to 95% loading efficiency but only 61% within Pluronic F68 micelles due to its higher hydrophilicity.²⁸ Similarly, Kim et al.²⁷ achieved encapsulation efficiencies of 39% to 79% for hydrophobic ICG-tetrabutylammonium salts in Pluronic F127. Rodriguez et al.²⁹ formed hydrophobic salts of ICG with tetrabutylammonium iodide (TBA) within poly(styrene)-b-poly(styrene-alt-maleic anhydride) micelles and achieved 87% encapsulation efficiency. The rapid precipitation by FNP yielded higher ICG encapsulation efficiencies than any of the previously reported loading techniques. Since the previous techniques involved introducing the ICG from or through the aqueous phase, the lack of uniform encapsulation into the core may be the reason. The previous studies could not vary NC size, as we can with FNP, so no comparison of FL intensity with size or loading efficiency is possible.

We calculated the available interfacial surface area available for ICG adsorption in the case of the polymeric micelles, which from Fig. 5(a) is 25 nm in diameter. Based on the projected surface area of an ICG molecule $\sim 0.15{\mathrm{nm}}^2$ and molecular volume of $5.8\times {10}^{-2}{\mathrm{nm}}^3$ (calculated with ChemAxon MarvinSketch v6.2.2 Geometry Plugin),⁵⁵ a micelle could accommodate $13\times {10}^3$ ICG molecules on its surface and $141\times {10}^3$ ICG molecules in the core. Since the ICG loading in the micelle core is $\sim 25\mathrm{wt.}\%$, the core would contain $\sim 35\times {10}^3$ ICG molecules. Therefore, we would expect ICG to be loaded both in the core and at the interface, which might be the reason for the very efficient loading of the micelles, even in the absence of the TOAC counter ion. The surface loading would become less significant for larger NCs.

2.6.

ICG NC–BSA Stability

It is important that the dye remain trapped in the NC core, so the NCs can be effectively tracked without fluorescent signal being confounded with free dye or dye bound to proteins. Kim et al.²⁷ reported Pluronic F127 micelles loaded with ICG-TBA salt ($\mathrm{ICG}\text{-}{\mathrm{C}}_4$) and incubated with 50% serum. A threefold increase in FL was seen due to the partitioning of ICG from the micelles. However, we have previously demonstrated that the relatively low CMC of these PPO-PEO copolymers comprising Pluronic F127 enables them to serve as “molecular shuttles” of hydrophobic components in the cores of NCs.⁵ The block copolymers used in FNP are chosen to have hydrophobic blocks large enough to not partition off the NC surface; they are kinetically frozen. ICG is known to bind strongly to serum proteins, in particular, albumin, globulins, and α-lipoproteins.^24,56–59 As noted above, Rodriguez et al. tested the release of ICG-tetrabutylammonium complex ($\mathrm{ICG}\text{-}{\mathrm{C}}_4$) from NCs only in DI water. This does not address the stability of ICG in NCs in vivo because in vivo ion exchange of the $\mathrm{ICG}\text{-}{\mathrm{C}}_4$ and partitioning to serum proteins can occur, as seen by Kim. Zerda et al.⁵³ created carbon nanotube-ICG constructs where ICG molecules were attached to carbon nanotubes simply by $\pi -\pi$ hydrophobic interactions. They tested the stability of these complexes by incubation in 10% serum/90% PBS for 24 h, which gives an albumin concentration of only 0.4 wt. %, 10 times lower than physiological levels. Even under these mild conditions, optical absorbance increased by 25%, which indicates the partitioning to BSA. Our objective was to determine if the ICG:counterion complex trapped in NC cores was stable in the presence of physiological levels of serum protein (albumin) and if the more hydrophobic octylammonium (${\mathrm{C}}_8$) and dodecylammonium (${\mathrm{C}}_{12}$) counter-ions might prevent ion exchange and make the NC less susceptible to partitioning to serum proteins.

NCs formed from ICG and tetrabutylammonium (${\mathrm{C}}_4$) in situ, tetraoctylammonium (${\mathrm{C}}_8$) in situ and premade, and tetradodecylammonium (${\mathrm{C}}_{12}$) in situ complexes were incubated at room temperature with 4 wt. % BSA in 5 mM phosphate buffer at pH 7.0, and the change in FL was measured over a period of $\sim 2\mathrm{h}$. The change in total system FL demonstrates ion exchange of ICG from the NC core to albumin, even when protected in the hydrophobic NC core.

The intrinsic FL of ICG in buffer and the FL of ICG in serum protein were first measured, and the data are shown in Fig. 6(a). The intrinsic FL, as defined by the slope of FL versus [ICG], is $\sim 1.6\times$ higher for ICG bound to protein than for ICG in buffer, which is consistent with the data in Fig. 1(f) (the correlation fits are shown in Fig. 6). Similarly, the intrinsic FL slopes of the various ICG NC systems were measured, and representative data for $\mathrm{ICG}\text{-}{\mathrm{C}}_8$ in situ are shown in Fig. 6(b). NC intrinsic FL was found to be 1 to 2 orders of magnitude lower than that for free ICG in buffer. The increase in FL upon ICG binding to BSA is due to a combination of (1) molecular disaggregation and stabilization of the monomeric ICG on the BSA,^41,42 (2) reduction of FRET within each NC core,^46,51 and (3) “rigidization” of the bound ICG, which reduces dissipative degrees of freedom such as molecular vibration and rotation, resulting in an increase in optical emission.^41,42 The relative impacts of these effects on observed FL can be estimated from Fig. 1(f), which shows a $1.6\times$ increase in FL for free ICG binding to albumin due to an increase in QY. Philip et al.⁴¹ have reported a FL QY increase from 2.7% to 4.0% for ICG bound to albumin, confirming this measurement. Furthermore, FL is reduced by a factor of $2.8\times$ by complexing and encapsulating free ICG within NC cores, due to a combination of aggregation and FRET-induced quenching. The strong tendency of ICG to form stable, self-quenching aggregates at low concentrations suggests that aggregation would have a larger impact on FL than FRET.^24,41,60

Fig. 6

(a) FL transfer experiments showing the increase in intrinsic ICG FL (slope) upon the addition of BSA to ICG dissolved in 5 mM phosphate buffer. For pure ICG, the regression fit is: $\mathrm{FL}=1.37\times {10}^7[\mathrm{ICG}(\mathrm{mg}/\mathrm{mL})]$, $R^2=0.996$, for ICG + BSA: $\mathrm{FL}=2.36\times {10}^7[\mathrm{ICG}(\mathrm{mg}/\mathrm{mL})]$, $R^2=0.991$. (b) Intrinsic FL of $\mathrm{ICG}\text{-}{\mathrm{C}}_8$ in situ, which is an order of magnitude lower than the intrinsic FL of free ICG solution and ICG + BSA solution. $\mathrm{ICG}\text{-}{\mathrm{C}}_8$ complex loaded at 10 wt. % core loading.

Experiments with the various NC formulations show the increase in FL as the ICG-ion pairs exchange from the NCs onto BSA in solution at 4 wt. %, which is at the physiological protein concentration.⁶¹ In the time course FL measurements, shown in Fig. 7, the $\mathrm{ICG}\text{-}{\mathrm{C}}_4$ in situ formulation displays the largest ($\sim 800\%$) rise in FL due to a large amount of ICG dye ion exchanging and partitioning out of the NC core and binding to the albumin. Both the ${\mathrm{C}}_8$ in situ and premade formulations display a relatively small change in FL, indicating a small amount partitions out since it is more hydrophobic than the ${\mathrm{C}}_4$ formulation. Studies with free ICG incubated with 4 wt. % BSA showed that the FL went immediately to the value shown in Fig. 1(f) and stayed there over the course of 120 min. Surprisingly, the ${\mathrm{C}}_{12}$ counter-ion does not confer the best ICG stability, having a FL change intermediate between the ${\mathrm{C}}_4$ and ${\mathrm{C}}_8$ counter-ions. This is likely due to (1) the ${\mathrm{C}}_{12}$ counter-ion micellizing more readily than the ${\mathrm{C}}_8$, thus providing a “molecular shuttling” effect that transfers additional ICG to the BSA. This effect has been observed in similar NC systems previously.⁵ A secondary effect may arise from specific favorable interactions between the ${\mathrm{C}}_{12}$ counter-ion and residues in the BSA.

Fig. 7

Percent FL change of various ICG NC formulations in the presence of 5 mM phosphate and 4 wt. % ($40\mathrm{mg}/\mathrm{mL}$) BSA. [▪ ${\mathrm{C}}_4$ in situ complex, • ${\mathrm{C}}_8$ in situ complex, ▾ ${\mathrm{C}}_8$ premade complex (two replicates shown), ▴ ${\mathrm{C}}_{12}$ in situ complex (two replicates shown)]. The ${\mathrm{C}}_4$ complex showed the greatest change in FL indicating the greatest amount of ICG exchanged away, as expected, while the ${\mathrm{C}}_8$ counter-ion provided the best protection.

By combining the data in Figs. 6 and 7, an estimate of the fraction of ICG transferred from NCs to BSA can be obtained

Table 4

Summary of ICG NC–BSA stability data.

Table 4 summarizes the ICG NC–BSA stability data. There is a positive correlation between the change in FL and the fraction of ICG transferred from NC to BSA. We see that the ${\mathrm{C}}_4$ counter-ion formulation provides little stability to the ICG, with $\sim 62\%$ of the ICG transferring to BSA, in agreement with the large FL rise in Fig. 7. The ${\mathrm{C}}_8$ complex formed either in situ or premade provides the best stability, with only 3% to 4% of the ICG transferred away. The ${\mathrm{C}}_{12}$ complex formed in situ has lower stability than the ${\mathrm{C}}_8$ complex but is significantly more stable than the ${\mathrm{C}}_4$. When ICG partitions from NC cores to BSA, there is a rise in the intrinsic FL slope (Fig. 6) that can be 1 to 2 orders of magnitude higher. Thus, even a small amount of BSA-bound ICG can lead to a large change in FL signal. While the $\mathrm{ICG}\text{-}{\mathrm{C}}_8$ and $\text{-}{\mathrm{C}}_{12}$ NC formulations are stable in phosphate buffer, when given the sink of the BSA protein, ICG is rapidly exchanged away from the NC. Clearly, this would be problematic for quantification in in vivo studies.

Finally, we sought to verify that 4 wt. % ($40\mathrm{mg}/\mathrm{mL}$) BSA, which is the physiological albumin concentration,⁶¹ was in sufficient excess to represent a true sink for the ICG. In these experiments, the $\mathrm{BSA}:\mathrm{ICG}$ molar ratio was $\sim 10:1$, but, if an ICG NC suspension is injected into a mouse (blood volume 1.5 mL) or human (blood volume 5 L), the total molar ratio of BSA to ICG would be much higher, which can result in ICG being continuously drawn out from NC cores. Therefore, we incubated the most stable NC formulation tested ($\mathrm{ICG}\text{-}{\mathrm{C}}_8$ in situ complex) with 4, 6, and 8 wt. % BSA and measured the FL time course over $\sim 2\mathrm{h}$. The results are shown in Fig. 8, where we see a dependence of the final FL plateau on the BSA concentration. With a greater external sink of BSA, the amount of ICG exchanged from the NC is greater.

Fig. 8

Average FL plateau height versus wt. % BSA in solution for $\mathrm{ICG}\text{-}{\mathrm{C}}_8$ in situ formed NCs, which was the most stable formulation tested. A linear dependence is apparent with $s\text{lope}=23.3$, $\text{intercept}=345$. This shows that the ICG partitions out of the NC core to an extent dependent on the size of the external BSA sink.

4.1.

Materials

Two forms of ICG were used: Cardiogreen, which contains NaI, was obtained from Sigma-Aldrich (I2633) and an iodine-free ICG was obtained from Persis Science LLC in Princeton, New Jersey. The cationic complexation agents TBA (86890), tetrabutylammonium chloride (86870), TOAC (87991), and TDDAC (87250) were obtained from Sigma-Aldrich and used without modification. Hydroxyl terminated poly(styrene) and poly(styrene)-b-poly(ethylene glycol) (1.5k-b-5k) were synthesized as previously described.⁶² Poly(styrene)-b-poly(ethylene glycol) (1.6k-b-5k) was obtained from Polymer Source (P13141-SEO, Polymer Source, Montreal, Canada). High-pressure liquid chromatography (HPLC) grade THF and diethyl ether (DEE) were obtained from Fisher Scientific (T425-4 and AC615080010, respectively, Fisher Scientific), and ultrapure water was obtained from a Barnstead NanoPure system delivering $>17.8\mathrm{M}\mathrm{\Omega }\text{-}\mathrm{cm}$ (hereafter referred to as “Milli-Q water”).

4.2.

Methods