Fluorescent nanoparticles produced in our lab are used for imaging ion concentrations and ion fluxes in biological systems such as cells during signaling and interstitial fluid during physiological homeostasis.
Tightly regulated ion homeostasis throughout the body is necessary for the prevention of such debilitating states as dehydration.1 In contrast, rapid ion fluxes at the cellular level are required for initiating action potentials in excitable cells.2 Sodium regulation plays an important role in both of these cases; however, no method currently exists for continuously monitoring sodium levels in vivo 3 and intracellular sodium probes 4 do not provide similar detailed results as calcium probes. In an effort to fill both of these voids, fluorescent nanosensors have been developed that can monitor sodium concentrations in vitro and in vivo.5,6 These sensors are based on ion-selective optode technology and consist of plasticized polymeric particles in which sodium specific recognition elements, pH-sensitive fluorophores, and additives are embedded.7-9 Mechanistically, the sodium recognition element extracts sodium into the sensor. 10 This extraction causes the pH-sensitive fluorophore to release a hydrogen ion to maintain charge neutrality within the sensor which causes a change in fluorescence. The sodium sensors are reversible and selective for sodium over potassium even at high intracellular concentrations.6 They are approximately 120 nm in diameter and are coated with polyethylene glycol to impart biocompatibility. Using microinjection techniques, the sensors can be delivered into the cytoplasm of cells where they have been shown to monitor the temporal and spatial sodium dynamics of beating cardiac myocytes.11 Additionally, they have also tracked real-time changes in sodium concentrations in vivo when injected subcutaneously into mice.3 Herein, we explain in detail and demonstrate the methodology for fabricating fluorescent sodium nanosensors and briefly demonstrate the biological applications our lab uses the nanosensors for: the microinjection of the sensors into cells; and the subcutaneous injection of the sensors into mice.
1. Preparation of optode
Before making the optode, aliquots of the components are need so that they can be easily measured and stored.
These aliquots and solutions will be used to make the optode material.
2. Creating nanosensors
3. Determining nanonsensor response
This method is used to determine the response of nanosensors designed to measure intracellular sodium. Different concentrations are recommended to be used for extracellular sodium concentration nanosensors.
Excitation (nm) | Emission (nm) | Cut-Off (nm) |
488 | 570 | 530 |
488 | 670 | 610 |
639 | 680 | 665 |
The nanosensor intensity at each wavelength is dependent on the sodium concentration. The use of the wavelength depends on the applications. For intracellular slow dynamics measurements, we use 488 nm/570 nm (excitation/emission) and 488 nm/670 nm which allow us to ratio the two wavelengths and reduce noise.
4. Intracellular imaging
5. In vivo imaging
All procedures have been reviewed and approved by Northeastern University’s Animal Care and Use Committee.
6. Representative Results
Figure 1. Response curves of five different nanosensor sets to sodium. Each set represents nanosensors from different optode formulations that had the same amount of CHIII, NaTFPB, PVC and DOS but varying amounts of NaIX . The data were converted to α values using the 639/680 nm intensities. Data are an average of 3, error bars omitted for clarity, with a fitted sigmoidal curve using Origin. In this response curve, the maximum concentration of sodium used was 500 mM. The Kd of the sodium nanosensors for sodium ranged from 10 mM (orange diamonds) to about 150 mM (black squares).
Figure 2. Injected neonatal cardiac myocytes. Cells were cultured on coverglass, mounted on a microscope and injected with sodium nanosensors. Shown are fluorescent (639 nm excitation), brightfield, and overlay. Note that some sensor clustering occurs but the cells have normal morphology, sensors have diffused throughout the cytosol and there is no nuclear loading.
Figure 3. Subcutaneous injection of mice with sodium nanosensors. Nine different injections of sodium nanosensors were made into the subcutaneous space of nude mice. Both bright field and fluorescent images (640/680) are overlaid.
The formation of nanosensors should take no longer than 10 minutes once the optode solution has been made and the PEG lipid dried. Optode can not only be made quickly when needed, but when stored at 4 degrees Celsius, they can be stable for months. We have shown that the nansensors, once formed, are stable in solution for at least a week; however, care must be taken to prevent photobleaching over this time by blocking the nanosensors from light.6 While sodium nanosensors were demonstrated here, optodes have been created for most biologically relevant ions such as potassium and chloride.10,12 We have also extended this technology to small molecules such as glucose.13
In addition to generating nanosensors to monitor different analytes, these nanosensors are amenable to other changes that will make them useful in most biological experiments. For example, the surface coating, in this case poly(ethylene glycol), can easily be changed using any amphiphilic molecule that is water soluble. This enables the possibility of functionalizing these nanoparticles for different applications or targets. The size of the nanoparticles can also be adjusted by altering the surface coating, the sonication intensity or the solvent used.
Calcium fluorescent indicators have been invaluable in determining intracellular calcium signaling; however, no available sodium sensitive dyes have the same ideal characteristics. Optode nanoparticles intended to provide an alternative method for imaging ions intracellularly have been in development for years.14 We have built upon this previous research to create nanosensors specific for intracellular sodium imaging that will hopefully provide a means to understand how sodium signaling affects cellular function and alterations in signaling which lead to certain diseases.
The use of fluorescent nanosensors in vivo offers a real-time minimally-invasive alternative for monitoring analytes over other methods such as blood draws.3 Sodium and glucose nanosensors based on the technology above have been shown to track changes in sodium and glucose, respectively in vivo.3,13 However, there currently exist limitations to this method as a monitoring tool. For example, the sensors must contain a fluorophore with a spectrum sufficiently shifted towards the near infrared red in order to minimize background autofluorescence from the skin.15 Second, the current injection technique does not produce uniform injection of the nanosensors which may be caused by such errors as variation in injection depth. Despite these limitations, the development of these fluorescent nanosensors and their successful demonstration could make these sensors an invaluable research tool and method for monitoring patient health.
The authors have nothing to disclose.
JMD and MKB are funded through the IGERT Nanomedicine Science and Technology program at Northeastern University (funding from NCI and NSF grant DGE- 0504331). This work was also funded by National Institutes of Health National Institute of General Medical Sciences Grant R01 GM084366. We also thank Saumya Das and Anthony Rosenzweig of BIDMC in Boston for providing cardiac myocytes and Kevin Cash for his contribution in the animal protocol development.
Product Name | Company | Catalogue Number | Comments |
---|---|---|---|
IVIS Lumina II Instrument Package | Caliper Life Sciences | 126273 | |
CD-1 Nude Mice | Charles River | Strain Code: 086 | Immunodeficient |
Insulin syringes | BD | 328438 | 3/10 ccmL , 8mm, 31G |
High Molecular Weight PVC | Sigma | ||
DOS | Sigma | ||
CHIII | Sigma | ||
NaTFPB | Sigma | ||
NaIX | Sigma | ||
Thin walled capillary glass | Sutter | ||
PEG lipid | Avanti Polar Lipids |
Table 1. Provides a list of chemicals and equipment used in this procedure. All common chemicals not listed were purchased from Sigma.