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Fluorescence imaging is a type of non-invasive imaging technique that can help visualize
biological processes Biological processes are those processes that are vital for an organism to live, and that shape its capacities for interacting with its environment. Biological processes are made of many chemical reactions or other events that are involved in the ...
taking place in a living organism. Images can be produced from a variety of methods including:
microscopy Microscopy is the technical field of using microscopes to view objects and areas of objects that cannot be seen with the naked eye (objects that are not within the resolution range of the normal eye). There are three well-known branches of micr ...
, imaging probes, and
spectroscopy Spectroscopy is the field of study that measures and interprets the electromagnetic spectra that result from the interaction between electromagnetic radiation and matter as a function of the wavelength or frequency of the radiation. Matter ...
.
Fluorescence Fluorescence is the emission of light by a substance that has absorbed light or other electromagnetic radiation. It is a form of luminescence. In most cases, the emitted light has a longer wavelength, and therefore a lower photon energy, tha ...
itself, is a form of
luminescence Luminescence is spontaneous emission of light by a substance not resulting from heat; or "cold light". It is thus a form of cold-body radiation. It can be caused by chemical reactions, electrical energy, subatomic motions or stress on a crys ...
that results from matter emitting light of a certain wavelength after absorbing
electromagnetic radiation In physics, electromagnetic radiation (EMR) consists of waves of the electromagnetic (EM) field, which propagate through space and carry momentum and electromagnetic radiant energy. It includes radio waves, microwaves, infrared, (visib ...
. Molecules that re-emit light upon absorption of light are called fluorophores. Fluorescence imaging photographs fluorescent dyes and fluorescent proteins to mark molecular mechanisms and structures. It allows one to experimentally observe the dynamics of
gene expression Gene expression is the process by which information from a gene is used in the synthesis of a functional gene product that enables it to produce end products, protein or non-coding RNA, and ultimately affect a phenotype, as the final effect. T ...
, protein expression, and molecular interactions in a living cell. It essentially serves as a precise, quantitative tool regarding biochemical applications. A common misconception, fluorescence differs from
bioluminescence Bioluminescence is the production and emission of light by living organisms. It is a form of chemiluminescence. Bioluminescence occurs widely in marine vertebrates and invertebrates, as well as in some fungi, microorganisms including some b ...
by how the proteins from each process produce light. Bioluminescence is a chemical process that involves enzymes breaking down a substrate to produce light. Fluorescence is the physical excitation of an electron, and subsequent return to emit light.


Attributes


Fluorescence mechanism

When a certain molecule absorbs light, the energy of the molecule is briefly raised to a higher excited state. The subsequent return to ground state results in emission of fluorescent light that can be detected and measured. The emitted light, resulting from the absorbed photon of energy ''hv'', has a specific wavelength. It is important to know this wavelength beforehand so that when an experiment is running, the measuring device knows what wavelength to be set at to detect light production. This wavelength is determined by the equation: \lambda_=\ \frac Where ''h'' = Planck's constant, and ''c'' = the speed of light. Typically a large scanning device or CCD is used here to measure the intensity and digitally photograph an image.


Fluorescent dyes versus proteins

Fluorescent dyes, with no maturation time, offer higher photo stability and brightness in comparison to fluorescent proteins. In terms of brightness, luminosity is dependent on the fluorophores’ extinction coefficient or ability to absorb light, and its quantum efficiency or effectiveness at transforming absorbed light into fluorescently emitting luminescence. The dyes themselves are not very fluorescent, but when they bind to proteins, they become more easily detectable. One example, NanoOrange, binds to the coating and hydrophobic regions of a protein while being immune to reducing agents. Regarding proteins, these molecules themselves will fluorescence when they absorb a specific incident light wavelength. One example of this, green fluorescent protein (GFP), fluoresces green when exposed to light in the blue to UV range. Fluorescent proteins are excellent reporter molecules that can aid in localizing proteins, observing protein binding, and quantifying gene expression.


Imaging range

Since some wavelengths of fluorescence are beyond the range of the human eye, charged-coupled devices (CCD) are used to accurately detect light and image the emission. This typically occurs in the 300 – 800 nm range. One of the advantages of fluorescent signaling is that intensity of emitted light behaves rather linearly in regards to the quantity of fluorescent molecules provided. This is obviously contingent that the absorbed light intensity and wavelength are constant. In terms of the actual image itself, it is usually in a 12-bit or 16-bit data format.


Imaging systems

The main components of fluorescence imaging systems are: * Excitation Source: a device that produces either a broad-wavelength source like UV light, or a narrow wavelength source like a laser. * Light display optics: the mechanism of which light illuminates the sample. This is typically done through direct illumination of the sample. * Light assortment optics: the collection method of the light itself. This typically constitutes lenses, mirrors, and filters. * Filtration of emitted light: optical filters ensure that reflected and scattered light are not included with the fluorescence. The three classes of emission filters are long-pass, short-pass, and band-pass. * Detection, amplification, and visualization: either photomultiplier (PMT) or charge-couple device (CCD) is used to detect and quantify emitted photons


Applications

* In PCR (agarose gel electrophoresis): SYBR Green is a very common dye that binds to DNA and is used to visualize DNA bands in an agarose gel. The dye absorbs blue light and fluoresces green for an imaging system to capture. * Blotting (Western, Northern, and Southern): fluorochromes can bind to antibodies, RNA, and DNA to fluoresce and quantify data * DNA Sequencing: Sanger Sequencing is a common form of nucleic acid detection that may use fluorescently labeled ddNTPs to image fluorescence peaks * Fluorescence image guided surgery: is a medical imaging approach that fluorescently labels a mass to aid in navigation. For example, indocyanine green can be used to detect lymph nodes in cancer patients. * Fluorescence imaging with one nanometer accuracy (FIONA): utilizes total internal reflection illumination to reduce noise and increase brightness of fluorophores *Calcium imaging: technique that utilizes fluorescent molecules called calcium indicators that change in fluorescence when bound to Ca2+ ions. This is a key part in seeing when cells are active in the nervous system.


Types of microscopy

A different array of microscope techniques can be employed to change the visualization and contrast of an image. Each method comes with pros and cons, but all utilize the same mechanism of fluorescence to observe a biological process. * Total internal reflection fluorescence microscopy: A microscopy technique that uses evanescent waves to selectively observe the fluorescence of a single molecule. * Light sheet fluorescence microscopy: A fluorescence microscopy technique that illuminates a thin slice of a sample at a perpendicular angle of examination. * Fluorescence-lifetime imaging microscopy: An imaging technique that records changes in fluorescence over time


Advantages

* Non-invasive: imaging ''in vivo'' can take place without having to puncture the skin * Sensitive: probes are designed to be extremely sensitive to detecting biological molecules like DNA, RNA, and proteins. * Multi-labeling: multiple fluorochromes can be detected within the samples allowing for an easy way to integrate standards and a control. * Stability of labeled molecules: fluorescently labeled molecules used in imaging can be stored for months while other molecules like ones that are radiolabeled, will decay over a few days. * Relatively safe to handle: most fluorophores can be safely and sufficiently handled with gloves, while for example, radioisotopes may require lead shields or other radiation protection. * Simple disposal: many fluorophores require minimal disposal methods while radioactive wastes require regulated disposal and long-term handling. This also aids in lowering the cost needed to utilize these products.


Disadvantages

* Photobleaching: A prevalent issue with fluorophores where the constant cycling between ground state and excited state damages the molecule and reduces its intensity. * Environmental susceptibility: environmental factors like temperature, ion concentration, and pH can affect the efficiency and emission of fluorochromes * Toxicity: Aome fluorochromes can be toxic to cells, to tissues, ''in vivo'', or by producing mutations. * Limited resolving power: Fluorescence microscopes are limited in their ability to distinguish close objects at the macroscopic level. In comparison, electron microscopes for example, have the capacity to resolve at a much smaller range. * Limited initial luminosity range: the incidence light source intensity has a limit and beyond this point can result in photodestruction of molecules. Overall, this form of imaging is extremely useful in cutting-edge research, with its ability to monitor biological processes. The progression from 2D fluorescent images to 3D ones has allowed scientists to better study spatial precision and resolution. In addition, with concentrated efforts towards 4D analysis, scientists are now able to monitor a cell in real time, enabling them to monitor fast acting processes.


Future directions

Developing more effective fluorescent proteins is a task that many scientists have taken up in order to improve imaging probe capabilities. Often, mutations in certain residues can significantly change the protein's fluorescent properties. For example, by mutating the F64L gene in jellyfish GFP, the protein is able to more efficiently fluoresce at 37 °C, an important attribute to have when growing cultures in a laboratory. In addition to this, genetic engineering can produce a protein that emits light at a better wavelength or frequency. In addition, the environment itself can play a crucial role. Fluorescence lifetime can be stabilized in a polar environment. Mechanisms that have been well described but not necessarily incorporated into practical applications hold promising potential for fluorescence imaging. Fluorescence resonance energy transfer (FRET) is an extremely sensitive mechanism that produce signaling molecules in the range of 1-10 nm. Improvements in the techniques that constitute fluorescence processes is also crucial towards more efficient designs. Fluorescence correlation spectroscopy (FCS) is an analysis technique that observes the fluctuation of fluorescence intensity. This analysis is a component of many fluorescence imaging machines and improvements in spatial resolution could improve the sensitivity and range. Development of more sensitive probes and analytical techniques for laser induced fluorescence can allow for more accurate, up-to-date experimental data.


See also

*
Fluorescence in the life sciences Fluorescence is used in the life sciences generally as a non-destructive way of tracking or analysing biological molecules. Some proteins or small molecules in cells are naturally fluorescent, which is called intrinsic fluorescence or autof ...
*
Fluorescence microscope A fluorescence microscope is an optical microscope that uses fluorescence instead of, or in addition to, scattering, reflection, and attenuation or absorption, to study the properties of organic or inorganic substances. "Fluorescence microsco ...


References


Further reading

* {{Cite book , author=Yu, Jyao; Harankhedkar, Shefali; Nabatilan, Arielle; Fahrni, Christopher , year=2021 , chapter=Chapter 4: Imaging Trace Metals in Biological Systems , url=https://www.degruyter.com/document/doi/10.1515/9783110589771-010/html , url-access=subscription , editor1-last=Kroneck , editor1-first=Peter M.H. , editor2-last=Sosa Torres , editor2-first=Martha , title=Metals, Microbes and Minerals: The Biogeochemical Side of Life , series=Volume 21 in the series Metal Ions in Life Sciences , publisher=Walter de Gruyter , location=Berlin , pages=81–134 , doi=10.1515/9783110589771-010 , isbn=9783110589771 , s2cid=240664558 , postscript= {{subscription. Cell imaging Fluorescence techniques