Principles
Conventional, widefield microscopy is generally unsuitable for imaging thick tissue because the images are corrupted by a blurred, out-of-focus background signal. Endomicroscopes achieve optical sectioning (removal of the background intensity) using the confocal principle - each image frame is assembled in a point-by-point fashion by scanning a laser spot rapidly over the tissue. In table-top confocal microscopes the scanning is usually performed using bulky galvanometer or resonant scanning mirrors. Endomicroscopes either have a miniaturised scanning head at the distal tip of the imaging probe, or perform the scanning outside of the patient and use an imaging fibre bundle to transfer the scan pattern to the tissue.Single Fibre Endomicroscopes
Single fibre confocal endomicroscopes use the tip of an optical fibre as a spatial filter, enabling miniaturisation of the microscope. 488nm blue laser passes from the source through an optical fibre to a flexible hand-held probe. Optics in the probe focus the laser to a spot in the tissue, exciting fluorescence. Emitted light is captured into the optical fibre and passed through an optical filter to a detector. An image is generated by scanning the focused spot throughout the image plane and compiling the point intensity measurements. The image plane can be translated up and down in the sample, allowing generation of 3D image stacks. Single fibre endomicroscopes have similar resolution of a conventional confocal microscope.Fibre Bundle Endomicroscopes
Fibre bundles were originally developed for use in flexible endoscopes. and have since been adapted for use in endomicroscopy.Goualher, G.L., et al. Towards Optical Biopsies with an Integrated Fibered Confocal Fluorescence Microscope. in MICCAI 2004. 2004. They consist of a large number (up to tens of thousands) of fibre cores inside a single shared cladding, are flexible, and have diameters on the order of a millimetre. In a coherent fibre bundle the relative positions of the cores are maintained along the fibre, meaning that an image projected onto one end of the bundle will be transferred to the other end without scrambling. Therefore, if one end of the bundle is placed at the focus of a table-top confocal microscope, the bundle will act as a flexible extension and allow endoscopic operation. Since only the cores, and not the cladding, transmit light, image processing must be applied to remove the resulting honeycomb-like appearance of the images. Each core essentially acts as an image pixel, and so the spacing between fibre cores limits the resolution. The addition of micro-optics at the distal tip of the bundle allows for magnification and hence higher resolution imaging, but at the cost of reducing the field-of-view.Distal Scanning Endomicroscopes
Distal scanning endomicroscopes incorporate a miniature 2D scanning apparatus into the imaging probe. The laser excitation and returning fluorescent emission are sent to and received from the scanning head using an optical fibre. Most experimental devices have either usedNon-Confocal Endomicroscopes
Widefield endomicroscopes (i.e. non-depth sectioning microscopes) have been developed for select applications, including the imaging of cells ''ex vivo''. Optical coherence tomography and multi-photon microscopy have both been demonstrated endoscopically.Huo, L., et al., Forward-viewing resonant fiber-optic scanning endoscope of appropriate scanning speed for 3D OCT imaging. Optics express, 2010. 18: p. 14375-84.Zhang, Y.Y., et al., A compact fiber-optic SHG scanning endomicroscope and its application to visualize cervical remodeling during pregnancy. Proceedings of the National Academy of Sciences, 2012. 109: P. 12878-83.Xi, J.F., et al., Integrated multimodal endomicroscopy platform for simultaneous en face optical coherence and two-photon fluorescence imaging. Optics Letters, 2012. 37: p. 362-44. Successful implementations have used distal scanning rather than fibre bundles due to problems withCommercial Products
Four endomicroscope products have been developed: The fluorescence in vivo endomicroscope - FIVE2 ( OptiScan Imaging Ltd, Melbourne, Australia) developed for pre-clinical research, the neurosurgical device Convivo ( Carl Zeiss Meditech AG, Jena, Germany), the Pentax ISC-1000/EC3870CIK endoscope (Applications
The majority of clinical trials have focused on applications in the gastro-intestinal (GI) tract, particularly the detection and characterisation of pre-cancerous lesions. OptiScan's FIVE2 has been certified to ISO 13485:2016 in alignment with 21CFR820 and EU Medical device regulations for installation of the scanner into medical devices while Mauna Kea’s Cellvizio has US Food and Drug Administration (FDA) 510(k) clearance and a European CE Mark for clinical use in the GI and pulmonary tracts. Research studies have suggested a large range of potential applications, including in the urinary tract, head and neck, ovaries, and lungs. Commonly used fluorescent stains include topically applied acriflavine, and intravenously administered fluorescein sodium.Sharman MJ et al. The exogenous fluorophore, fluorescein, enables in vivo assessment of the gastrointestinal mucosa via confocal endomicroscopy: optimization of intravenous dosing in the dog model. Journal of Veterinary Pharmacology and Therapeutics, 2012. DOI: 10.1111/jvp.12031References
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