Characterization of Liposomes Using Quantitative Phase Microscopy (QPM)

Cauzzo, Jennifer; Jayakumar, Nikhil; Ahluwalia, Balpreet Singh; Ahmad, Azeem; Škalko‐Basnet, Nataša

doi:10.3390/pharmaceutics13050590

Cited by 11 publications

(5 citation statements)

References 56 publications

(86 reference statements)

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“…Furthermore, this approach is utilized to capture the sub-cellular dynamics within U2OS cells for an extended duration of 3 h, as well as to observe the high-speed dynamics of human RBCs at a rate of 50 fps. We believe the proposed approach of achieving high throughput phase imaging with high spatial resolution and high phase sensitivity will open new avenues of bioimaging where both high-spatial sensitivity and high-imaging speed is necessary, such as live cell imaging of sperm cells 3 , pathogens like bacteria 26 and nanosized bio-particles such as liposomes 27 , extra-cellular vesicles and exosomes.…”

Section: Discussionmentioning

confidence: 99%

High space–time bandwidth product imaging in low coherence quantitative phase microscopy

Ahmad,

Gocłowski,

Dubey

et al. 2024

Sci Rep

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Current low coherence quantitative phase microscopy (LC-QPM) systems suffer from either reduced field of view (FoV) or reduced temporal resolution due to the short temporal coherence (TC) length of the light source. Here, we propose a hybrid, experimental and numerical approach to address this core problem associated with LC-QPM. We demonstrate high spatial resolution and high phase sensitivity in LC-QPM at high temporal resolution. High space–time bandwidth product is achieved by employing incoherent light source for sample illumination in QPM to increase the spatial resolution and single-shot Hilbert spiral transform (HST) based phase recovery algorithm to enhance the temporal resolution without sacrificing spatial resolution during the reconstruction steps. The high spatial phase sensitivity comes by default due to the use of incoherent light source in QPM which has low temporal coherence length and does not generate speckle noise and coherent noise. The spatial resolution achieved by the HST is slightly inferior to the temporal phase-shifting (TPS) method when tested on a specimen but surpasses that of the single-shot Fourier transform (FT) based phase recovery method. Contrary to HST method, FT method requires high density fringes for lossless phase recovery, which is difficult to achieve in LC-QPM over entire FoV. Consequently, integration of HST algorithm with LC-QPM system makes an attractive route. Here, we demonstrate scalable FoV and resolution in single-shot LC-QPM and experimentally corroborate it on a test object and on both live and fixed biological specimen such as MEF, U2OS and human red blood cells (RBCs). LC-QPM system with HST reconstruction offer high-speed single-shot QPM imaging at high phase sensitivity and high spatial resolution enabling us to study sub-cellular dynamic inside U2OS for extended duration (3 h) and observe high-speed (50 fps) dynamics of human RBCs. The experimental results validate the effectiveness of the present approach and will open new avenues in the domain of biomedical imaging in the future.

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Section: Discussionmentioning

confidence: 99%

High space–time bandwidth product imaging in low coherence quantitative phase microscopy

Ahmad,

Gocłowski,

Dubey

et al. 2024

Sci Rep

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“…Because of the double layer, liposomes, like other cells, allow a watery environment inside. The presence of the water-based core allows loading of the lysosomes with both hydrophobic and/or hydrophilic drugs, so these NPs have many therapeutic benefits [ 14 ]. To be visualized, liposomes must be labeled with certain substances, such as lipophilic cyanine dyes that fluoresce in visible light.…”

Section: Discussionmentioning

confidence: 99%

Histological findings for the absorption of small and large liposomes – the basis of future drug delivery and contrast media systems

Şufaru,

Stan,

Peptu

et al. 2024

Rom J Morphol Embryol

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Background and Objectives: The purpose of our study was to obtain and characterize carrier systems in different sizes that can affect oral absorption, since the mechanisms of liposome absorption are not yet fully understood. From stomach to the small intestine, liposomes can be gradually destroyed. Understanding the factors that affect oral absorption leads to developing safe and effective nanosystems to improve the oral delivery of therapeutics. Materials and Methods: We determined the efficiency of the absorption of small and large liposomes at the level of gingival mucosa, heart, liver, testicles, kidneys, and lungs, using frozen-section fluorescence microscopy, on rat tissues after liposomes administration. A number of 36 male rats were divided in four groups: control groups, A and C, consisted of six rats each and did not receive liposomes; two other groups, B and D, were the experimental ones, and consisted of 12 male rats each. The animals received small liposomes (75–76 nm) and large liposomes (80–87 nm), respectively, administered either by endogastric tube or intraperitoneal injection. After 24 hours, the animals were sacrificed, and we harvested the organs. We performed frozen sections and analyzed them with fluorescence microscopy. Results: The frozen sections obtained from all organs revealed a higher absorption level of small liposomes in the testicles, liver, and gum, while the large liposomes had a greater affinity for the liver, with variations dependent on the route of administration. Conclusions: Frozen-section fluorescence microscopy is a reliable technique for visualization of liposome absorption. Based on the size of these nanosystems, we revealed significant absorption for small liposomes in testicles, liver, heart, and gum, and for large liposomes mainly in the liver, compared with the control groups. The study advocates for the usage of liposomes for medical purposes, based on their absorption proprieties.

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“…With the proposed approach, scalable FOV and resolution phase imaging of the test specimen and a biological specimen (HeLa cells) is demonstrated. We believe the proposed approach of achieving high throughput phase imaging with high spatial resolution and high phase sensitivity will open new avenues of bioimaging where both high-spatial sensitivity and high-imaging speed is necessary, such as live cell imaging of sperm cells 3 , pathogens like bacteria 23 and nanosized bio-particles such as liposomes 24 , extra-cellular vesicles and exosomes.…”

Section: Discussionmentioning

confidence: 99%

High space-time bandwidth product imaging in low coherence quantitative phase microscopy

Ahmad

Gocłowski

Dubey

et al. 2022

Preprint

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Current low coherence quantitative phase microscopy (LC-QPM) systems suffer from either reduced field of view (FoV) or reduced temporal resolution due to the short temporal coherence (TC) length of the light source. Here, we propose a hybrid, experimental and numerical approach to address this core problem associated with LC-QPM. We demonstrate high spatial resolution and high phase sensitivity in LC-QPM at high temporal resolution. High space-time bandwidth product is achieved by employing incoherent light source for sample illumination in QPM to increase the spatial resolution and single-shot Hilbert spiral transform (HST) based phase recovery algorithm to enhance the temporal resolution without sacrificing spatial resolution during the reconstruction steps. The high spatial phase sensitivity comes by default due to the use of incoherent light source in QPM which has low temporal coherence length and does not generate speckle noise and coherent noise. The spatial resolution obtained from HST is compared with temporal phase shifting (TPS) method on a test specimen and found to be in a good agreement with each other and better than single-shot Fourier transform (FT) based phase recovery method. Contrary to HST method, FT method requires high density fringes for lossless phase recovery, which is difficult to achieve in LC-QPM over entire FoV. Consequently, integration of HST algorithm with LC-QPM system makes an attractive route. Here, we demonstrate scalable FoV and resolution in single-shot LC-QPM and experimentally corroborate it on a test object and on both live and fixed biological specimen such as HeLa and U2OS cells. LC-QPM system with HST reconstruction offer high-speed single-shot QPM imaging at high phase sensitivity and high spatial resolution enabling us to study sub-cellular dynamic inside U2OS for extended duration (3 hours). The experimental results validate the effectiveness of the present approach and will open new avenues in the domain of biomedical imaging in future.

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Characterization of Liposomes Using Quantitative Phase Microscopy (QPM)

Cited by 11 publications

References 56 publications

High space–time bandwidth product imaging in low coherence quantitative phase microscopy

High space–time bandwidth product imaging in low coherence quantitative phase microscopy

Histological findings for the absorption of small and large liposomes – the basis of future drug delivery and contrast media systems

High space-time bandwidth product imaging in low coherence quantitative phase microscopy

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