Your search keyword '"Buzalewicz, Igor"' showing total 12 results

1. Quantifying the Dynamics of Bacterial Biofilm Formation on the Surface of Soft Contact Lens Materials Using Digital Holographic Tomography to Advance Biofilm Research.

Author

Buzalewicz, Igor, Kaczorowska, Aleksandra, Fijałkowski, Wojciech, Pietrowska, Aleksandra, Matczuk, Anna Karolina, Podbielska, Halina, Wieliczko, Alina, Witkiewicz, Wojciech, and Jędruchniewicz, Natalia

Subjects

SOFT contact lenses, DRUG resistance in bacteria, BIOFILMS, HYDROGELS, TOMOGRAPHY, HOLOGRAPHY, DIGITAL preservation, HOLOGRAPHIC gratings

Abstract

The increase in bacterial resistance to antibiotics in recent years demands innovative strategies for the detection and combating of biofilms, which are notoriously resilient. Biofilms, particularly those on contact lenses, can lead to biofilm-related infections (e.g., conjunctivitis and keratitis), posing a significant risk to patients. Non-destructive and non-contact sensing techniques are essential in addressing this threat. Digital holographic tomography emerges as a promising solution. This allows for the 3D reconstruction of the refractive index distribution in biological samples, enabling label-free visualization and the quantitative analysis of biofilms. This tool provides insight into the dynamics of biofilm formation and maturation on the surface of transparent materials. Applying digital holographic tomography for biofilm examination has the potential to advance our ability to combat the antibiotic bacterial resistance crisis. A recent study focused on characterizing biofilm formation and maturation on six soft contact lens materials (three silicone hydrogels, three hydrogels), with a particular emphasis on Staphylococcus epidermis and Pseudomonas aeruginosa, both common culprits in ocular infections. The results revealed species- and time-dependent variations in the refractive indexes and volumes of biofilms, shedding light on cell dynamics, cell death, and contact lens material-related factors. The use of digital holographic tomography enables the quantitative analysis of biofilm dynamics, providing us with a better understanding and characterization of bacterial biofilms. [ABSTRACT FROM AUTHOR]

Published

2024

2. Quantitative Phase Imaging Detecting the Hypoxia-Induced Patterns in Healthy and Neoplastic Human Colonic Epithelial Cells.

Author

Buzalewicz, Igor, Mrozowska, Monika, Kmiecik, Alicja, Kulus, Michał, Haczkiewicz-Leśniak, Katarzyna, Dzięgiel, Piotr, Podhorska-Okołów, Marzenna, and Zadka, Łukasz

Subjects

EPITHELIAL cells, CELL size, REFRACTIVE index, COLORECTAL cancer, CELL morphology

Abstract

Hypoxia is a frequent phenomenon during carcinogenesis and may lead to functional and structural changes in proliferating cancer cells. Colorectal cancer (CRC) is one of the most common neoplasms in which hypoxia is associated with progression. The aim of this study was to assess the optical parameters and microanatomy of CRC and the normal intestinal epithelium cells using the digital holotomography (DHT) method. The examination was conducted on cancer (HT-29, LoVo) and normal colonic cells (CCD-18Co) cultured in normoxic and hypoxic environments. The assessment included optical parameters such as the refractive index (RI) and dry mass as well as the morphological features. Hypoxia decreased the RI in all cells as well as in their cytoplasm, nucleus, and nucleoli. The opposite tendency was noted for spheroid-vesicular structures, where the RI was higher for the hypoxic state. The total volume of hypoxic CCD-18Co and LoVo cells was decreased, while an increase in this parameter was observed for HT-29 cells. Hypoxia increased the radius and cell volume, including the dry mass of the vesicular content. The changes in the optics and morphology of hypoxic cells may suggest the possibility of using DHT in the detection of circulating tumor cells (CTCs). [ABSTRACT FROM AUTHOR]

Published

2022

3. The Enhancement of Antimicrobial Photodynamic Therapy of Escherichia Coli by a Functionalized Combination of Photosensitizers: In Vitro Examination of Single Cells by Quantitative Phase Imaging.

Author

Pietrowska, Aleksandra, Hołowacz, Iwona, Ulatowska-Jarża, Agnieszka, Guźniczak, Mateusz, Matczuk, Anna K., Wieliczko, Alina, Wolf-Baca, Mirela, and Buzalewicz, Igor

Abstract

The prevention of biofilm formation is crucial for the limitation of bacterial infections typically associated with postoperative infections, complications in bedridden patients, and a short-term prognosis in affected cancer patients or mechanically ventilated patients. Antimicrobial photodynamic therapy (aPDT) emerges as a promising alternative for the prevention of infections due to the inability of bacteria to become resistant to aPDT inactivation processes. The aim of this study was to demonstrate the use of a functionalized combination of Chlorin e6 and Pheophorbide as a new approach to more effective aPDT by increasing the accumulation of photosensitizers (PSs) within Escherichia coli cells. The accumulation of PSs and changes in the dry mass density of single-cell bacteria before and after aPDT treatment were investigated by digital holotomography (DHT) using the refractive index as an imaging contrast for 3D label-free live bacteria cell imaging. The results confirmed that DHT can be used in complex examination of the cell–photosensitizer interaction and characterization of the efficiency of aPDT. Furthermore, the use of Pheophorbide a as an efflux pomp inhibitor in combination with Chlorin e6 increases photosensitizers accumulation within E. coli and overcomes the limited penetration of Gram-negative cells by anionic and neutral photosensitizers. [ABSTRACT FROM AUTHOR]

Published

2022

4. Molecular profiling of the intestinal mucosa and immune cells of the colon by multi-parametric histological techniques.

Author

Zadka, Łukasz, Chrabaszcz, Karolina, Buzalewicz, Igor, Wiercigroch, Ewelina, Glatzel-Plucińska, Natalia, Szleszkowski, Łukasz, Gomułkiewicz, Agnieszka, Piotrowska, Aleksandra, Kurnol, Krzysztof, Dzięgiel, Piotr, Jurek, Tomasz, and Malek, Kamilla

Subjects

INTESTINAL mucosa, CD4 antigen, IMMUNITY, IMMUNOSTAINING, REFRACTIVE index

Abstract

The impact of the post-mortem interval (PMI) on the optical molecular characteristics of the colonic mucosa and the gut-associated lymphoid tissue (GALT) were examined by multi-parametric measurements techniques. Inflammatory cells were identified by immunohistochemical staining. Molecular parameters were estimated using the Raman spectroscopy (RS) and Fourier Transform Infrared (FTIR) spectroscopic imaging. The 3D refractive index (3D-RI) distributions of samples were determined using the digital holographic tomography. The distribution of immune cells between post-mortem (PM) and normal controls did show significant differences for CD4 (P = 0.0016) or CD8 (P < 0.0001), whose expression level was decreased in PM cases. No association was found between individual PMI values and inflammatory cell distribution. However, there was a tendency for a negative correlation between CD4+ cells and PMI (r = − 0.542, P = 0.032). The alterations ongoing in post-mortem tissue may suggest that PMI has a suppressive effect on the effector properties of the cell-mediated immunity. Moreover, it was confirmed that spectroscopic and digital holotomographic histology are also a useful technique for characterization of the differences in inflammation of varying intensity and in GALT imaging in a solid tissue. Anatomical location of immune cells and methods of tissue fixation determine the molecular and optical parameters of the examined cases. [ABSTRACT FROM AUTHOR]

Published

2021

5. Current Trends of Innovations in Microbiological Diagnosis by Light Diffraction.

Author

Buzalewicz, Igor and Podbielska, Halina

Published

2017

6. Novel Perspectives on the Characterization of Species-Dependent Optical Signatures of Bacterial Colonies by Digital Holography.

Author

Buzalewicz, Igor, Kujawińska, Małgorzata, Krauze, Wojciech, and Podbielska, Halina

Subjects

BACTERIAL colonies, HOLOGRAPHY, OPTICAL diffraction, FOOD industry, FOOD microbiology, MEDICAL practice

Abstract

The use of light diffraction for the microbiological diagnosis of bacterial colonies was a significant breakthrough with widespread implications for the food industry and clinical practice. We previously confirmed that optical sensors for bacterial colony light diffraction can be used for bacterial identification. This paper is focused on the novel perspectives of this method based on digital in-line holography (DIH), which is able to reconstruct the amplitude and phase properties of examined objects, as well as the amplitude and phase patterns of the optical field scattered/diffracted by the bacterial colony in any chosen observation plane behind the object from single digital hologram. Analysis of the amplitude and phase patterns inside a colony revealed its unique optical properties, which are associated with the internal structure and geometry of the bacterial colony. Moreover, on a computational level, it is possible to select the desired scattered/diffracted pattern within the entire observation volume that exhibits the largest amount of unique, differentiating bacterial features. These properties distinguish this method from the already proposed sensing techniques based on light diffraction/scattering of bacterial colonies. The reconstructed diffraction patterns have a similar spatial distribution as the recorded Fresnel patterns, previously applied for bacterial identification with over 98% accuracy, but they are characterized by both intensity and phase distributions. Our results using digital holography provide new optical discriminators of bacterial species revealed in one single step in form of new optical signatures of bacterial colonies: digital holograms, reconstructed amplitude and phase patterns, as well as diffraction patterns from all observation space, which exhibit species-dependent features. To the best of our knowledge, this is the first report on bacterial colony analysis via digital holography and our study represents an innovative approach to the subject. [ABSTRACT FROM AUTHOR]

Published

2016

7. Evaluation of Antibacterial Agents Activity.

Author

Buzalewicz, Igor, Wysocka-Król, Katarzyna, Kowal, Katarzyna, and Podbielska, Halina

Abstract

The novel computer aided image processing analysis presented in this paper is used to evaluate the number of bacteria colonies. Proposed algorithm exploits the computer-aided calculations of optical transforms and it is implemented to the analysis of CCD recorded images of bacteria colonies. The diffraction patterns were approximated by the Fourier spectrum and additionally, the Mellin transform was applied to omit the problem of bacteria colonies sizes fluctuations. This approach exploits the properties of Fourier and Mellin transforms for scale and spatial locations invariant analysis. The significant correlation between parameters characterizing the Mellin spectrum and the number of bacteria colonies, was observed. Presented method was used for characterization of sterilization efficiency of antibacterial nanomaterials. [ABSTRACT FROM AUTHOR]

Published

2010

8. Exploiting of optical transforms for bacteria evaluation in vitro.

Author

Buzalewicz, Igor, Wysocka, Katarzyna, and Podbielska, Halina

Published

2009

9. Photolon Nanoporous Photoactive Material with Antibacterial Activity and Label-Free Noncontact Method for Free Radical Detection.

Author

Buzalewicz, Igor, Hołowacz, Iwona, Matczuk, Anna K., Guźniczak, Mateusz, Skrzela, Dominika, Karwańska, Magdalena, Wieliczko, Alina, Kowal, Katarzyna, and Ulatowska-Jarża, Agnieszka

Subjects

FREE radicals, NANOPOROUS materials, ANTIBACTERIAL agents, SCANNING probe microscopy, OPTICAL properties, ACTION spectrum, KELVIN probe force microscopy

Abstract

The worldwide increase in bacterial resistance and healthcare-associated bacterial infections pose a serious threat to human health. The antimicrobial photodynamic method reveals the opportunity for a new therapeutic approach that is based on the limited delivery of photosensitizer from the material surface. Nanoporous inorganic–organic composites were obtained by entrapment of photosensitizer Photolon in polysiloxanes that was prepared by the sol–gel method. The material was characterized by its porosity, optical properties (fluorescence and absorbance), and laser-induced antimicrobial activity against Staphylococcus epidermidis, Staphylococcus aureus, Pseudomonas aeruginosa, and Escherichia coli. The permanent encapsulation of Photolon in the silica coating and the antimicrobial efficiency was confirmed by confocal microscope and digital holotomography. The generation of free radicals from nanoporous surfaces was proved by scanning Kelvin probe microscopy. For the first time, it was confirmed that Kelvin probe microscopy can be a label-free, noncontact alternative to other conventional methods based on fluorescence or chemiluminescence probes, etc. It was confirmed that the proposed photoactive coating enables the antibacterial photodynamic effect based on free radicals released from the surface of the coating. The highest bactericidal efficiency of the proposed coating was 87.16%. This coating can selectively limit the multiplication of bacterial cells, while protecting the environment and reducing the risk of surface contamination. [ABSTRACT FROM AUTHOR]

Published

2022

10. Bacteria Single-Cell and Photosensitizer Interaction Revealed by Quantitative Phase Imaging.

Author

Buzalewicz, Igor, Ulatowska-Jarża, Agnieszka, Kaczorowska, Aleksandra, Gąsior-Głogowska, Marlena, Podbielska, Halina, Karwańska, Magdalena, Wieliczko, Alina, Matczuk, Anna K., Kowal, Katarzyna, Kopaczyńska, Marta, and Díez-Pascual, Ana María

Subjects

PHOTOSENSITIZERS, THREE-dimensional imaging, BACTERIAL inactivation, BACTERIA, IMAGE analysis

Abstract

Quantifying changes in bacteria cells in the presence of antibacterial treatment is one of the main challenges facing contemporary medicine; it is a challenge that is relevant for tackling issues pertaining to bacterial biofilm formation that substantially decreases susceptibility to biocidal agents. Three-dimensional label-free imaging and quantitative analysis of bacteria–photosensitizer interactions, crucial for antimicrobial photodynamic therapy, is still limited due to the use of conventional imaging techniques. We present a new method for investigating the alterations in living cells and quantitatively analyzing the process of bacteria photodynamic inactivation. Digital holographic tomography (DHT) was used for in situ examination of the response of Escherichia coli and Staphylococcus aureus to the accumulation of the photosensitizers immobilized in the copolymer revealed by the changes in the 3D refractive index distributions of single cells. Obtained results were confirmed by confocal microscopy and statistical analysis. We demonstrated that DHT enables real-time characterization of the subcellular structures, the biophysical processes, and the induced local changes of the intracellular density in a label-free manner and at sub-micrometer spatial resolution. [ABSTRACT FROM AUTHOR]

Published

2021

11. Development of the Correction Algorithm to Limit the Deformation of Bacterial Colonies Diffraction Patterns Caused by Misalignment and Its Impact on the Bacteria Identification in the Proposed Optical Biosensor.

Author

Buzalewicz, Igor, Suchwałko, Agnieszka, Karwańska, Magdalena, Wieliczko, Alina, and Podbielska, Halina

Subjects

BACTERIAL typing, DIFFRACTION patterns, OPTICAL diffraction, ALGORITHMS, BIOSENSORS

Abstract

Recently proposed methods of bacteria identification in optical biosensors based on the phenomenon of light diffraction on macro-colonies offer over 98% classification accuracy. However, such high accuracy relies on the comparable and repeatable spatial intensity distribution of diffraction patterns. Therefore, it is essential to eliminate all non-species/strain-dependent factors affecting the diffraction patterns. In this study, the impact of the bacterial colony and illuminating beam misalignment on the variation of classification features extracted from diffraction patterns was examined. It was demonstrated that misalignment introduced by the scanning module significantly affected diffraction patterns and extracted classification features used for bacteria identification. Therefore, it is a crucial system-dependent factor limiting the identification accuracy. The acceptable misalignment level, when the accuracy and quality of the classification features are not affected, was determined as no greater than 50 µm. Obtained results led to development of image-processing algorithms for determination of the direction of misalignment and concurrent alignment of the bacterial colonies' diffraction patterns. The proposed algorithms enable the rigorous monitoring and controlling of the measurement's conditions in order to preserve the high accuracy of bacteria identification. [ABSTRACT FROM AUTHOR]

Published

2020

12. Photoactive Pore Matrix for In Situ Delivery of a Photosensitizer in Vascular Smooth Muscle Cells Selective PDT.

Author

Wawrzyńska, Magdalena, Duda, Maciej, Hołowacz, Iwona, Kaczorowska, Aleksandra, Ulatowska-Jarża, Agnieszka, Buzalewicz, Igor, Kałas, Wojciech, Wysokińska, Edyta, Biały, Dariusz, Podbielska, Halina, and Kopaczyńska, Marta

Subjects

VASCULAR smooth muscle, REACTIVE oxygen species, MUSCLE cells, ERYTHROCYTES, PORE size (Materials), VASCULAR endothelial cells, MESOPOROUS materials, MESOPOROUS silica

Abstract

In this study we present the porous silica-based material that can be used for in situ drug delivery, offering effective supply of active compounds regardless its water solubility. To demonstrate usability of this new material, three silica-based materials with different pore size distribution as a matrix for doping with Photolon (Ph) and Protoporphyrin IX (PPIX) photosensitizers, were prepared. These matrices can be used for coating cardiovascular stents used for treatment of the coronary artery disease and enable intravascular photodynamic therapy (PDT), which can modulate the vascular response to injury caused by stent implantation—procedure that should be thought as an alternative for drug eluting stent. The FTIR spectroscopic analysis confirmed that all studied matrices have been successfully functionalized with the target photosensitizers. Atomic force microscopy revealed that resulting photoactive matrices were very smooth, which can limit the implantation damage and reduce the risk of restenosis. No viability loss of human peripheral blood lymphocytes and no erythrocyte hemolysis upon prolonged incubations on matrices indicated good biocompatibility of designed materials. The suitability of photoactive surfaces for PDT was tested in two cell lines relevant to stent implantation: vascular endothelial cells (HUVECs) and vascular smooth muscle cells (VSMC). It was demonstrated that 2 h incubation on the silica matrices was sufficient for uptake of the encapsulated photosensitizers. Moreover, the amount of the absorbed photosensitizer was sufficient for induction of a phototoxic reaction as shown by a rise of the reactive oxygen species in photosensitized VSMC. On the other hand, limited reactive oxygen species (ROS) induction in HUVECs in our experimental set up suggests that the proposed method of PDT may be less harmful for the endothelial cells and may decrease a risk of the restenosis. Presented data clearly demonstrate that porous silica-based matrices are capable of in situ delivery of photosensitizer for PDT of VSMC. [ABSTRACT FROM AUTHOR]

Published

2019