Your search keyword '"Mikkonen JJ"' showing total 11 results

1. The defence architecture of the superficial cells of the oral mucosa.

Author

Asikainen P, Ruotsalainen TJ, Mikkonen JJ, Koistinen A, Ten Bruggenkate C, and Kullaa AM

Published

2012

2. Effects of irradiation in the mandibular bone loaded with dental implants. An experimental study with a canine model.

Author

Padala SR, Asikainen P, Ruotsalainen T, Mikkonen JJ, Silvast TS, Koistinen AP, Schulten EAJM, Ten Bruggenkate CM, and Kullaa AM

Subjects

Animals, Dogs, Mandible diagnostic imaging, Osseointegration, Osteocytes, X-Ray Microtomography, Dental Implants

Abstract

Radiation therapy may compromise the quality of bone around dental implants, and its ability to regenerate, remodel, and revascularize. This study aimed to describe the irradiation effect on the bone microstructure of the mandible using dental implants in a canine model. Five beagle dogs were exposed to 40 Gy fractionated radiation. In total, 20 dental implants were inserted, two in the irradiated and two in the non-irradiated side. The mandible bone blocks were subjected to 3D micro-computed tomography (µCT) imaging, later evaluated histomorphometrically by light microscopy and scanning electron microscopy. Alterations in irradiated bone were observed under µCT imaging showing an increased anisotropy, porosity, and pore volume. Bone surface-to-bone volume decreased. The bone to implant contact index was significantly reduced in the irradiated bone (75.6% ± 5.8%) as compared to the non-irradiated bone (85.1% ± 6.8%). In the irradiated mandible, osteocytes with their filopodial processes, the bone beneath the periosteum, and subperiosteal veins showed structural differences but were not significant, whereas the diameter of Haversian canals were smaller statistical significant as compared to the control side. The study highlights that radiation dosage of fractioned 40 Gy causes alterations in the alveolar bone microstructure with compatible osseointegration and clinically stable dental implants.

Published

2021

3. Alveolar bone remodeling after tooth extraction in irradiated mandible: An experimental study with canine model.

Author

Heinonen V, Ruotsalainen TJ, Paavola L, Mikkonen JJ, Asikainen P, Koistinen AP, and Kullaa AM

Subjects

Alveolar Process pathology, Alveolar Process ultrastructure, Animals, Disease Models, Animal, Dogs, Mandible pathology, Mandible ultrastructure, Microscopy, Electron, Scanning, Osteocytes pathology, Osteocytes ultrastructure, Alveolar Process radiation effects, Bone Remodeling radiation effects, Mandible radiation effects, Osteocytes radiation effects, Tooth Extraction adverse effects

Abstract

Objectives: The aim of the present study is to investigate the morphological and cellular changes in dental extraction socket that has been irradiated after the tooth extraction and to describe morphological characteristics of the osteocytes and osteocyte-lacunar-canalicular network (LCN) by scanning electron microscopy (SEM)., Material and Methods: Five beagle dogs aged 1-2 years were used in this study. One side of each mandible was irradiated in two sessions and the other side of mandible (non-irradiated) served as a control. The mandible bone blocks were processed by bulk staining en bloc in basic fuchsin and the specimens were embedded routinely in polymethyl methacrylate resin without preliminary decalcification. All blocks were subjected to micro-CT imaging, after that the specimens were prepared for light microscopy and SEM., Results: Alterations in bone macrostructure are minimal in irradiated bone, but the changes in LCN are clear. In the area of the tooth extraction socket, the connections of osteocytes to the vessels and to neighboring osteocytes were not observed both in irradiated and nonirradiated bone. However, osteoclasts were located in the bone surface entering inside to the bone between osteons. In the lamellar bone of lateral sides, a decrease in canalicular connections between osteocytes and periosteum was found in irradiated bone as compared to the non-irradiated side., Conclusions: The novelty of the present study is that radiation disrupts osteocytes and their dendrites.

Published

2018

4. Oral mucosal epithelial cells express the membrane anchored mucin MUC1.

Author

Ukkonen H, Pirhonen P, Herrala M, Mikkonen JJ, Singh SP, Sormunen R, and Kullaa AM

Subjects

Adult, Cell Line, Tumor, Cell Membrane metabolism, Cytoplasm metabolism, Dental Pellicle cytology, Female, Humans, Immunohistochemistry methods, Male, Microscopy, Immunoelectron methods, Middle Aged, Mouth Mucosa cytology, Dental Pellicle metabolism, Epithelial Cells metabolism, Mouth Mucosa metabolism, Mucin-1 biosynthesis

Abstract

Objective: The presence of a stable salivary pellicle (SP) is essential to provide a wet surface for the oral mucosal epithelia. The oral mucosa is covered by the SP which is suggested to be a mixed film of both salivary and epithelial components. Our aim was to analyse the presence of membrane-anchored mucin MUC1 in the oral mucosal epithelia., Desing: The presence of MUC1 was studied by immunohistochemical and immunoelectron microscopical methods in 19 buccal mucosal specimens. The localization and intensity of the epithelial expression were analyzed., Results: Strong staining of MUC1 was found in the epithelial cells of intermediate and superficial layers. Some basal cells were shown faint expression. In the intermediate and superficial layers, the MUC1 expression was seen mainly on the upper cell surface. Furthermore, the expression of MUC1 was noted in the cytoplasm near the nucleus and in the rough granules. By electron microscopy, extracellular domain of membrane-anchored molecules extruded about 15-30nm above the cell surface in the apical cells of the oral epithelium. Immunoelectron microscopic examination shows that MUC1 is mainly localized in the plasma membrane of epithelial cells and also in small vesicles (75-100nm) just below the plasma membrane., Conclusion: The membrane-anchored MUC1 is expressed in the superficial layer of the oral mucosal epithelium, especially on the upper surface of epithelial cells. MUCI may be the anchoring protein of the salivary pellicle stabilization., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2017

5. Fourier Transform Infrared Spectroscopy and Photoacoustic Spectroscopy for Saliva Analysis.

Author

Mikkonen JJ, Raittila J, Rieppo L, Lappalainen R, Kullaa AM, and Myllymaa S

Subjects

Adult, Albumins analysis, Female, Humans, Linear Models, Male, Thiocyanates analysis, Young Adult, Photoacoustic Techniques methods, Saliva chemistry, Spectroscopy, Fourier Transform Infrared methods

Abstract

Saliva provides a valuable tool for assessing oral and systemic diseases, but concentrations of salivary components are very small, calling the need for precise analysis methods. In this work, Fourier transform infrared (FT-IR) spectroscopy using transmission and photoacoustic (PA) modes were compared for quantitative analysis of saliva. The performance of these techniques was compared with a calibration series. The linearity of spectrum output was verified by using albumin-thiocyanate (SCN(-)) solution at different SCN(-) concentrations. Saliva samples used as a comparison were obtained from healthy subjects. Saliva droplets of 15 µL were applied on the silicon sample substrate, 6 drops for each specimen, and dried at 37 ℃ overnight. The measurements were carried out using an FT-IR spectrometer in conjunction with an accessory unit for PA measurements. The findings with both transmission and PA modes mirror each other. The major bands presented were 1500-1750 cm(-1) for proteins and 1050-1200 cm(-1) for carbohydrates. In addition, the distinct spectral band at 2050 cm(-1) derives from SCN(-) anions, which is converted by salivary peroxidases to hypothiocyanate (OSCN(-)). The correlation between the spectroscopic data with SCN(-) concentration (r > 0.990 for transmission and r = 0.967 for PA mode) was found to be significant (P < 0.01), thus promising to be utilized in future applications., (© The Author(s) 2016.)

Published

2016

6. Salivary metabolomics in the diagnosis of oral cancer and periodontal diseases.

Author

Mikkonen JJ, Singh SP, Herrala M, Lappalainen R, Myllymaa S, and Kullaa AM

Subjects

Humans, Mouth Neoplasms metabolism, Periodontal Diseases metabolism, Specimen Handling methods, Metabolomics, Mouth Neoplasms diagnosis, Periodontal Diseases diagnosis, Saliva metabolism

Abstract

Metabolomics is a systemic study of metabolites, which are small molecules generated by the process of metabolism. The metabolic profile of saliva can provide an early outlook of the changes associated with a wide range of diseases, including oral cancer and periodontal diseases. It is possible to measure levels of disease-specific metabolites using different methods as presented in this study. However, many challenges exist including incomplete understanding of the complicated metabolic pathways of different oral diseases. The review concludes with the discussion on future perspectives of salivary metabolomics from a clinician point of view. Salivary metabolomics may afford a new research avenue to identify local and systemic disorders but also to aid in the design and modification of therapies. A MEDLINE search using keywords "salivary metabolomics" returned 23 results in total, of which seven were omitted for being reviews or letters to the editor. The rest of the articles were used for preparation of the review, 13 of these were published in the last 5 years., (© 2015 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2016

7. Microplicae--Specialized Surface Structure of Epithelial Cells of Wet-Surfaced Oral Mucosa.

Author

Asikainen P, Sirviö E, Mikkonen JJ, Singh SP, Schulten EA, ten Bruggenkate CM, Koistinen AP, and Kullaa AM

Subjects

Humans, Microscopy, Electron, Scanning, Mouth ultrastructure, Mouth Mucosa ultrastructure

Abstract

The surface structure of the superficial cells of the oral mucosa is decorated with numerous membrane ridges, termed microplicae (MPLs). The MPL structure is typical of the epithelial surfaces that are covered with protective mucus. Cell membrane MPLs are no longer seen as passive consequences of cellular activity. The interaction between MPLs and the mucins has been demonstrated, however the role of MPL structure seen on the upper surface of the oral epithelial cells is speculative. The cell surface is of potentially great significance, as it harbors many markers for refined prognosis and targets for oral mucosal diseases and cancer therapy. With these aspects in mind, we conducted the present review of the MPL structure and function in order to form the basis for further studies of MPLs of the oral epithelial cells.

Published

2015

8. Microstructure of oral epithelial cells as an underlying basis for salivary mucosal pellicle.

Author

Kullaa AM, Asikainen P, Herrala M, Ukkonen H, and Mikkonen JJ

Subjects

Adult, Dental Pellicle metabolism, Female, Humans, Immunohistochemistry, Male, Microscopy, Electron, Scanning, Microscopy, Electron, Transmission, Middle Aged, Mouth Mucosa metabolism, Mucin-1 biosynthesis, Mucin-4 biosynthesis, Dental Pellicle ultrastructure, Mouth Mucosa ultrastructure

Abstract

Background: Salivary mucosal pellicle forms the structural basis of the local innate immune defense mechanism of the oral mucosa. At the surface of the oral mucosa, the apical cell membrane adjacent to the saliva interface contains short membrane folds, termed microplicae (MPL). This MPL structure of oral epithelial cells and its function as a basis to the salivary mucosal pellicle is unclear. In this preliminary study, we describe the ultrastructural morphology of cell membrane of superficial cells of the oral mucosa and study the membrane-associated mucins (MAMs), MUC1 and MUC4, with immunohistological methods., Materials and Methods: Oral mucosal specimens were obtained from six healthy patients. Half of each specimen was prepared routinely for light microscopy, and the other part for scanning and transmission electron microscopy. The presence of MUC1 and MUC4 were studied by immunohistochemical methods in oral mucosal specimens., Results: Morphologically, the cell membrane of MPL is partly discontinuous and membrane-associated molecules extrude from the cell membrane. MUC1 expression was detected in the superficial part of the buccal epithelium, while MUC4 had no expression in the oral squamous epithelium., Conclusions: The novel of this study is that the membrane-tethered molecules seem to occur onto the cell membrane of the superficial epithelial cells of the oral mucosa. Furthermore, the stratified squamous epithelium of the buccal mucosa produces MUC1 for the surface-saliva pellicle interface. The interaction between MPL structure, MUC1 mucin, and salivary mucosal pellicle is discussed.

Published

2014

9. Surface morphology of superficial cells in irradiated oral mucosa: an experimental study in beagle dog.

Author

Asikainen P, Mikkonen JJ, and Kullaa AM

Subjects

Animals, Disease Models, Animal, Dogs, Epithelial Cells radiation effects, Epithelial Cells ultrastructure, Microscopy, Electron, Scanning, Radiotherapy adverse effects, Mouth Mucosa radiation effects, Mouth Mucosa ultrastructure, Stomatitis pathology

Abstract

Objectives: The aim of the present study is to investigate if radiation induces changes in the superficial cells of the oral mucosa and secondly to describe morphological characteristics of the cell surface structure by scanning electron microscopy (SEM)., Materials and Methods: Ten beagle dogs aged 1-2 years were used in this study. One side of each mandible was irradiated in two sessions, each lasting 1 week. The total dosage was 40 Gy (Group A; 5 dogs) and 50 Gy (Group B; 5 dogs), in five fractions of 4 Gy. The other side of mandible (non-irradiated) served as a control. The specimen was harvested with a scalpel from the alveolar mucosa of the irradiated area 1 year after irradiation and studied with SEM., Results: In the control side, the surface structure of the cell contains straight parallel or branched microplicae (MPL), which were equally spaced over the cell surfaces. Discontinuous and short MPL were typical cell structure of irradiated mucosa. In 50 Gy group, the surface structure of epithelial cell was pitted and the cell boundaries were thick., Conclusions: The novelty of the present study is that radiation disrupts superficial cells of the oral mucosa. The role of the MPL structure of the superficial cells in mucositis development is discussed.

Published

2014

10. Fissured tongue: a sign of tongue edema?

Author

Järvinen J, Mikkonen JJ, and Kullaa AM

Subjects

Adult, Humans, Edema complications, Glossitis, Benign Migratory physiopathology, Inflammation complications, Models, Biological, Tongue, Fissured epidemiology, Tongue, Fissured etiology, Tongue, Fissured pathology

Abstract

Fissured tongue (FT) is a condition frequently seen in the general population. Clinically, FT is characterized by grooves that vary in depth and are noted along the dorsal and/or dorsolateral aspects of the tongue. Furthermore, FT presents many enlarged, smooth filiform papillae and subepithelial inflammatory infiltration. Despite of many studies, the etiology of FT remains obscure. FT is believed to be a congenital anomaly associated with several disorders and with geographic tongue (GT). We hypothesize that FT is not a congenital anomaly, and FT with swollen filiform papillae may represent edema in the subepithelial tissue of the tongue. According to the literature, the difference in prevalence among different age groups indicates that FT is not a congenital disorder. FT appears to occur more commonly in adults, and it is very rare or not at all in children younger than 10 years old. An association between FT and GT is well established in the literature, supporting the results of previous authors suggesting that FT might be a consequence of GT. The most remarkable finding in the region of swollen papillae of FT samples has been the subepithelial infiltrates of polymorphonuclear leucocytes and lymphocytes causing the subepithelial edema. The clinically visible grooves and large edematic papillae clustered on the region of the fissures might be caused by the inflammation and edema underneath the epithelium. In the future, FT and GT must be researched together as two different entities of the same disease so that GT is a prestage of FT. The diagnosis of FT must be taken to consideration whether the tongue surface have smooth and swollen papillae or normal-appearing filiform papillae., (Copyright © 2014 Elsevier Ltd. All rights reserved.)

Published

2014

11. Microstructure of the superficial epithelial cells of the human oral mucosa.

Author

Asikainen P, Mikkonen JJ, Ruotsalainen TJ, Koistinen AP, and Kullaa AM

Subjects

Adolescent, Adult, Child, Child, Preschool, Female, Humans, Image Processing, Computer-Assisted, Male, Microscopy, Electron, Scanning, Microscopy, Electron, Transmission, Middle Aged, Young Adult, Epithelial Cells ultrastructure, Mouth Mucosa ultrastructure

Abstract

Background: The apical cell membrane of the oral mucosa adjacent to the saliva interface is thrown into membrane folds, termed microplicae (MPL) with variation in morphology. The present study classifies morphological changes undergone by MPL into qualitative and quantitative categories., Material and Methods: Oral mucosal specimens were obtained from 32 healthy patients. Half of each specimen was prepared routinely for light microscopy, and the other part for scanning and transmission electron microscopy. Different measurements of cell structure were presented: the density of MPL, the width and height of MPL, the width of furrows between two adjacent MPL and the distance of the centre of MPL. Morphometric measurements were obtained using a semiautomatic ImageJ analysis software (W Rasband, National Institutes of Health, Bethesda, MD)., Results: Parallel and branching MPL was common observation in the area of lining mucosa and in the tongue between the filiform papillae. The density of MPL was higher in the cells of the buccal mucosa than in the cells of the tongue, 43.69 + 11.43% and 31.68 + 10.32%, respectively. The difference was significant (p < 0.001). The width of MPL was 0.16 µm in cells of the buccal mucosa and 0.12 µm in cells of the tongue., Conclusions: Our findings support the idea that MPL structure is a determining factor for the functionality of the oral epithelium since the values of the MPL were kept relatively stable. The role of MPL structure of the oral mucosal cells is discussed.

Published

2014