Your search keyword '"Hemmilä, Heidi"' showing total 20 results

1. Vacuum Oven Drying: A Cost-Effective Way of Producing Field-Deployable Reagents for In-house Real-Time PCR Methods

Author

Lind, Katja, Mölsä, Markos, Kalin-Mänttäri, Laura, Hemmilä, Heidi, Voutilainen, Liina, and Nikkari, Simo

Published

2023

2. High secondary attack rate and persistence of SARS-CoV-2 antibodies in household transmission study participants, Finland 2020–2021

Author

Dub, Timothée, primary, Solastie, Anna, additional, Hagberg, Lotta, additional, Liedes, Oona, additional, Nohynek, Hanna, additional, Haveri, Anu, additional, Virta, Camilla, additional, Vara, Saimi, additional, Lasander, Mervi, additional, Ekström, Nina, additional, Österlund, Pamela, additional, Lind, Katja, additional, Valtonen, Hanna, additional, Hemmilä, Heidi, additional, Ikonen, Niina, additional, Lukkarinen, Timo, additional, Palmu, Arto A., additional, and Melin, Merit, additional

Published

2022

3. Molecular Characterization of Adenoviruses Among Finnish Military Conscripts

Author

Mölsä, Markos, Hemmilä, Heidi, Rönkkö, Esa, Virkki, Maria, Nikkari, Simo, and Ziegler, Thedi

Published

2016

4. High secondary attack rate and persistence of SARS-CoV-2 antibodies in household transmission study participants, Finland 2020

Author

Dub, Timothée, primary, Nohynek, Hanna, additional, Hagberg, Lotta, additional, Liedes, Oona, additional, Haveri, Anu, additional, Virta, Camilla, additional, Solastie, Anna, additional, Vara, Saimi, additional, Ekström, Nina, additional, Österlund, Pamela, additional, Lind, Katja, additional, Valtonen, Hanna, additional, Hemmilä, Heidi, additional, Ikonen, Niina, additional, Lukkarinen, Timo, additional, Palmu, Arto A., additional, and Melin, Merit, additional

Published

2021

5. The role of microbes in the pathogenesis of acute rhinosinusitis in young adults

Author

Autio, Timo J., Tapiainen, Terhi, Koskenkorva, Timo, Närkiö, Mervi, Lappalainen, Maija, Nikkari, Simo, Hemmilä, Heidi, Koskela, Katja A., Koskela, Markku, Koivunen, Petri, and Alho, Olli‐Pekka

Subjects

Male, Haemophilus Infections, Statistics as Topic, virus, Cohort Studies, Young Adult, Nasopharynx, Original Reports, otorhinolaryngologic diseases, Humans, Prospective Studies, Allergy/Rhinology, Sinusitis, pathophysiology, Finland, Rhinitis, Bacteriological Techniques, Virulence, pathogenic bacteria, Endoscopy, Cone-Beam Computed Tomography, Maxillary Sinus, Haemophilus influenzae, Nasal Mucosa, Military Personnel, Virus Diseases, Acute Disease, Disease Progression, sinus, Acute rhinosinusitis, Multiplex Polymerase Chain Reaction, Follow-Up Studies

Abstract

Objectives/Hypothesis To provide information on the course of acute rhinosinusitis (ARS) with sequential nasal and paranasal microbiological data and their correlation with clinical outcomes. Study Design We conducted a prospective cohort study among 50 Finnish military recruits with clinically diagnosed ARS in spring 2012. Methods We collected symptom, nasal endoscopy, and cone‐beam CT (CBCT) scores during the early (2–3 days from onset) and later phases (9–10 days). We took viral samples from the nasopharynx (multiplex respiratory virus polymerase chain reaction [PCR]), bacterial culture from the middle meatus during both phases, and both viral and bacterial samples from the maxillary sinus aspirate (respiratory virus PCR, bacterial culture, broad‐range bacterial PCR) during the later phase. Cilia destruction and microbial biofilms were sought from a nasal mucosal biopsy sample. Results We found that 42 (84%) of the subjects had viral nucleic acid in the nasopharynx during ARS. During the early phase, 28 (56%) of the subjects had nontypeable H. influenzae (NTHi) in the middle meatus, which was associated with wider paranasal mucosal changes in CBCT scans and increased symptoms during the study period. After 9 to 10 days from the onset, NTHi was found in the maxillary sinus in eight subjects (40%, 8/20) and led to prolonged symptoms. Bacterial biofilm was ruled out in 39 (78%) cases, and cilia destruction did not correlate with microbiological or clinical outcomes. Conclusion Nasal and paranasal H. influenzae coinfection during viral infection may modify the symptoms and the extent of sinonasal mucosal disease observed in CBCT scans already from the beginning of the ARS episode. Level of Evidence N/A. Laryngoscope, 125:E1–E7, 2015

Published

2014

6. Metagenomic Evaluation of Bacteria from Voles

Author

Koskela, Katja A., primary, Kalin-Mänttäri, Laura, additional, Hemmilä, Heidi, additional, Smura, Teemu, additional, Kinnunen, Paula M., additional, Niemimaa, Jukka, additional, Henttonen, Heikki, additional, and Nikkari, Simo, additional

Published

2017

7. Phylogeography of Francisella tularensis subspecies holarctica in Finland, 1993–2011

Author

Sissonen, Susanna, Rossow, Heidi, Karlsson, Edvin, Hemmilä, Heidi, Henttonen, Heikki, Isomursu, Marja, Kinnunen, Paula M., Pelkola, Kirsti, Pelkonen, Sinikka, Tarkka, Eveliina, Myrtennäs, Kerstin, Nikkari, Simo, and Forsman, Mats

Abstract

Background: Finland repeatedly reports some of the highest incidences of tularaemia worldwide. To determine genetic diversity of the aetiologic agent of tularaemia, Francisella tularensis, a total of 76 samples from humans (n = 15) and animals (n = 61) were analysed. Methods: We used CanSNPs and canINDEL hydrolysis or TaqMan MGB probes for the analyses, either directly from the clinical tissue samples (n = 21) or from bacterial isolates (n = 55). Results: The genotypes of the strains were assigned to three previously described basal subspecies holarctica clades. The majority of strains (n = 67) were assigned to B.12, a clade reported to dominate in Scandinavia and Eastern Europe. A single strain was assigned to clade B.4, previously reported from North America, Europe and China. The remaining strains (n = 8) were members of clade B.6. Importantly, new diversity was discovered in clade B.6. We describe two newly designed TaqMan MGB probe assays for this new B.6 subclade B.70, and its previously identified sister clade B.11, a clade dominantly found in Western Europe. Conclusions: The high genetic diversity of F. tularensis subspecies holarctica present in Finland is consistent with previous findings in Sweden. The results suggest a northern and southern division of the B.6 subclade B.10, where B.11 predominates in Western and Central Europe and B.70 is found in Fennoscandia. Further research is required to define whether the vast diversity of genotypes found is related to different habitats or reservoir species, their different postglacial immigration routes to Fennoscandia, or dynamics of the reservoir species.

Published

2015

8. Comparison of four commercial DNA extraction kits for the recovery of Bacillus spp. spore DNA from spiked powder samples

Author

Mölsä, Markos, primary, Kalin-Mänttäri, Laura, additional, Tonteri, Elina, additional, Hemmilä, Heidi, additional, and Nikkari, Simo, additional

Published

2016

9. Severe Ocular Cowpox in a Human, Finland

Author

Kinnunen, Paula M., primary, Holopainen, Juha M., additional, Hemmilä, Heidi, additional, Piiparinen, Heli, additional, Sironen, Tarja, additional, Kivelä, Tero, additional, Virtanen, Jenni, additional, Niemimaa, Jukka, additional, Nikkari, Simo, additional, Järvinen, Asko, additional, and Vapalahti, Olli, additional

Published

2015

10. Molecular characterization of adenoviruses among finnish military conscripts

Author

Mölsä, Markos, primary, Hemmilä, Heidi, additional, Rönkkö, Esa, additional, Virkki, Maria, additional, Nikkari, Simo, additional, and Ziegler, Thedi, additional

Published

2015

11. Monitoring biothreat agents (Francisella tularensis, Bacillus anthracis and Yersinia pestis) with a portable real-time PCR instrument

Author

Mölsä, Markos, primary, Hemmilä, Heidi, additional, Katz, Anna, additional, Niemimaa, Jukka, additional, Forbes, Kristian M., additional, Huitu, Otso, additional, Stuart, Peter, additional, Henttonen, Heikki, additional, and Nikkari, Simo, additional

Published

2015

12. Phylogeography ofFrancisella tularensissubspeciesholarcticain Finland, 1993–2011

Author

Sissonen, Susanna, primary, Rossow, Heidi, additional, Karlsson, Edvin, additional, Hemmilä, Heidi, additional, Henttonen, Heikki, additional, Isomursu, Marja, additional, Kinnunen, Paula M., additional, Pelkola, Kirsti, additional, Pelkonen, Sinikka, additional, Tarkka, Eveliina, additional, Myrtennäs, Kerstin, additional, Nikkari, Simo, additional, and Forsman, Mats, additional

Published

2015

13. Experimental infection of voles with francisella tularensis indicates their amplification role in tularemia outbreaks

Author

Rossow, Heidi, Forbes, Kristian M, Tarkka, Eveliina, Kinnunen, Paula M, Hemmilä, Heidi, Huitu, Otso, Nikkari, Simo, Henttonen, Heikki, Kipar, Anja, Vapalahti, Olli, Rossow, Heidi, Forbes, Kristian M, Tarkka, Eveliina, Kinnunen, Paula M, Hemmilä, Heidi, Huitu, Otso, Nikkari, Simo, Henttonen, Heikki, Kipar, Anja, and Vapalahti, Olli

Abstract

Tularemia outbreaks in humans have been linked to fluctuations in rodent population density, but the mode of bacterial maintenance in nature is unclear. Here we report on an experiment to investigate the pathogenesis of Francisella tularensis infection in wild rodents, and thereby assess their potential to spread the bacterium. We infected 20 field voles (Microtus agrestis) and 12 bank voles (Myodes glareolus) with a strain of F. tularensis ssp. holarctica isolated from a human patient. Upon euthanasia or death, voles were necropsied and specimens collected for histological assessment and identification of bacteria by immunohistology and PCR. Bacterial excretion and a rapid lethal clinical course with pathological changes consistent with bacteremia and tissue necrosis were observed in infected animals. The results support a role for voles as an amplification host of F. tularensis, as excreta and, in particular, carcasses with high bacterial burden could serve as a source for environmental contamination.

Published

2014

14. Experimental Infection of Voles with Francisella tularensis Indicates Their Amplification Role in Tularemia Outbreaks

Author

Rossow, Heidi, primary, Forbes, Kristian M., additional, Tarkka, Eveliina, additional, Kinnunen, Paula M., additional, Hemmilä, Heidi, additional, Huitu, Otso, additional, Nikkari, Simo, additional, Henttonen, Heikki, additional, Kipar, Anja, additional, and Vapalahti, Olli, additional

Published

2014

15. Detection ofFrancisella tularensisin Voles in Finland

Author

Rossow, Heidi, primary, Sissonen, Susanna, additional, Koskela, Katja A., additional, Kinnunen, Paula M., additional, Hemmilä, Heidi, additional, Niemimaa, Jukka, additional, Huitu, Otso, additional, Kuusi, Markku, additional, Vapalahti, Olli, additional, Henttonen, Heikki, additional, and Nikkari, Simo, additional

Published

2014

16. The role of microbes in the pathogenesis of acute rhinosinusitis in young adults.

Author

Autio, Timo J., Tapiainen, Terhi, Koskenkorva, Timo, Närkiö, Mervi, Lappalainen, Maija, Nikkari, Simo, Hemmilä, Heidi, Koskela, Katja A., Koskela, Markku, Koivunen, Petri, and Alho, Olli‐Pekka

Abstract

Objectives/Hypothesis To provide information on the course of acute rhinosinusitis (ARS) with sequential nasal and paranasal microbiological data and their correlation with clinical outcomes. Study Design We conducted a prospective cohort study among 50 Finnish military recruits with clinically diagnosed ARS in spring 2012. Methods We collected symptom, nasal endoscopy, and cone-beam CT (CBCT) scores during the early (2-3 days from onset) and later phases (9-10 days). We took viral samples from the nasopharynx (multiplex respiratory virus polymerase chain reaction [PCR]), bacterial culture from the middle meatus during both phases, and both viral and bacterial samples from the maxillary sinus aspirate (respiratory virus PCR, bacterial culture, broad-range bacterial PCR) during the later phase. Cilia destruction and microbial biofilms were sought from a nasal mucosal biopsy sample. Results We found that 42 (84%) of the subjects had viral nucleic acid in the nasopharynx during ARS. During the early phase, 28 (56%) of the subjects had nontypeable H. influenzae (NTHi) in the middle meatus, which was associated with wider paranasal mucosal changes in CBCT scans and increased symptoms during the study period. After 9 to 10 days from the onset, NTHi was found in the maxillary sinus in eight subjects (40%, 8/20) and led to prolonged symptoms. Bacterial biofilm was ruled out in 39 (78%) cases, and cilia destruction did not correlate with microbiological or clinical outcomes. Conclusion Nasal and paranasal H. influenzae coinfection during viral infection may modify the symptoms and the extent of sinonasal mucosal disease observed in CBCT scans already from the beginning of the ARS episode. Level of Evidence N/A. Laryngoscope, 125:E1-E7, 2015 [ABSTRACT FROM AUTHOR]

Published

2015

17. Detection of Francisella tularensis in Voles in Finland.

Author

Rossow, Heidi, Sissonen, Susanna, Koskela, Katja A., Kinnunen, Paula M., Hemmilä, Heidi, Niemimaa, Jukka, Huitu, Otso, Kuusi, Markku, Vapalahti, Olli, Henttonen, Heikki, and Nikkari, Simo

Subjects

FRANCISELLA tularensis, VIRULENCE of bacteria, VOLES, RODENT diseases, ZOONOSES

Abstract

Francisella tularensis is a highly virulent intracellular bacterium causing the zoonotic disease tularemia. It recurrently causes human and animal outbreaks in northern Europe, including Finland. Although F. tularensis infects several mammal species, only rodents and lagomorphs seem to have importance in its ecology. Peak densities of rodent populations may trigger tularemia outbreaks in humans; however, it is still unclear to which extent rodents or other small mammals maintain F. tularensis in nature. The main objective of this study was to obtain information about the occurrence of F. tularensis in small mammals in Finland. We snap-trapped 547 wild small mammals representing 11 species at 14 locations around Finland during 6 years and screened them for the presence of F. tularensis DNA using PCR analysis. High copy number of F. tularensis-specific DNA was detected in tissue samples of five field voles ( Microtus agrestis) originating from one location and 2 years. According to DNA sequences of the bacterial 23S ribosomal RNA gene amplified from F. tularensis-infected voles, the infecting agent belongs to the subspecies holarctica. To find out the optimal tissue for tularemia screening in voles, we compared the amounts of F. tularensis DNA in lungs, liver, spleen, and kidney of the infected animals. F. tularensis DNA was detectable in high levels in all four organs except for one animal, whose kidney was F. tularensis DNA-negative. Thus, at least liver, lung, and spleen seem suitable for F. tularensis screening in voles. Thus, liver, lung, and spleen all seem suitable for F. tularensis screening in voles. In conclusion, field voles can be heavily infected with F. tularensis subsp. holarctica and thus potentially serve as the source of infection in humans and other mammals. [ABSTRACT FROM AUTHOR]

Published

2014

18. Metagenomic Evaluation of Bacteria from Voles.

Author

Koskela KA, Kalin-Mänttäri L, Hemmilä H, Smura T, Kinnunen PM, Niemimaa J, Henttonen H, and Nikkari S

Subjects

Animals, Bacteria classification, Finland, Arvicolinae microbiology, Bacteria genetics, Bacteria isolation & purification, Genome, Bacterial, Metagenomics

Abstract

Voles (Arvicolinae, Rodentia) are known carriers of zoonotic bacteria such as Bartonella spp. and Francisella tularensis. However, apart from F. tularensis, the bacterial microbiome of voles has not previously been determined in Finland and rarely elsewhere. Therefore, we studied liver samples from 61 voles using 16S ribosomal RNA gene PCR analysis, followed by Sanger sequencing. Twenty-three of these samples were also studied with tag-encoded pyrosequencing. The samples originated from 21 field voles (Microtus agrestis), 37 tundra voles (Microtus oeconomus), and 3 bank voles (Myodes glareolus). With the more conventional 16S rDNA PCR analysis, 90 (33%) of the recovered 269 sequence types could be identified to genus level, including Bartonella, Francisella, Mycoplasma, Anaplasma, and Acinetobacter in 31, 15, 9, 9, and 9 sequences, respectively. Seventy-five (28%) matched best with sequences of uncultured bacteria, of which 40/75 could be classified to the order Clostridiales and, more specifically, to families Lachnospiraceae and Ruminococcaceae. Pyrosequencing from 23 samples revealed comparable and similar results: clinically relevant bacterial families such as Mycoplasmataceae, Bartonellaceae, Anaplasmataceae, and Francisellaceae were recognized. These analyses revealed significant bacterial diversity in vole livers, consisting of distinct and constant sequence patterns reflecting bacteria found in the intestinal gut, but including some known zoonotic pathogens as well. The molecular bacterial sequence types determined with the two different techniques shared major similarities and verified remarkable congruency between the methods.

Published

2017

19. Phylogeography of Francisella tularensis subspecies holarctica in Finland, 1993-2011.

Author

Sissonen S, Rossow H, Karlsson E, Hemmilä H, Henttonen H, Isomursu M, Kinnunen PM, Pelkola K, Pelkonen S, Tarkka E, Myrtennäs K, Nikkari S, and Forsman M

Subjects

Animals, Bacterial Typing Techniques, DNA, Bacterial, Europe, Finland epidemiology, Francisella tularensis classification, Genome, Bacterial, Genotype, Humans, Phylogeny, Phylogeography, Polymerase Chain Reaction, Polymorphism, Single Nucleotide, Tularemia epidemiology, Francisella tularensis genetics, Francisella tularensis isolation & purification, Genetic Variation, Tularemia microbiology

Abstract

Background: Finland repeatedly reports some of the highest incidences of tularaemia worldwide. To determine genetic diversity of the aetiologic agent of tularaemia, Francisella tularensis, a total of 76 samples from humans (n = 15) and animals (n = 61) were analysed., Methods: We used CanSNPs and canINDEL hydrolysis or TaqMan MGB probes for the analyses, either directly from the clinical tissue samples (n = 21) or from bacterial isolates (n = 55)., Results: The genotypes of the strains were assigned to three previously described basal subspecies holarctica clades. The majority of strains (n = 67) were assigned to B.12, a clade reported to dominate in Scandinavia and Eastern Europe. A single strain was assigned to clade B.4, previously reported from North America, Europe and China. The remaining strains (n = 8) were members of clade B.6. Importantly, new diversity was discovered in clade B.6. We describe two newly designed TaqMan MGB probe assays for this new B.6 subclade B.70, and its previously identified sister clade B.11, a clade dominantly found in Western Europe., Conclusions: The high genetic diversity of F. tularensis subspecies holarctica present in Finland is consistent with previous findings in Sweden. The results suggest a northern and southern division of the B.6 subclade B.10, where B.11 predominates in Western and Central Europe and B.70 is found in Fennoscandia. Further research is required to define whether the vast diversity of genotypes found is related to different habitats or reservoir species, their different postglacial immigration routes to Fennoscandia, or dynamics of the reservoir species.

Published

2015

20. Detection of Francisella tularensis in voles in Finland.

Author

Rossow H, Sissonen S, Koskela KA, Kinnunen PM, Hemmilä H, Niemimaa J, Huitu O, Kuusi M, Vapalahti O, Henttonen H, and Nikkari S

Subjects

Animals, Base Sequence, DNA, Bacterial chemistry, DNA, Bacterial genetics, Female, Finland epidemiology, Francisella tularensis genetics, Geography, Humans, Liver microbiology, Lung microbiology, Male, Molecular Sequence Data, Rodent Diseases epidemiology, Sequence Analysis, DNA veterinary, Species Specificity, Spleen microbiology, Tularemia epidemiology, Tularemia microbiology, Zoonoses, Arvicolinae, Francisella tularensis isolation & purification, Rodent Diseases microbiology, Tularemia veterinary

Abstract

Francisella tularensis is a highly virulent intracellular bacterium causing the zoonotic disease tularemia. It recurrently causes human and animal outbreaks in northern Europe, including Finland. Although F. tularensis infects several mammal species, only rodents and lagomorphs seem to have importance in its ecology. Peak densities of rodent populations may trigger tularemia outbreaks in humans; however, it is still unclear to which extent rodents or other small mammals maintain F. tularensis in nature. The main objective of this study was to obtain information about the occurrence of F. tularensis in small mammals in Finland. We snap-trapped 547 wild small mammals representing 11 species at 14 locations around Finland during 6 years and screened them for the presence of F. tularensis DNA using PCR analysis. High copy number of F. tularensis-specific DNA was detected in tissue samples of five field voles (Microtus agrestis) originating from one location and 2 years. According to DNA sequences of the bacterial 23S ribosomal RNA gene amplified from F. tularensis-infected voles, the infecting agent belongs to the subspecies holarctica. To find out the optimal tissue for tularemia screening in voles, we compared the amounts of F. tularensis DNA in lungs, liver, spleen, and kidney of the infected animals. F. tularensis DNA was detectable in high levels in all four organs except for one animal, whose kidney was F. tularensis DNA-negative. Thus, at least liver, lung, and spleen seem suitable for F. tularensis screening in voles. Thus, liver, lung, and spleen all seem suitable for F. tularensis screening in voles. In conclusion, field voles can be heavily infected with F. tularensis subsp. holarctica and thus potentially serve as the source of infection in humans and other mammals.

Published

2014