Olfactory progenitor cell transplantation into the mammalian inner ear

Patel, Nirmal Praful, School of Medicine, UNSW

January 2006

A practical consideration in the development of cellular therapy technology for the inner ear is the development of an in vitro model for assessing the optimal conditions for successful application of cells. The first part of this thesis describes the adaptation of the cochleovestibular structure harvested from P1 mouse pups for analysis of factors critical for the optimal implantation of stem cells in the inner ear. Results of these studies establish that the c17.2 neural stem cell line can be introduced into the cochleovestibular structure in vitro. Using this model, c17.2 cells demonstrated survival predominantly within the vestibule and basal spiral ganglion regions. Furthermore, the addition of the ototoxin, cisplatin and the neurotrophin, Brain Derived Neurotrophic Growth Factor (BDNF) enhanced the survival and migration/dispersion of c17.2 cells within the cochleovestibular explant. The second part of this thesis examines the hypothesis that olfactory neurosphere (ONS) and progenitor cells harvested from the olfactory epithelium represent a viable source of graft material for potential therapeutic applications in the inner ear. Olfactory epithelium represents a unique source of pluripotent cells that may serve as either homografts or autografts. The feasibility of ONSs to survive and integrate into a mammalian cochlea in vivo was assessed. The ONSs were isolated as a crude fraction from the olfactory epithelium of P1 to P3 day old swiss webster mouse pups, ubiquitously expressing the Green Fluorescent Protein (GFP) marker. The ONSs were microinjected into the cochleae of adult CD1 male mice. Four weeks following their implantation, ONS cells expressing the GFP marker and stained by Nestin were identified in all areas of the cochlea and vestibule, including the spiral ganglion. Robust survival and growth of the implanted ONS and ONS derived cells in the cochlea also included the development of ???tumor-like??? clusters, a phenomenon not observed in control animals implanted with c17.2 neural stem cells. Collectively, the results of this thesis illustrate the potential of olfactory neurosphere and progenitor cells to survive in the inner ear and expose a potential harmful effect of their transplantation.

Labyrinth (Ear) - Therapy

Cellular therapy - Animal models

Olfactory progenitor cell transplantation into the mammalian inner ear

Patel, Nirmal Praful, School of Medicine, UNSW

January 2006

A practical consideration in the development of cellular therapy technology for the inner ear is the development of an in vitro model for assessing the optimal conditions for successful application of cells. The first part of this thesis describes the adaptation of the cochleovestibular structure harvested from P1 mouse pups for analysis of factors critical for the optimal implantation of stem cells in the inner ear. Results of these studies establish that the c17.2 neural stem cell line can be introduced into the cochleovestibular structure in vitro. Using this model, c17.2 cells demonstrated survival predominantly within the vestibule and basal spiral ganglion regions. Furthermore, the addition of the ototoxin, cisplatin and the neurotrophin, Brain Derived Neurotrophic Growth Factor (BDNF) enhanced the survival and migration/dispersion of c17.2 cells within the cochleovestibular explant. The second part of this thesis examines the hypothesis that olfactory neurosphere (ONS) and progenitor cells harvested from the olfactory epithelium represent a viable source of graft material for potential therapeutic applications in the inner ear. Olfactory epithelium represents a unique source of pluripotent cells that may serve as either homografts or autografts. The feasibility of ONSs to survive and integrate into a mammalian cochlea in vivo was assessed. The ONSs were isolated as a crude fraction from the olfactory epithelium of P1 to P3 day old swiss webster mouse pups, ubiquitously expressing the Green Fluorescent Protein (GFP) marker. The ONSs were microinjected into the cochleae of adult CD1 male mice. Four weeks following their implantation, ONS cells expressing the GFP marker and stained by Nestin were identified in all areas of the cochlea and vestibule, including the spiral ganglion. Robust survival and growth of the implanted ONS and ONS derived cells in the cochlea also included the development of ???tumor-like??? clusters, a phenomenon not observed in control animals implanted with c17.2 neural stem cells. Collectively, the results of this thesis illustrate the potential of olfactory neurosphere and progenitor cells to survive in the inner ear and expose a potential harmful effect of their transplantation.

Labyrinth (Ear) - Therapy

Cellular therapy - Animal models

Genetic and epigenetic mechanisms in the aetiology of orofacial clefts / Mecanismos genéticos e epigenéticos na etiologia das fissuras orofaciais

Cruz, Lucas Alvizi

29 September 2017

Craniofacial development is a tightly regulated event that requires expression of many genes at a precise space-temporal specificity. Interference in the regulation of such genes and their pathways is known to lead to abnormal phenotypes affecting the face and cranium. In this manner, regulation of these pathways is further complicated by interaction between genetic and environmental factors such that disturbance to either may result in craniofacial malformation, as orofacial clefts. Despite several at-risk loci have been identified, they do not completely explain the high heritability observed for the orofacial clefts and many questions remain open. For example, concerning the orofacial clefts transcriptome, the gene pathways which may be dysregulated and the affected cellular processes are still poorly understood. Further, if there is gene expression dysregulation in orofacial clefts, the causes leading to that need to be elucidated, such as the investigation of epigenetic factors. Also, since the multifactorial contribution makes environment relevant to this malformation, epigenetic and epigenomic differences in orofacial clefts should clarified. At last, rare syndromic forms of orofacial clefts with still unknown molecular cause and mechanisms should be elucidated in order to better understand craniofacial development and their impact in non-syndromic forms. Therefore, the main objective of this study was to investigate the molecular mechanisms involved in the aetiology of orofacial clefts, which was focused in gene expression and epigenetic analysis in non-syndromic cleft lip and/or palate (NSCL/P) as well as genetic, gene expression, animal modelling and epigenetics in Richieri-Costa-Pereira Syndrome (RCPS), a rare autosomal recessive syndromic form of orofacial cleft. We found significant transcriptome differences in NSCL/P in comparison to controls, revealing the BRCA1-dependent DNA damage repair pathway as compromised in NSCL/P cells leading to DNA damage accumulation. Next, we studied the potential of DNA methylation in those cells and found a slight but significant increase of BRCA1 promoter DNA methylation in NSCL/P cells and a distinct DNA methylation distribution, point to a possible epigenetic contribution in this phenomenon. We also evaluated the contribution of DNA methylation in 8q24.21 region, one of the most replicated regions in NSCL/P Genome-wide association studies and found no significant differences in our sample. Attempting to investigate DNA methylation in NSCL/P in an epigenomic level, we analysed methylomes and found 578 methylation variable positions in NSCL/P, highly enriched in regulatory regions and in relevant gene pathways for craniofacial development as Epithelial-Mesenchymal Transition pathway. We also studied effect of DNA methylation in familial NSCL/P displaying incomplete penentrance and found a significant increase of CDH1 promoter hypermethylation in penetrant cases in comparison to non-penetrants. Finally, by the use of different sequencing strategies and identity-by-descent analysis we mapped the mutation region of RCPS to EIF4A3 5\'UTR/promoter and found a complex structure of expanded repeats in RCPS patients leading to EIF4A3 downregulation. We were also able to validate the phenotypes using an animal modelling strategy in zebrafish. Because those repeats are CG rich, we investigated whether they were submitted to DNA hypermethylation in RCPS patients as a cause for EIF4A3 hypomorphism, however we found no evidence of methylation increase in RCPS. In conclusion, we were able to associate dysregulated pathways to NSCL/P susceptibility and DNA methylation differences to both non-familial and familial NSCLP. Besides, we were able to identify the genetic cause of RCPS, which now can be molecularly diagnosed. Altogether, our results add to the understanding of craniofacial development and the aetiology of orofacial clefts / O desenvolvimento craniofacial é um evento finamente regulado que requer a expressão de muitos genes em uma precisão espaço-temporal específica. A interferência na regulação de tais genes e suas respectivas vias é sabidamente causadora de fenótipos que afetam a face e o crânio. Neste sentido, a regulação destas vias é decorrente da interação entre fatores genéticos e ambientais, de tal forma que a perturbação de quaisquer destes fatores pode resultar em malformações craniofaciais, como as fissuras orofaciais. Apesar dos muitos loci de risco já identificados, estes não explicam completamente a alta herdabilidade observadas nas fissuras orofaciais e muitas questões permanecem em aberto. Por exemplo, em relação ao transcriptoma em fissuras orofaciais, as vias genéticas que podem estar desreguladas, assim como processos celulares afetados em decorrência, são ainda pouco compreendidos. Além disso, se há desregulação na expressão de genes em fissuras orofaciais, as causas que levam a essas diferenças necessitam ser elucidadas, como, por exemplo, por meio da investigação de fatores epigenéticos. Também, uma vez que o componente multifatorial torna a influência do ambiente relevante para esta malformação, diferenças epigenéticas e epigenômicas nas fissuras orofaciais devem ser melhor compreendidas. Por fim, formas raras e sindrômicas de fissuras orofaciais sem elucidação de causa moleculares devem ser estudadas para que melhor se compreenda o desenvolvimento craniofacial e o impacto destes mecanismos moleculares em formas não-sindrômicas. Portanto, nosso objetivo principal neste estudo foi investigar os mecanismos moleculares envolvidos na etiologia das fissuras orofaciais, com o foco na análise de expressão gênica e epigenètica em fissuras de lábio-palatinas não-sindrômicas (FL/P NS) e também o estudo genético, de expressão gênica, modelagem animal e epigenética na Síndrome de Richieri-Costa-Pereira (RCPS), uma forma sindrômica e autossômica recessiva de fissura orofacial. Nós encontramos diferenças significantes no transcriptoma de FL/P NS em comparação com controles, que revelaram o comprometimento da via do BRCA1 no reparo ao dano de DNA e o acúmulo de dano de DNA em células FL/P NS. Em seguida, nós estudamos o potencial da metilação de DNA nestas células e encontramos um pequeno, porém significante, aumento de metilação de DNA no promotor do BRCA1 e uma distribuição diferente de metilação, apontando para uma possível contribuição epigenética na desregulação do gene. Nós também avaliamos a contribuição da metilação de DNA na região 8q24.21, uma das mais associadas às FL/P NS por meio de Genome-wide association studies, porém não encontramos diferenças significantes na nossa amostra. Com o intuito de investigar a metilação de DNA em FL/P NS em uma escala epigenômica, nós analisamos o perfil de metilomas e encontramos 578 sítios diferencialmente metilados nas FL/P NS, altamente enriquecidos em regiões regulatórias e em vias relevantes para o desenvolvimento craniofacial como a via de Transição Epitélio-Mesenquimal. Nós também estudamos o efeito da metilação de DNA em casos famílias de FL/P NS com penetrância incompleta e encontramos um aumento significativo de metilação do promotor do CDH1 nos casos penetrantes em comparação aos não-penetrantes. Por último, por meio de diferentes estratégias de sequenciamento e análise de segregação de haplótipos nós mapeamos a mutação de RCPS na região 5\'UTR/promotor do EIF4A3 e encontramos uma estrutura complexa de expansão de repetições nos pacientes RCPS, ocasionando a diminuição da expressão do EIF4A3. Nós também reproduzimos fenótipos comparáveis aos da RCPS por meio de modelo animal em zebrafish. Uma vez que tais repetições são ricas em CG, nós investigamos se estas poderiam ser submetidas à metilação de DNA em pacientes RCPS como uma causa para a redução dos transcritos do EIF4A3, porém não encontramos evidências de aumento de metilação em RCPS. Em conclusão, nós conseguimos associar vias gênicas desreguladas à susceptibilidade para as FL/P NS e diferenças de metilação de DNA tanto em casos familiais como não-familiais de FL/P NS. Além disso, identificamos a causa genética de RCPS, sendo que a síndrome pode ser agora diagnosticada molecularmente. Em conjunto, nossos resultados adicionam ao conhecimento do desenvolvimento craniofacial e na etiologia das fissuras orofaciais

Cellular and animal models

Cleft lip and/or palate

Craniofacial development

Desenvolvimento craniofacial

Epigenoma

Epigenomics

Fissura de lábio e/ou palato

Homozygosity mapping

Mapeamento por homozigose

Modelos celulares e animais

Transcriptoma

Transcriptomics

Genetic and epigenetic mechanisms in the aetiology of orofacial clefts / Mecanismos genéticos e epigenéticos na etiologia das fissuras orofaciais

Lucas Alvizi Cruz

29 September 2017

Craniofacial development is a tightly regulated event that requires expression of many genes at a precise space-temporal specificity. Interference in the regulation of such genes and their pathways is known to lead to abnormal phenotypes affecting the face and cranium. In this manner, regulation of these pathways is further complicated by interaction between genetic and environmental factors such that disturbance to either may result in craniofacial malformation, as orofacial clefts. Despite several at-risk loci have been identified, they do not completely explain the high heritability observed for the orofacial clefts and many questions remain open. For example, concerning the orofacial clefts transcriptome, the gene pathways which may be dysregulated and the affected cellular processes are still poorly understood. Further, if there is gene expression dysregulation in orofacial clefts, the causes leading to that need to be elucidated, such as the investigation of epigenetic factors. Also, since the multifactorial contribution makes environment relevant to this malformation, epigenetic and epigenomic differences in orofacial clefts should clarified. At last, rare syndromic forms of orofacial clefts with still unknown molecular cause and mechanisms should be elucidated in order to better understand craniofacial development and their impact in non-syndromic forms. Therefore, the main objective of this study was to investigate the molecular mechanisms involved in the aetiology of orofacial clefts, which was focused in gene expression and epigenetic analysis in non-syndromic cleft lip and/or palate (NSCL/P) as well as genetic, gene expression, animal modelling and epigenetics in Richieri-Costa-Pereira Syndrome (RCPS), a rare autosomal recessive syndromic form of orofacial cleft. We found significant transcriptome differences in NSCL/P in comparison to controls, revealing the BRCA1-dependent DNA damage repair pathway as compromised in NSCL/P cells leading to DNA damage accumulation. Next, we studied the potential of DNA methylation in those cells and found a slight but significant increase of BRCA1 promoter DNA methylation in NSCL/P cells and a distinct DNA methylation distribution, point to a possible epigenetic contribution in this phenomenon. We also evaluated the contribution of DNA methylation in 8q24.21 region, one of the most replicated regions in NSCL/P Genome-wide association studies and found no significant differences in our sample. Attempting to investigate DNA methylation in NSCL/P in an epigenomic level, we analysed methylomes and found 578 methylation variable positions in NSCL/P, highly enriched in regulatory regions and in relevant gene pathways for craniofacial development as Epithelial-Mesenchymal Transition pathway. We also studied effect of DNA methylation in familial NSCL/P displaying incomplete penentrance and found a significant increase of CDH1 promoter hypermethylation in penetrant cases in comparison to non-penetrants. Finally, by the use of different sequencing strategies and identity-by-descent analysis we mapped the mutation region of RCPS to EIF4A3 5\'UTR/promoter and found a complex structure of expanded repeats in RCPS patients leading to EIF4A3 downregulation. We were also able to validate the phenotypes using an animal modelling strategy in zebrafish. Because those repeats are CG rich, we investigated whether they were submitted to DNA hypermethylation in RCPS patients as a cause for EIF4A3 hypomorphism, however we found no evidence of methylation increase in RCPS. In conclusion, we were able to associate dysregulated pathways to NSCL/P susceptibility and DNA methylation differences to both non-familial and familial NSCLP. Besides, we were able to identify the genetic cause of RCPS, which now can be molecularly diagnosed. Altogether, our results add to the understanding of craniofacial development and the aetiology of orofacial clefts / O desenvolvimento craniofacial é um evento finamente regulado que requer a expressão de muitos genes em uma precisão espaço-temporal específica. A interferência na regulação de tais genes e suas respectivas vias é sabidamente causadora de fenótipos que afetam a face e o crânio. Neste sentido, a regulação destas vias é decorrente da interação entre fatores genéticos e ambientais, de tal forma que a perturbação de quaisquer destes fatores pode resultar em malformações craniofaciais, como as fissuras orofaciais. Apesar dos muitos loci de risco já identificados, estes não explicam completamente a alta herdabilidade observadas nas fissuras orofaciais e muitas questões permanecem em aberto. Por exemplo, em relação ao transcriptoma em fissuras orofaciais, as vias genéticas que podem estar desreguladas, assim como processos celulares afetados em decorrência, são ainda pouco compreendidos. Além disso, se há desregulação na expressão de genes em fissuras orofaciais, as causas que levam a essas diferenças necessitam ser elucidadas, como, por exemplo, por meio da investigação de fatores epigenéticos. Também, uma vez que o componente multifatorial torna a influência do ambiente relevante para esta malformação, diferenças epigenéticas e epigenômicas nas fissuras orofaciais devem ser melhor compreendidas. Por fim, formas raras e sindrômicas de fissuras orofaciais sem elucidação de causa moleculares devem ser estudadas para que melhor se compreenda o desenvolvimento craniofacial e o impacto destes mecanismos moleculares em formas não-sindrômicas. Portanto, nosso objetivo principal neste estudo foi investigar os mecanismos moleculares envolvidos na etiologia das fissuras orofaciais, com o foco na análise de expressão gênica e epigenètica em fissuras de lábio-palatinas não-sindrômicas (FL/P NS) e também o estudo genético, de expressão gênica, modelagem animal e epigenética na Síndrome de Richieri-Costa-Pereira (RCPS), uma forma sindrômica e autossômica recessiva de fissura orofacial. Nós encontramos diferenças significantes no transcriptoma de FL/P NS em comparação com controles, que revelaram o comprometimento da via do BRCA1 no reparo ao dano de DNA e o acúmulo de dano de DNA em células FL/P NS. Em seguida, nós estudamos o potencial da metilação de DNA nestas células e encontramos um pequeno, porém significante, aumento de metilação de DNA no promotor do BRCA1 e uma distribuição diferente de metilação, apontando para uma possível contribuição epigenética na desregulação do gene. Nós também avaliamos a contribuição da metilação de DNA na região 8q24.21, uma das mais associadas às FL/P NS por meio de Genome-wide association studies, porém não encontramos diferenças significantes na nossa amostra. Com o intuito de investigar a metilação de DNA em FL/P NS em uma escala epigenômica, nós analisamos o perfil de metilomas e encontramos 578 sítios diferencialmente metilados nas FL/P NS, altamente enriquecidos em regiões regulatórias e em vias relevantes para o desenvolvimento craniofacial como a via de Transição Epitélio-Mesenquimal. Nós também estudamos o efeito da metilação de DNA em casos famílias de FL/P NS com penetrância incompleta e encontramos um aumento significativo de metilação do promotor do CDH1 nos casos penetrantes em comparação aos não-penetrantes. Por último, por meio de diferentes estratégias de sequenciamento e análise de segregação de haplótipos nós mapeamos a mutação de RCPS na região 5\'UTR/promotor do EIF4A3 e encontramos uma estrutura complexa de expansão de repetições nos pacientes RCPS, ocasionando a diminuição da expressão do EIF4A3. Nós também reproduzimos fenótipos comparáveis aos da RCPS por meio de modelo animal em zebrafish. Uma vez que tais repetições são ricas em CG, nós investigamos se estas poderiam ser submetidas à metilação de DNA em pacientes RCPS como uma causa para a redução dos transcritos do EIF4A3, porém não encontramos evidências de aumento de metilação em RCPS. Em conclusão, nós conseguimos associar vias gênicas desreguladas à susceptibilidade para as FL/P NS e diferenças de metilação de DNA tanto em casos familiais como não-familiais de FL/P NS. Além disso, identificamos a causa genética de RCPS, sendo que a síndrome pode ser agora diagnosticada molecularmente. Em conjunto, nossos resultados adicionam ao conhecimento do desenvolvimento craniofacial e na etiologia das fissuras orofaciais

Desenvolvimento craniofacial

Epigenoma

Fissura de lábio e/ou palato

Mapeamento por homozigose

Modelos celulares e animais

Transcriptoma

Cellular and animal models

Cleft lip and/or palate

Craniofacial development

Epigenomics

Homozygosity mapping

Transcriptomics

Identification de nouvelles cibles thérapeutiques dans la dysfonction primaire du greffon suite à une transplantation pulmonaire

Landry, Caroline

08 1900

Introduction : La dysfonction primaire du greffon (DPG) post-transplantation pulmonaire est la principale cause de décès en phase péri-opératoire. Sa physiopathologie n’est pas encore totalement élucidée mais les lésions d’Ischémie/Reperfusion (I/R) pourraient constituer un facteur important de son développement. L’I/R et la DPG sont caractérisées par des dommages de l’endothélium vasculaire et de l’épithélium alvéolaire, un œdème pulmonaire et une réaction inflammatoire exacerbée. La résorption de l’œdème dépend du rétablissement de l’intégrité fonctionnelle alvéolaire, dont la capacité à réabsorber les ions Na+ (via les canaux ENaC), et secondairement le liquide par les cellules alvéolaires. Nous avons émis l’hypothèse que la dysfonction épithéliale alvéolaire, causée par l’I/R, présente dans les greffons donneurs (GD), jouerait un rôle clef dans le développement de la DPG chez les receveurs. Notre but était d’identifier de biomarqueurs, associés à la dysfonction épithéliale des GD et au développement de DPG chez les receveurs. Méthodes : L’impact d’un protocole mimant une I/R a d’abord été évalué sur des cultures primaires de cellules alvéolaires de rats. Puis, nous avons étudié l’impact de l’I/R in vivo grâce à des modèles de stress inflammatoire par infusion de LPS ou transplantation unilatérale chez le porc. Finalement, des biopsies de tissus de GD ont été recueillies durant les transplantations pulmonaires. Après détermination du grade de DPG chez les receveurs, nous avons étudié les facteurs et les altérations alvéolaires associés. Résultats : Une baisse d’expression des protéines de jonctions serrées (ZO-1), des canaux ioniques ENaC et CFTR ainsi qu’une réduction de la résistance transépithéliale et de la capacité de réparation suite aux lésions ont été observées suite au protocole mimant l’I/R dans le modèle de cultures primaires de cellules alvéolaires. Un traitement avec un activateur du canal K+ KvLQT1 (R L3) a permis d’améliorer la vitesse de réparation, l’intégrité de la barrière épithéliale et l’expression d’ENaC et CFTR. Dans nos modèles animaux, nous avons observé une réponse pro-inflammatoire et une altération des protéines ZO-1, ENaC et CFTR. Nos données préliminaires indiquent aussi une infiltration inflammatoire et une baisse d’ENaC, CFTR et ZO-1, déjà présentes dans les GD ayant subits une I prolongée, chez les receveurs ayant ensuite développés une DPG. Conclusion : Nos résultats soutiennent notre hypothèse du développement d’une dysfonction épithéliale alvéolaire, caractérisée par une altération de biomarqueurs de fonctionnalité et d’intégrité (ENaC, CFTR et ZO-1), en lien avec l’I/R et la DPG. / Background: Primary graft dysfunction (PGD) after lung transplantation is the first cause of death in the perioperative phase. The PGD pathophysiology is not fully elucidated, but Ischemia/Reperfusion (I/R) injury might be an important factor. I/R and PGD both feature endothelial/ epithelial damage, lung edema and inflammation. Edema resorption then depends on the restoration of the alveolar functional integrity, especially the ability of alveolar epithelial cells to reabsorb Na+ (through ENaC channels) and fluid. We hypothesized that alveolar epithelial dysfunction (related to I/R), observed within donor grafts, then plays a key role in the development of PGD in lung recipients. Our goal was to identify novel biomarkers, associated with epithelial dysfunction within donor’s grafts, and then PGD development in recipients. Methods: The impact of a protocol mimicking hypothermic ischemia and reperfusion was first tested on primary rat alveolar epithelial cell cultures. Then, the impact of I/R was studied in vivo using models of inflammatory stress induced by LPS infusion or after unilateral transplantation in pigs. Finally, lung biopsies from donor grafts were collected during lung transplantations. After defining PGD scores within the recipients, associated factors and alveolar alterations were finally analyzed. Results: In primary cell cultures, the protocol mimicking hypothermic I/R induced a decrease in tight junction proteins (ZO-1), transepithelial resistance, wound repair capacity as well as ENaC and CFTR channel expression. Treatment with a KvLQT1 K+ channel activator (R-L3) accelerated the repair rates and enhanced barrier integrity (ZO-1 staining) as well as ENaC and CFTR protein expressions. In the porcine models, an exacerbated inflammatory response was observed along with alveolar damage, lung edema and decreased ZO-1, ENaC and CFTR expressions. Our preliminary data using human samples collected during lung transplantations also indicate an inflammatory response and reduced ENaC, CFTR and ZO-1 expressions, already observed within lung grafts, submitted to longer cold ischemia duration, among lung recipients then developing a PGD. Conclusion: Altogether these data support our hypothesis of an alveolar epithelial dysfunction, featuring an alteration of functionality and barrier integrity biomarkers (ENaC, CFTR and ZO-1), associated with I/R and DPG.

Transplantation pulmonaire

Dysfonction primaire du greffon

Ischémie/Reperfusion

Épithélium alvéolaire

Dommages

Intégrité

Canaux ioniques

Inflammation

Modèles cellulaires et animaux

Recherche translationnelle

Lung transplantation

Primary graft dysfunction

Ischemia/Reperfusion

Alveolar epithelium

Injury

Integrity

Ionic channels

Cellular and animal models

Translational research