Homotopy Characterization of ANR Function Spaces

Let Y be an absolute neighbourhood retract (ANR) for the class of metric spaces and let X be a topological space. Let YX denote the space of continuous maps from X to Y equipped with the compact open topology. We show that if X is a compactly generated Tychonoff space and Y is not discrete, then YX is an ANR for metric spaces if and only if X is hemicompact and YX has the homotopy type of a CW complex

Morphological and Functional Correlations in Acute Central Serous Chorioretinopathy

Purpose: We evaluate morphological and functional correlations in patients with acute central serous chorioretinopathy (CSC). Methods: A prospective study was conducted on 50 patients with an acute CSC episode lasting less than 3 months. At baseline, assessments included optical coherence tomography (OCT), best-corrected visual acuity (BCVA), contrast sensitivity (CS), microperimetry (MP), and multifocal electroretinography (mfERG). A correlation analysis between OCT morphological parameters (maximal subretinal fluid height (SRF), central retinal thickness (CRT), and macular volume (MV)) and functional parameters was conducted on the affected eye for each patient. Results: Among the morphological parameters, SRF showed the strongest correlations with functional parameters (r absolute value range = 0.10–0.70). Weak correlations were observed between BCVA and morphological parameters (r absolute value range = 0.14–0.26). Average retinal sensitivity (MP-A) was the functional parameter displaying the most robust negative correlation with morphological parameters (r absolute value range = 0.61–0.70). In contrast, average contrast sensitivity (CS-A) and mfERG average amplitude density in the first (mfERG-A1) and second (mfERG-A2) ring showed weak to moderate (r absolute value range = 0.35–0.56) yet statistically significantly nonzero correlations. Conclusions: SRF and CRT could serve as the most representative morphological proxies for visual function deficit in acute CSC patients. Retinal sensitivity, as measured by MP, may be superior to BCVA in clinical research studies or when an in-depth visual function evaluation is needed

Rational Reidemeister trace of an outer automorphism of finite order

Let $H$ be a group of type $FP$ over the rationals and let $phicolon Hto H$ be an automorphism whose class in ${rm Out}(H)$ has finite order and such that the Lefschetz number of some iterate $phi^i$ is nonzero. We show that under a suitable Bass conjecture assumption, this iterate $phi^i$ is conjugate to a finite order automorphism, and the intersection of the fixed point set of $phi$ with the center of $H$ is of bounded exponent. In the torsion-free case it follows that the center of the HNN extension $langle H,t,vert,forall hin H:,tht^{-1}=phi(h)rangle$ is infinite cyclic. These results are related to Geoghegan and Nicas\u27 first order Euler characteristic of a group $G$ with a finite Eilenberg-MacLane complexthis is a morphism $chi_1(G)$ from the center of $G$ to $H_1(Gk)$ where $k$ is a ring of coefficients. We give a complete determination of $chi_1(G)$ with rational coefficients

Homotopy Characterization of ANR Function Spaces

Let Y be an absolute neighbourhood retract (ANR) for the class of metric spaces and let X be a topological space. Let YX denote the space of continuous maps from X to Y equipped with the compact open topology. We show that if X is a compactly generated Tychonoff space and Y is not discrete, then YX is an ANR for metric spaces if and only if X is hemicompact and YX has the homotopy type of a CW complex

Genska terapija v onkologiji, prvi razvojni koraki v Sloveniji

Gene therapy is also attracting interest in oncology. Probably the most interesting approach is immunostimulation. Plasmid DNA can be constructed, which is coding for a specific immunostimulatory molecule, which is then delivered into the cells, either in tumour or normal tissue. The transfected tissue then becomes the producer of the molecules encoded in the plasmid. The product is then released from the cells, either locally or systemically into the bloodstream. Since plasmids have hampered transport through the plasma membrane, delivery systems are needed that are either viral or nonviral. In our studies we predominantly use the non-viral transfection system, based on electroporation of the cells.Interleukin 12 (IL-12) is a cytokine with well-known anti-tumour and anti-angiogenic function. Therefore, in the SmartGene.si project we wanted to construct a plasmid DNA which is coding for IL-12 (plasmid phIL12), and perform all the necessary testing and prepare the documentation for its clinical testing in the treatment of skin tumours. The SmartGene.si consortium comprises partners from academia and industry. In the project it was necessary to prepare the plasmid according to the European Medicinal Agency (EMA) recommendations. For the application for the study approval submitted to the Agency for Medical Products and Medical Devices of the Republic of Slovenia (JAZMP), it was necessary to perform pharmacological, pharmacokinetic, and efficiency testing of phIL12. Thereafter, we had to develop the process and the facility, and prepare the drug.During the last three years, we have achieved all the goals and obtained the approval of the JAZMP for clinical testing of the product phIL12 in humans. We also obtained the approval of the National Ethics Committee. Currently, we are testing phIL-12 in a Phase I clinical protocol on head and neck skin tumours, with the aim to test the safety and feasibility of intratumoral gene electrotransfer of the plasmid phIL12. Another goal of the study is to determine a suitable dose of plasmid that could be used in future studies as adjuvant treatment to ablative therapies such as radiotherapy or electrochemotherapy.Genska terapija postaja čedalje bolj zanimiva tudi v onkologiji. Med aplikacijami je morda najzanimivejša imunostimulacija. Pripravimo lahko plazmidno DNA, ki nosi zapis za različne imunostimulatorne molekule, ki jih vnesemo v celice tumorjev ali normalnih tkiv. Ta tkiva postanejo proizvajalci teh molekul, ki lahko delujejo lokalno ali pa se izločajo tudi sistemsko v krvni obtok. Ker plazmidna DNA ne prehaja celične membrane, so potrebni dostavni sistemi, virusni ali nevirusni. V naših študijah uporabljamo predvsem nevirusni dostavni sistem – elektroporacijo.Interlevkin 12 (IL-12) je eden od zanimivih citokinov, za katerega je znano protitumorsko delovanje s spodbujanjem imunskega odziva in antiangiogenim delovanjem. Namen projekta SmartGene.si je bil pripraviti plazmid z zapisom za interlevkin 12 (plazmid phIL12) in pripraviti vse potrebno za njegovo klinično testiranje za zdravljenje kožnih tumorjev. V konzorciju smo združili moči s partnerji z akademskega in industrijskega področja. Treba je bilo pripraviti plazmid za uporabo v humani onkologiji po zahtevah Evropske agencije za zdravila (EMA). Za prijavo klinične študije na Javno agencijo za zdravila in medicinske pripomočke (JAZMP) smo morali izvesti tudi vse neklinične raziskave o varnosti in učinkovitosti zdravila. Nato je bilo treba razviti postopek priprave zdravila, zagotoviti primerne prostore za pripravo in izvedbo postopka priprave zdravila.V treh letih smo dosegli vse te zastavljene cilje in dobili dovoljenje za izvajanje klinične študije na kožnih tumorjih, ki ga je izdala JAZMP na osnovi pozitivnega mnenja Komisije Republike Slovenije za medicinsko etiko. Zdaj poteka klinična študija faze I preizkušanja plazmida phIL12 na kožnih tumorjih glave in vratu z namenom preveriti varnost in sprejemljivost genskega elektroprenosa plazmida v tumorje. Cilj študije je prav tako določiti primeren odmerek zdravila, ki bi ga v nadaljnji klinični študiji uporabili kot adjuvantno zdravljenje k ablativnim terapijam, kot sta radioterapija ali elektrokemoterapija

Gene therapy in oncology, first steps of development in Slovenia

Genska terapija postaja čedalje bolj zanimiva tudi v onkologiji. Med aplikacijami je morda najzanimivejša imunostimulacija. Pripravimo lahko plazmidno DNA, ki nosi zapis za različne imunostimulatorne molekule, ki jih vnesemo v celice tumorjev ali normalnih tkiv. Ta tkiva postanejo proizvajalci teh molekul, ki lahko delujejo lokalno ali pa se izločajo tudi sistemsko v krvni obtok. Ker plazmidna DNA ne prehaja celične membrane, so potrebni dostavni sistemi, virusni ali nevirusni. V naših študijah uporabljamo predvsem nevirusni dostavni sistem – elektroporacijo. Interlevkin 12 (IL-12) je eden od zanimivih citokinov, za katerega je znano protitumorsko delovanje s spodbujanjem imunskega odziva in antiangiogenim delovanjem. Namen projekta SmartGene.si je bil pripraviti plazmid z zapisom za interlevkin 12 (plazmid phIL12) in pripraviti vse potrebno za njegovo klinično testiranje za zdravljenje kožnih tumorjev. V konzorciju smo združili moči s partnerji z akademskega in industrijskega področja. Treba je bilo pripraviti plazmid za uporabo v humani onkologiji po zahtevah Evropske agencije za zdravila (EMA). Za prijavo klinične študije na Javno agencijo za zdravila in medicinske pripomočke (JAZMP) smo morali izvesti tudi vse neklinične raziskave o varnosti in učinkovitosti zdravila. Nato je bilo treba razviti postopek priprave zdravila, zagotoviti primerne prostore za pripravo in izvedbo postopka priprave zdravila. V treh letih smo dosegli vse te zastavljene cilje in dobili dovoljenje za izvajanje klinične študije na kožnih tumorjih, ki ga je izdala JAZMP na osnovi pozitivnega mnenja Komisije Republike Slovenije za medicinsko etiko. Zdaj poteka klinična študija faze I preizkušanja plazmida phIL12 na kožnih tumorjih glave in vratu z namenom preveriti varnost in sprejemljivost genskega elektroprenosa plazmida v tumorje. Cilj študije je prav tako določiti primeren odmerek zdravila, ki bi ga v nadaljnji klinični študiji uporabili kot adjuvantno zdravljenje k ablativnim terapijam, kot sta radioterapija ali elektrokemoterapija.Gene therapy is also attracting interest in oncology. Probably the most interesting approach is immunostimulation. Plasmid DNA can be constructed, which is coding for a specific immunostimulatory molecule, which is then delivered into the cells, either in tumour or normal tissue. The transfected tissue then becomes the producer of the molecules encoded in the plasmid. The product is then released from the cells, either locally or systemically into the bloodstream. Since plasmids have hampered transport through the plasma membrane, delivery systems are needed that are either viral or nonviral. In our studies we predominantly use the non-viral transfection system, based on electroporation of the cells. Interleukin 12 (IL-12) is a cytokine with well-known anti-tumour and anti-angiogenic function. Therefore, in the SmartGene.si project we wanted to construct a plasmid DNA which is coding for IL-12 (plasmid phIL12), and perform all the necessary testing and prepare the documentation for its clinical testing in the treatment of skin tumours. The SmartGene.si consortium comprises partners from academia and industry. In the project it was necessary to prepare the plasmid according to the European Medicinal Agency (EMA) recommendations. For the application for the study approval submitted to the Agency for Medical Products and Medical Devices of the Republic of Slovenia (JAZMP), it was necessary to perform pharmacological, pharmacokinetic, and efficiency testing of phIL12. Thereafter, we had to develop the process and the facility, and prepare the drug. During the last three years, we have achieved all the goals and obtained the approval of the JAZMP for clinical testing of the product phIL12 in humans. We also obtained the approval of the National Ethics Committee. Currently, we are testing phIL-12 in a Phase I clinical protocol on head and neck skin tumours, with the aim to test the safety and feasibility of intratumoral gene electrotransfer of the plasmid phIL12. Another goal of the study is to determine a suitable dose of plasmid that could be used in future studies as adjuvant treatment to ablative therapies such as radiotherapy or electrochemotherapy