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2. Gender disparities in patients undergoing extracorporeal cardiopulmonary resuscitation

Author

Springer, A., primary, Dreher, A., additional, Reimers, J., additional, Kaiser, L., additional, Bahlmann, E., additional, van der Schalk, H., additional, Wohlmuth, P., additional, Gessler, N., additional, Hassan, K., additional, Wietz, J., additional, Bein, B., additional, Spangenberg, T., additional, Willems, S., additional, Hakmi, S., additional, and Tigges, E., additional

Published
2024
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5. Mechanism of praziquantel action at a parasitic flatworm ion channel

Author

Friedrich L, Jonathan S. Marchant, Nawal A. Yahya, Sang-Kyu Park, Evgeny G. Chulkov, Spangenberg T, Claudia M. Rohr, Rippmann F, and Maillard D

Subjects
Flatworm, biology, Fasciola, Chemistry, Schistosomiasis, Liver fluke, Pharmacology, biology.organism_classification, medicine.disease, Praziquantel, Transient receptor potential channel, medicine, Single amino acid, Ion channel, medicine.drug
Abstract

Praziquantel (PZQ) is an essential medicine for treating parasitic flatworm infections such as schistosomiasis, which afflicts over 250 million people. However, PZQ is not universally effective, lacking activity against the liver fluke Fasciola. The reason for this insensitivity is unclear, as the mechanism of PZQ action is unknown. Here, we show PZQ activates a transient receptor potential melastatin ion channel (TRPMPZQ) in schistosomes by engaging a hydrophobic ligand binding pocket within the voltage-sensor like domain to cause Ca2+ entry and worm paralysis. PZQ activates TRPMPZQ homologues in other PZQ-sensitive flukes, but not Fasciola. However, a single amino acid change in the Fasciola TRPMPZQ binding pocket, to mimic schistosome TRPMPZQ, confers PZQ sensitivity. After decades of clinical use, the basis of PZQ action at a druggable TRP channel is resolved.

Published
2021
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7. Setting Our Sights on Infectious Diseases

Author

De Rycker, M., Horn, D., Aldridge, B., Amewu, R.K., Barry, C.E., Buckner, F.S., Cook, S., Ferguson, M.A.J., Gobeau, N., Herrmann, J., Herrling, P., Hope, W., Keiser, J., Lafuente-Monasterio, M.J., Leeson, P.D., Leroy, D., Manjunatha, U.H., McCarthy, J., Miles, T.J., Mizrahi, V., Moshynets, O., Niles, J., Overington, J.P., Pottage, J., Rao, S.P.S., Read, K.D., Ribeiro, I., Silver, L.L., Southern, J., Spangenberg, T., Sundar, S., Taylor, C., Van Voorhis, W., White, N.J., Wyllie, S., Wyatt, P.G., Gilbert, I.H., De Rycker, M., Horn, D., Aldridge, B., Amewu, R.K., Barry, C.E., Buckner, F.S., Cook, S., Ferguson, M.A.J., Gobeau, N., Herrmann, J., Herrling, P., Hope, W., Keiser, J., Lafuente-Monasterio, M.J., Leeson, P.D., Leroy, D., Manjunatha, U.H., McCarthy, J., Miles, T.J., Mizrahi, V., Moshynets, O., Niles, J., Overington, J.P., Pottage, J., Rao, S.P.S., Read, K.D., Ribeiro, I., Silver, L.L., Southern, J., Spangenberg, T., Sundar, S., Taylor, C., Van Voorhis, W., White, N.J., Wyllie, S., Wyatt, P.G., and Gilbert, I.H.

Abstract

In May 2019, the Wellcome Centre for Anti-Infectives Research (WCAIR) at the University of Dundee, UK, held an international conference with the aim of discussing some key questions around discovering new medicines for infectious diseases and a particular focus on diseases affecting Low and Middle Income Countries. There is an urgent need for new drugs to treat most infectious diseases. We were keen to see if there were lessons that we could learn across different disease areas and between the preclinical and clinical phases with the aim of exploring how we can improve and speed up the drug discovery, translational, and clinical development processes. We started with an introductory session on the current situation and then worked backward from clinical development to combination therapy, pharmacokinetic/pharmacodynamic (PK/PD) studies, drug discovery pathways, and new starting points and targets. This Viewpoint aims to capture some of the learnings.

Published
2020

8. Setting Our Sights on Infectious Diseases

Author

De Rycker, M, Horn, D, Aldridge, B, Amewu, RK, Barry, CE, Buckner, FS, Cook, S, Ferguson, MAJ, Gobeau, N, Herrmann, J, Herding, P, Hope, W, Keiser, J, Lafuente-Monasterio, MJ, Leeson, PD, Leroy, D, Manjunatha, UH, McCarthy, J, Miles, TJ, Mizrahi, V, Moshynets, O, Niles, J, Overington, JP, Pottage, J, Rao, SPS, Read, KD, Ribeiro, I, Silver, LL, Southern, J, Spangenberg, T, Sundar, S, Taylor, C, Van Voorhis, W, White, NJ, Wyllie, S, Wyatt, PG, Gilbert, IH, De Rycker, M, Horn, D, Aldridge, B, Amewu, RK, Barry, CE, Buckner, FS, Cook, S, Ferguson, MAJ, Gobeau, N, Herrmann, J, Herding, P, Hope, W, Keiser, J, Lafuente-Monasterio, MJ, Leeson, PD, Leroy, D, Manjunatha, UH, McCarthy, J, Miles, TJ, Mizrahi, V, Moshynets, O, Niles, J, Overington, JP, Pottage, J, Rao, SPS, Read, KD, Ribeiro, I, Silver, LL, Southern, J, Spangenberg, T, Sundar, S, Taylor, C, Van Voorhis, W, White, NJ, Wyllie, S, Wyatt, PG, and Gilbert, IH

Abstract

In May 2019, the Wellcome Centre for Anti-Infectives Research (WCAIR) at the University of Dundee, UK, held an international conference with the aim of discussing some key questions around discovering new medicines for infectious diseases and a particular focus on diseases affecting Low and Middle Income Countries. There is an urgent need for new drugs to treat most infectious diseases. We were keen to see if there were lessons that we could learn across different disease areas and between the preclinical and clinical phases with the aim of exploring how we can improve and speed up the drug discovery, translational, and clinical development processes. We started with an introductory session on the current situation and then worked backward from clinical development to combination therapy, pharmacokinetic/pharmacodynamic (PK/PD) studies, drug discovery pathways, and new starting points and targets. This Viewpoint aims to capture some of the learnings.

Published
2020

9. Abstracts of the Eighth EDCTP Forum, 6-9 November 2016.

Author

Makanga, M, Beattie, P, Breugelmans, G, Nyirenda, T, Bockarie, M, Tanner, M, Volmink, J, Hankins, C, Walzl, G, Chegou, N, Malherbe, S, Hatherill, M, Scriba, TJ, Zak, DE, Barry, CE, Kaufmann, SHE, Noor, A, Strub-Wourgaft, N, Phillips, P, Munguambe, K, Ravinetto, R, Tinto, H, Diro, E, Mahendrahata, Y, Okebe, J, Rijal, S, Garcia, C, Sundar, S, Ndayisaba, G, Sopheak, T, Ngoduc, T, Van Loen, H, Jacobs, J, D'Alessandro, U, Boelaert, M, Buvé, A, Kamalo, P, Manda-Taylor, L, Rennie, S, Mokgatla, B, Bahati, Ijsselmuiden, C, Afolabi, M, Mcgrath, N, Kampmann, B, Imoukhuede, E, Alexander, N, Larson, H, Chandramohan, D, Bojang, K, Kasaro, MP, Muluka, B, Kaunda, K, Morse, J, Westfall, A, Kapata, N, Kruuner, A, Henostroza, G, Reid, S, Alabi, A, Foguim, F, Sankarganesh, J, Bruske, E, Mfoumbi, A, Mevyann, C, Adegnika, A, Lell, B, Kranzer, K, Kremsner, P, Grobusch, M, Sabiiti, W, Ntinginya, N, Kuchaka, D, Azam, K, Kampira, E, Mtafya, B, Bowness, R, Bhatt, N, Davies, G, Kibiki, G, Gillespie, S, Lejon, V, Ilboudo, H, Mumba, D, Camara, M, Kaba, D, Lumbala, C, Fèvre, E, Jamonneau, V, Bucheton, B, Büscher, P, Chisenga, C, Sinkala, E, Chilengi, R, Chitundu, H, Zyambo, Z, Wandeler, G, Vinikoor, M, Emilie, D, Camara, O, Mathurin, K, Guiguigbaza-Kossigan, D, Philippe, B, Regassa, F, Hassane, S, Bienvenu, SM, Fabrice, C, Ouédraogo, E, Kouakou, L, Owusu, M, Mensah, E, Enimil, A, Mutocheluh, M, Ndongo, FA, Tejiokem, MC, Texier, G, Penda, C, Ndiang, S, Ndongo, J-A, Guemkam, G, Sofeu, CL, Afumbom, K, Faye, A, Msellati, P, Warszawski, J, Vos, A, Devillé, W, Barth, R, Klipstein-Grobusch, K, Tempelman, H, Venter, F, Coutinho, R, Grobbee, D, Ssemwanga, D, Lyagoba, F, Magambo, B, Kapaata, A, Kirangwa, J, Nannyonjo, M, Nassolo, F, Nsubuga, R, Yebra, G, Brown, A, Kaleebu, P, Nylén, H, Habtewold, A, Makonnen, E, Yimer, G, Burhenne, J, Diczfalusy, U, Aklillu, E, Steele, D, Walker, R, Simuyandi, M, Beres, L, Bosomprah, S, Ansumana, R, Taitt, C, Lamin, JM, Jacobsen, KH, Mulvaney, SP, Leski, T, Bangura, U, Stenger, D, De Vries, S, Zinsou, FJ, Honkpehedji, J, Dejon, JC, Loembe, MM, Bache, B, Pakker, N, Van Leeuwen, R, Hounkpatin, AB, Yazdanbakhsh, M, Bethony, J, Hotez, P, Diemert, D, Bache, BE, Fernandes, JF, Obiang, RM, Kabwende, AL, Grobusch, MP, Krishna, S, Kremsner, PG, Todagbe, AS, Nambozi, M, Kabuya, J-B, Hachizovu, S, Mwakazanga, D, Kasongo, W, Buyze, J, Mulenga, M, Geertruyden, J-P, Gitaka, J, Chan, C, Kongere, J, Kagaya, W, Kaneko, A, Kabore, N, Barry, N, Kabre, Z, Werme, K, Fofana, A, Compaore, D, Nikiema, F, Some, F, Djimde, A, Zongo, I, Ouedraogo, B, Kone, A, Sagara, I, Björkman, A, Gil, JP, Nchinda, G, Bopda, A, Nji, N, Ambada, G, Ngu, L, Tchadji, J, Sake, C, Magagoum, S, Njambe, GD, Lisom, A, Park, CG, Tait, D, Sibusiso, H, Manda, O, Croucher, K, Van Der Westhuizen, A, Mshanga, I, Levin, J, Nanvubya, A, Kibengo, F, Jaoko, W, Pala, P, Perreau, M, Namuniina, A, Kitandwe, P, Tapia, G, Serwanga, J, Yates, N, Fast, P, Mayer, B, Montefiori, D, Tomaras, G, Robb, M, Lee, C, Wagner, R, Sanders, E, Kilembe, W, Kiwanuka, N, Gilmour, J, Kuipers, H, Vooij, D, Chinyenze, K, Priddy, F, Ding, S, Hanke, T, Pantaleo, G, Ngasala, B, Jovel, I, Malmberg, M, Mmbando, B, Premji, Z, Mårtensson, A, Mwaiswelo, R, Agbor, L, Apinjoh, T, Mwanza, S, Chileshe, J, Joshi, S, Malunga, P, Manyando, C, Laufer, M, Dara, A, Niangaly, A, Sinha, I, Brodin, D, Fofana, B, Dama, S, Dembele, D, Sidibe, B, Diallo, N, Thera, M, Wright, K, Gil, J, Doumbo, O, Baraka, V, Nabasumba, C, Francis, F, Lutumba, P, Mavoko, H, Alifrangis, M, Van Geertruyden, J-P, Sissoko, S, Sangaré, C, Toure, S, Sanogo, K, Diakite, H, Doumbia, D, Haidara, K, Julé, A, Ashurst, H, Merson, L, Olliaro, P, Marsh, V, Lang, T, Guérin, P, Awuondo, K, Njenga, D, Nyakarungu, E, Titus, P, Sutamihardja, A, Lowe, B, Ogutu, B, Billingsley, P, Soulama, I, Kaboré, M, Coulibaly, A, Ouattara, M, Sanon, S, Diarra, A, Bougouma, E, Ouedraogo, A, Sombie, B, Kargougou, D, Ouattara, D, Issa, N, Tiono, A, Sirima, S, Chaponda, M, Dabira, E, Dao, F, Dara, N, Coulibaly, M, Tolo, A, Maiga, H, Ouologuem, N, Niangaly, H, Botchway, F, Wilson, N, Dickinson-Copeland, CM, Adjei, AA, Wilson, M, Stiles, JK, Hamid, MA, Awad-Elgeid, M, Nasr, A, Netongo, P, Kamdem, S, Velavan, T, Lasry, E, Diarra, M, Bamadio, A, Traore, A, Coumare, S, Soma, B, Dicko, Y, Sangare, B, Tembely, A, Traore, D, Haidara, A, Dicko, A, Diawara, E, Beavogui, A, Camara, D, Sylla, M, Yattara, M, Sow, A, Camara, GC, Diallo, S, Mombo-Ngoma, G, Remppis, J, Sievers, M, Manego, RZ, Endamne, L, Hutchinson, D, Held, J, Supan, C, Salazar, CLO, Bonkian, LN, Nahum, A, Sié, A, Abdulla, S, Cantalloube, C, Djeriou, E, Bouyou-Akotet, M, Mordmüller, B, Siribie, M, Sirima, SB, Ouattara, SM, Coulibaly, S, Kabore, JM, Amidou, D, Tekete, M, Traore, O, Haefeli, W, Borrmann, S, Kaboré, N, Kabré, Z, Nikèma, F, Compaoré, D, Somé, F, Djimdé, A, Ouédraogo, J, Chalwe, V, Miller, J, Diakité, H, Greco, B, Spangenberg, T, Kourany-Lefoll, E, Oeuvray, C, Mulry, J, Tyagarajan, K, Magsaam, B, Barnes, K, Hodel, EM, Humphreys, G, Pace, C, Banda, CG, Denti, P, Allen, E, Lalloo, D, Mwapasa, V, Terlouw, A, Mwesigwa, J, Achan, J, Jawara, M, Ditanna, G, Worwui, A, Affara, M, Koukouikila-Koussounda, F, Kombo, M, Vouvoungui, C, Ntoumi, F, Etoka-Beka, MK, Deibert, J, Poulain, P, Kobawila, S, Gueye, NG, Seda, B, Kwambai, T, Jangu, P, Samuels, A, Kuile, FT, Kariuki, S, Barry, A, Bousema, T, Okech, B, Egwang, T, Corran, P, Riley, E, Ezennia, I, Ekwunife, O, Muleba, M, Stevenson, J, Mbata, K, Coetzee, M, Norris, D, Moneke-Anyanwoke, N, Momodou, J, Clarke, E, Scott, S, Tijani, A, Djimde, M, Vaillant, M, Samouda, H, Mensah, V, Roetynck, S, Kanteh, E, Bowyer, G, Ndaw, A, Oko, F, Bliss, C, Jagne, YJ, Cortese, R, Nicosia, A, Roberts, R, D'Alessio, F, Leroy, O, Faye, B, Cisse, B, Gerry, S, Viebig, N, Lawrie, A, Ewer, K, Hill, A, Nebie, I, Tiono, AB, Sanou, G, Konate, AT, Yaro, BJ, Sodiomon, S, Honkpehedji, Y, Agobe, JCD, Zinsou, F, Mengue, J, Richie, T, Hoffman, S, Nouatin, O, Ngoa, UA, Edoa, JR, Homoet, A, Engelhon, JE, Massinga-Louembe, M, Esen, M, Theisen, M, Sim, KL, Luty, AJ, Moutairou, K, Dinko, B, King, E, Targett, G, Sutherland, C, Likhovole, C, Ouma, C, Vulule, J, Musau, S, Khayumbi, J, Okumu, A, Murithi, W, Otu, J, Gehre, F, Zingue, D, Kudzawu, S, Forson, A, Mane, M, Rabna, P, Diarra, B, Kayede, S, Adebiyi, E, Kehinde, A, Onyejepu, N, Onubogu, C, Idigbe, E, Ba, A, Diallo, A, Mboup, S, Disse, K, Kadanga, G, Dagnra, Y, Baldeh, I, Corrah, T, De Jong, B, Antonio, M, Musanabaganwa, C, Musabyimana, JP, Karita, E, Diop, B, Nambajimana, A, Dushimiyimana, V, Karame, P, Russell, J, Ndoli, J, Hategekimana, T, Sendegeya, A, Condo, J, Binagwaho, A, Okonko, I, Okerentugba, P, Opaleye, O, Awujo, E, Frank-Peterside, N, Moyo, S, Kotokwe, K, Mohammed, T, Boleo, C, Mupfumi, L, Chishala, S, Gaseitsiwe, S, Tsalaile, L, Bussmann, H, Makhema, J, Baum, M, Marlink, R, Engelbretch, S, Essex, M, Novitsky, V, Saka, E, Kalipalire, Z, Bhairavabhotla, R, Midiani, D, Sherman, J, Mgode, G, Cox, C, Bwana, D, Mtui, L, Magesa, D, Kahwa, A, Mfinanga, G, Mulder, C, Borain, N, Petersen, L, Du Plessis, J, Theron, G, Holm-Hansen, C, Tekwu, EM, Sidze, LK, Assam, JPA, Eyangoh, S, Niemann, S, Beng, VP, Frank, M, Atiadeve, S, Hilmann, D, Awoniyi, D, Baumann, R, Kriel, B, Jacobs, R, Kidd, M, Loxton, A, Kaempfer, S, Singh, M, Mwanza, W, Milimo, D, Moyo, M, Kasese, N, Cheeba-Lengwe, M, Munkondya, S, Ayles, H, De Haas, P, Muyoyeta, M, Namuganga, AR, Kizza, HM, Mendy, A, Tientcheu, L, Ayorinde, A, Coker, E, Egere, U, Coussens, A, Naude, C, Chaplin, G, Noursadeghi, M, Martineau, A, Jablonski, N, Wilkinson, R, Ouedraogo, HG, Matteelli, A, Regazzi, M, Tarnagda, G, Villani, P, Sulis, G, Diagbouga, S, Roggi, A, Giorgetti, F, Kouanda, S, Bidias, A, Ndjonka, D, Olemba, C, Souleymanou, A, Mukonzo, J, Kuteesa, R, Ogwal-Okeng, J, Gustafsson, LL, Owen, J, Bassi, P, Gashau, W, Olaf, K, Dodoo, A, Okonkwo, P, Kanki, P, Maruapula, D, Seraise, B, Einkauf, K, Reilly, A, Rowley, C, Musonda, R, Framhein, A, Mpagama, S, Semvua, H, Maboko, L, Hoelscher, M, Heinrich, N, Mulenga, L, Kaayunga, C, Davies, M-A, Egger, M, Musukuma, K, Dambe, R, Usadi, B, Ngari, M, Thitiri, J, Mwalekwa, L, Fegan, G, Berkley, J, Nsagha, D, Munamunungu, V, Bolton, C, Siyunda, A, Shilimi, J, Bucciardini, R, Fragola, V, Abegaz, T, Lucattini, S, Halifom, A, Tadesse, E, Berhe, M, Pugliese, K, De Castro, P, Terlizzi, R, Fucili, L, Di Gregorio, M, Mirra, M, Zegeye, T, Binelli, A, Vella, S, Abraham, L, Godefay, H, Rakotoarivelo, R, Raberahona, M, Randriamampionona, N, Andriamihaja, R, Rasamoelina, T, Cornet, M, De Dieu Randria, MJ, Benet, T, Vanhems, P, Andrianarivelo, MR, Chirwa, U, Michelo, C, Hamoonga, R, Wandiga, S, Oduor, P, Agaya, J, Sharma, A, Cavanaugh, S, Cain, K, Mukisa, J, Mupere, E, Worodria, W, Ngom, JT, Koro, F, Godwe, C, Adande, C, Ateugieu, R, Onana, T, Ngono, A, Kamdem, Y, Ngo-Niobe, S, Etoa, F-X, Kanengoni, M, Ruzario, S, Ndebele, P, Shana, M, Tarumbiswa, F, Musesengwa, R, Gutsire, R, Fisher, K, Thyagarajan, B, Akanbi, O, Binuyo, M, Ssengooba, W, Respeito, D, Mambuque, E, Blanco, S, Mandomando, I, Cobelens, F, Garcia-Basteiro, A, Tamene, A, Topp, S, Mwamba, C, Padian, N, Sikazwe, I, Geng, E, Holmes, C, Sikombe, K, Hantuba, Czaicki, N, Simbeza, S, Somwe, P, Umulisa, M, Ilo, J, Kestelyn, E, Uwineza, M, Agaba, S, Delvaux, T, Wijgert, J, Gethi, D, Odeny, L, Tamandjou, C, Kaindjee-Tjituka, F, Brandt, L, Cotton, M, Nel, E, Preiser, W, Andersson, M, Adepoju, A, Magana, M, Etsetowaghan, A, Chilikwazi, M, Sutcliffe, C, Thuma, P, Sinywimaanzi, K, Matakala, H, Munachoonga, P, Moss, W, Masenza, IS, Geisenberger, O, Agrea, P, Rwegoshora, F, Mahiga, H, Olomi, W, Kroidl, A, Kayode, G, Amoakoh-Coleman, M, Ansah, E, Uthman, O, Fokam, J, Santoro, M-M, Musolo, C, Chimbiri, I, Chikwenga, G, Deula, R, Massari, R, Lungu, A, Perno, C-F, Ndzengue, G, Loveline, N, Lissom, A, Flaurent, T, Sosso, S, Essomba, C, Kpeli, G, Otchere, I, Lamelas, A, Buultjens, A, Bulach, D, Baines, S, Seemann, T, Giulieri, S, Nakobu, Z, Aboagye, S, Owusu-Mireku, E, Danso, E, Hauser, J, Hinic, V, Pluschke, G, Stinear, T, Yeboah-Manu, D, Elshayeb, A, Siddig, ME, Ahmed, AA, Hussien, AE, Kabwe, M, Tembo, J, Chilukutu, L, Chilufya, M, Ngulube, F, Lukwesa, C, Enne, V, Wexner, H, Mwananyanda, L, Hamer, D, Sinyangwe, S, Ahmed, Y, Klein, N, Maeurer, M, Zumla, A, Bates, M, Beyala, L, Etienne, G, Anthony, N, Benjamin, A, Ateudjieu, J, Chibwe, B, Ojok, D, Tarr, CA, Perez, GM, Omeonga, S, Kibungu, F, Meyer, A, Lansana, P, Mayor, A, Onyango, P, Van Loggerenberg, F, Furtado, T, Boggs, L, Segrt, A, Dochez, C, Burnett, R, Mphahlele, MJ, Miiro, G, Mbidde, E, Peshu, N, Kivaya, E, Ngowi, B, Kavishe, R, Maowia, M, Sandstrom, E, Ayuo, E, Mmbaga, B, Leisegang, C, Thorpe, M, Batchilly, E, N'Guessan, J-P, Kanteh, D, Søfteland, S, Sebitloane, M, Vwalika, B, Taylor, M, Galappaththi-Arachchige, H, Holmen, S, Gundersen, SG, Ndhlovu, P, Kjetland, EF, Kombe, F, Toohey, J, Pienaar, E, Kredo, T, Cham, PM, Abubakar, I, Dondeh, BL, Vischer, N, Pfeiffer, C, Burri, C, Musukwa, K, Zürcher, S, Mwandu, T, Bauer, S, Adriko, M, Mwaura, P, Omolloh, K, Jones, C, Malecela, M, Hamidu, BA, Jenner, TE, Asiedu, LJ, Osei-Atweneboana, M, Afeke, I, Addo, P, Newman, M, Durnez, L, Eddyani, M, Ammisah, N, Abas, M, Quartey, M, Ablordey, A, Akinwale, O, Adeneye, A, Ezeugwu, S, Olukosi, Y, Adewale, B, Sulyman, M, Mafe, M, Okwuzu, J, Gyang, P, Nwafor, T, Henry, U, Musa, B, Ujah, I, Agobé, JCD, Grau-Pujol, B, Sacoor, C, Nhabomba, A, Casellas, A, Quintó, L, Subirà, C, Giné, R, Valentín, A, Muñoz, J, Nikiema, M, Ky-Ba, A, Comapore, KAM, Sangare, L, Oluremi, A, Michel, M, Camara, Y, Sanneh, B, Cuamba, I, Gutiérrez, J, Lázaro, C, Mejia, R, Adedeji, A, Folorunsho, S, Demehin, P, Akinsanya, B, Cowley, G, Da Silva, ET, Nabicassa, M, De Barros, PDP, Blif, MM, Bailey, R, Last, A, Mahendradhata, Y, Gotuzzo, E, De Nys, K, Casteels, M, Nona, SK, Lumeka, K, Todagbe, A, Djima, MM, Ukpong, M, Sagay, A, Khamofu, H, Torpey, K, Afiadigwe, E, Anenih, J, Ezechi, O, 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Clarke, E, Scott, S, Tijani, A, Djimde, M, Vaillant, M, Samouda, H, Mensah, V, Roetynck, S, Kanteh, E, Bowyer, G, Ndaw, A, Oko, F, Bliss, C, Jagne, YJ, Cortese, R, Nicosia, A, Roberts, R, D'Alessio, F, Leroy, O, Faye, B, Cisse, B, Gerry, S, Viebig, N, Lawrie, A, Ewer, K, Hill, A, Nebie, I, Tiono, AB, Sanou, G, Konate, AT, Yaro, BJ, Sodiomon, S, Honkpehedji, Y, Agobe, JCD, Zinsou, F, Mengue, J, Richie, T, Hoffman, S, Nouatin, O, Ngoa, UA, Edoa, JR, Homoet, A, Engelhon, JE, Massinga-Louembe, M, Esen, M, Theisen, M, Sim, KL, Luty, AJ, Moutairou, K, Dinko, B, King, E, Targett, G, Sutherland, C, Likhovole, C, Ouma, C, Vulule, J, Musau, S, Khayumbi, J, Okumu, A, Murithi, W, Otu, J, Gehre, F, Zingue, D, Kudzawu, S, Forson, A, Mane, M, Rabna, P, Diarra, B, Kayede, S, Adebiyi, E, Kehinde, A, Onyejepu, N, Onubogu, C, Idigbe, E, Ba, A, Diallo, A, Mboup, S, Disse, K, Kadanga, G, Dagnra, Y, Baldeh, I, Corrah, T, De Jong, B, Antonio, M, Musanabaganwa, C, Musabyimana, JP, Karita, E, Diop, B, Nambajimana, A, Dushimiyimana, V, Karame, P, Russell, J, Ndoli, J, Hategekimana, T, Sendegeya, A, Condo, J, Binagwaho, A, Okonko, I, Okerentugba, P, Opaleye, O, Awujo, E, Frank-Peterside, N, Moyo, S, Kotokwe, K, Mohammed, T, Boleo, C, Mupfumi, L, Chishala, S, Gaseitsiwe, S, Tsalaile, L, Bussmann, H, Makhema, J, Baum, M, Marlink, R, Engelbretch, S, Essex, M, Novitsky, V, Saka, E, Kalipalire, Z, Bhairavabhotla, R, Midiani, D, Sherman, J, Mgode, G, Cox, C, Bwana, D, Mtui, L, Magesa, D, Kahwa, A, Mfinanga, G, Mulder, C, Borain, N, Petersen, L, Du Plessis, J, Theron, G, Holm-Hansen, C, Tekwu, EM, Sidze, LK, Assam, JPA, Eyangoh, S, Niemann, S, Beng, VP, Frank, M, Atiadeve, S, Hilmann, D, Awoniyi, D, Baumann, R, Kriel, B, Jacobs, R, Kidd, M, Loxton, A, Kaempfer, S, Singh, M, Mwanza, W, Milimo, D, Moyo, M, Kasese, N, Cheeba-Lengwe, M, Munkondya, S, Ayles, H, De Haas, P, Muyoyeta, M, Namuganga, AR, Kizza, HM, Mendy, A, Tientcheu, L, Ayorinde, A, Coker, E, Egere, U, Coussens, A, Naude, C, Chaplin, G, Noursadeghi, M, Martineau, A, Jablonski, N, Wilkinson, R, Ouedraogo, HG, Matteelli, A, Regazzi, M, Tarnagda, G, Villani, P, Sulis, G, Diagbouga, S, Roggi, A, Giorgetti, F, Kouanda, S, Bidias, A, Ndjonka, D, Olemba, C, Souleymanou, A, Mukonzo, J, Kuteesa, R, Ogwal-Okeng, J, Gustafsson, LL, Owen, J, Bassi, P, Gashau, W, Olaf, K, Dodoo, A, Okonkwo, P, Kanki, P, Maruapula, D, Seraise, B, Einkauf, K, Reilly, A, Rowley, C, Musonda, R, Framhein, A, Mpagama, S, Semvua, H, Maboko, L, Hoelscher, M, Heinrich, N, Mulenga, L, Kaayunga, C, Davies, M-A, Egger, M, Musukuma, K, Dambe, R, Usadi, B, Ngari, M, Thitiri, J, Mwalekwa, L, Fegan, G, Berkley, J, Nsagha, D, Munamunungu, V, Bolton, C, Siyunda, A, Shilimi, J, Bucciardini, R, Fragola, V, Abegaz, T, Lucattini, S, Halifom, A, Tadesse, E, Berhe, M, Pugliese, K, De Castro, P, Terlizzi, R, Fucili, L, Di Gregorio, M, Mirra, M, Zegeye, T, Binelli, A, Vella, S, Abraham, L, Godefay, H, Rakotoarivelo, R, Raberahona, M, Randriamampionona, N, Andriamihaja, R, Rasamoelina, T, Cornet, M, De Dieu Randria, MJ, Benet, T, Vanhems, P, Andrianarivelo, MR, Chirwa, U, Michelo, C, Hamoonga, R, Wandiga, S, Oduor, P, Agaya, J, Sharma, A, Cavanaugh, S, Cain, K, Mukisa, J, Mupere, E, Worodria, W, Ngom, JT, Koro, F, Godwe, C, Adande, C, Ateugieu, R, Onana, T, Ngono, A, Kamdem, Y, Ngo-Niobe, S, Etoa, F-X, Kanengoni, M, Ruzario, S, Ndebele, P, Shana, M, Tarumbiswa, F, Musesengwa, R, Gutsire, R, Fisher, K, Thyagarajan, B, Akanbi, O, Binuyo, M, Ssengooba, W, Respeito, D, Mambuque, E, Blanco, S, Mandomando, I, Cobelens, F, Garcia-Basteiro, A, Tamene, A, Topp, S, Mwamba, C, Padian, N, Sikazwe, I, Geng, E, Holmes, C, Sikombe, K, Hantuba, Czaicki, N, Simbeza, S, Somwe, P, Umulisa, M, Ilo, J, Kestelyn, E, Uwineza, M, Agaba, S, Delvaux, T, Wijgert, J, Gethi, D, Odeny, L, Tamandjou, C, Kaindjee-Tjituka, F, Brandt, L, Cotton, M, Nel, E, Preiser, W, Andersson, M, Adepoju, A, Magana, M, Etsetowaghan, A, Chilikwazi, M, Sutcliffe, C, Thuma, P, Sinywimaanzi, K, Matakala, H, Munachoonga, P, Moss, W, Masenza, IS, Geisenberger, O, Agrea, P, Rwegoshora, F, Mahiga, H, Olomi, W, Kroidl, A, Kayode, G, Amoakoh-Coleman, M, Ansah, E, Uthman, O, Fokam, J, Santoro, M-M, Musolo, C, Chimbiri, I, Chikwenga, G, Deula, R, Massari, R, Lungu, A, Perno, C-F, Ndzengue, G, Loveline, N, Lissom, A, Flaurent, T, Sosso, S, Essomba, C, Kpeli, G, Otchere, I, Lamelas, A, Buultjens, A, Bulach, D, Baines, S, Seemann, T, Giulieri, S, Nakobu, Z, Aboagye, S, Owusu-Mireku, E, Danso, E, Hauser, J, Hinic, V, Pluschke, G, Stinear, T, Yeboah-Manu, D, Elshayeb, A, Siddig, ME, Ahmed, AA, Hussien, AE, Kabwe, M, Tembo, J, Chilukutu, L, Chilufya, M, Ngulube, F, Lukwesa, C, Enne, V, Wexner, H, Mwananyanda, L, Hamer, D, Sinyangwe, S, Ahmed, Y, Klein, N, Maeurer, M, Zumla, A, Bates, M, Beyala, L, Etienne, G, Anthony, N, Benjamin, A, Ateudjieu, J, Chibwe, B, Ojok, D, Tarr, CA, Perez, GM, Omeonga, S, Kibungu, F, Meyer, A, Lansana, P, Mayor, A, Onyango, P, Van Loggerenberg, F, Furtado, T, Boggs, L, Segrt, A, Dochez, C, Burnett, R, Mphahlele, MJ, Miiro, G, Mbidde, E, Peshu, N, Kivaya, E, Ngowi, B, Kavishe, R, Maowia, M, Sandstrom, E, Ayuo, E, Mmbaga, B, Leisegang, C, Thorpe, M, Batchilly, E, N'Guessan, J-P, Kanteh, D, Søfteland, S, Sebitloane, M, Vwalika, B, Taylor, M, Galappaththi-Arachchige, H, Holmen, S, Gundersen, SG, Ndhlovu, P, Kjetland, EF, Kombe, F, Toohey, J, Pienaar, E, Kredo, T, Cham, PM, Abubakar, I, Dondeh, BL, Vischer, N, Pfeiffer, C, Burri, C, Musukwa, K, Zürcher, S, Mwandu, T, Bauer, S, Adriko, M, Mwaura, P, Omolloh, K, Jones, C, Malecela, M, Hamidu, BA, Jenner, TE, Asiedu, LJ, Osei-Atweneboana, M, Afeke, I, Addo, P, Newman, M, Durnez, L, Eddyani, M, Ammisah, N, Abas, M, Quartey, M, Ablordey, A, Akinwale, O, Adeneye, A, Ezeugwu, S, Olukosi, Y, Adewale, B, Sulyman, M, Mafe, M, Okwuzu, J, Gyang, P, Nwafor, T, Henry, U, Musa, B, Ujah, I, Agobé, JCD, Grau-Pujol, B, Sacoor, C, Nhabomba, A, Casellas, A, Quintó, L, Subirà, C, Giné, R, Valentín, A, Muñoz, J, Nikiema, M, Ky-Ba, A, Comapore, KAM, Sangare, L, Oluremi, A, Michel, M, Camara, Y, Sanneh, B, Cuamba, I, Gutiérrez, J, Lázaro, C, Mejia, R, Adedeji, A, Folorunsho, S, Demehin, P, Akinsanya, B, Cowley, G, Da Silva, ET, Nabicassa, M, De Barros, PDP, Blif, MM, Bailey, R, Last, A, Mahendradhata, Y, Gotuzzo, E, De Nys, K, Casteels, M, Nona, SK, Lumeka, K, Todagbe, A, Djima, MM, Ukpong, M, Sagay, A, Khamofu, H, Torpey, K, Afiadigwe, E, Anenih, J, Ezechi, O, Nweneka, C, Idoko, J, Muhumuza, S, Katahoire, A, Nuwaha, F, Olsen, A, Okeyo, S, Omollo, R, Kimutai, R, Ochieng, M, Egondi, T, Moonga, C, Chileshe, C, Magwende, G, Anumudu, C, Onile, O, Oladele, V, Adebayo, A, Awobode, H, Oyeyemi, O, Odaibo, A, Kabuye, E, Lutalo, T, Njua-Yafi, C, Nkuo-Akenji, T, Anchang-Kimbi, J, Mugri, R, Chi, H, Tata, R, Njumkeng, C, Dodoo, D, Achidi, E, Fernandes, J, Bache, EB, Matakala, K, Searle, K, Greenman, M, and Rainwater-Lovett, K

Published
2017

12. Interaction of drug-carrier systems with targets: A study using atomic force microscopy

Author

Blaschke, T., Spangenberg, T., Schlupp, P., Dathe, M., Szcymczak, W., Mehnert, W., Korting, H.C., Thalhammer, S., Niehus, H., Schäfer-Korting, M., and Kramer, K.D.

Subjects
Solid lipid nanoparticles, Electron-spin-resonance, Parelectric spectroscopy, Occlusive properties, Skin, Matrix, Bioavailability, Cytotoxicity, Enhancement, Liposomes
Abstract

To learn about the interaction between drug agents and nanoparticular carrier systems, the physical analytical methods of parelectric, electron spin and fluorescence spectroscopy have proven helpful tools to yield descriptive models of such complex systems. For a deeper understanding of drug absorption from body surfaces and drug distribution into the tissues, however, the lack of knowledge about the interaction between such agents and membranes on different levels is a severe drawback. This gap can be closed by the application of atomic force microscopy at normal temperatures and under the admission of liquid surroundings. Moreover, this method allows the inspection of such system-membrane interactions in dependence on time. We studied membrane topography in liquid and gel-phase mixtures, structural changes of membranes during their destruction by aqueous peptide solutions as well as the stability of the membranes exposed to surfactants of increasing concentration and to lipid nanoparticles (solid lipid nanoparticles, nanostructured lipid carriers). For future modelling we can describe the geometry of lipid nanoparticles as well.

Published
2010

17. Activité tectonique, magmatique et hydrothermale autour des triples jonctions de16°50'S-173°30'E et de l6°30'S-l76°10E dans le bassin nord fidjien (SWPacifique): Campagne HYFIFLUX

Author

Auzende, Jean-marie, Halbach, P, Allspach, A, Becker, K, Blum, N, Bonnier, Olga, Van Gerven, M, Halbach, M, Koschinsky, A, Lange, D, Madureira, Mj, Manoutsoglou, E, Mrazek, J, Munch, U, Pratt, C, Rahders, E, Van Reusel, A, Richter, S, Seifert, T, Spangenberg, T, Stenzler, J, Thiermann, F, Turkay, M, and Windoffer, R

Subjects
Dorsales, Magmatisme, SW PACIFIC, TECTONISM, Tectonique, RIDGES, Hydrothermalisme, MAGMATISM, HYDROTHERMALISM, SW Pacifique
Abstract

The aim of the HYFIFLUX-SONNE 99 cruise was the geological, biological and chemical study of the 2 triple-junctions characterizing the oceanic accretion in the North Fiji Basin. Multibeam bathymetric coverage, in situ observations and sampling confirmed the existence of an active spreading ridge immediately west of the Fiji islands (WFR), and gave an evaluation of the magmatic and hydrothermal activity of the central ridge (CSR). New hydrothermal sites have been discovered and sampled., La campagne HYFIFLUX-SONNE 99 a eu pour objectif l'étude géologique, biologique et chimique des 2 triples jonctions qui caractérisent l'accrétion océanique dans le bassin nord fidjien. La couverture bathymétrique multifaisceaux, l'observation in situ et l'échantillonnage ont permis de confirmer l'existence d'un axe d'accrétion actif immédiatement à l'Ouest des îles Fidji (WFR), et d'évaluer l'activité magmatique et hydrothermale à l'extrémité nord de l'axe central (CSR). De nouveaux sites hydrothermaux ont été découverts et échantillonnés.

Published
1995

28. Merck Open Global Health Library in vitro screening against Schistosoma mansoni identified two new substances with antischistosomal activities for further development.

Author

Ueberall ME, Berchthold M, Häberli C, Lindemann S, Spangenberg T, Keiser J, and Grevelding CG

Subjects
Animals, Praziquantel pharmacology, Drug Repositioning, Anthelmintics pharmacology, Drug Evaluation, Preclinical, Mice, Female, Global Health, Schistosoma mansoni drug effects, Schistosomiasis mansoni drug therapy, Schistosomiasis mansoni parasitology, Schistosomicides pharmacology
Abstract

Background: Schistosomiasis, which is caused by the parasite Schistosoma mansoni as well as other species of the trematode genus Schistosoma, leads to chronic inflammation and finally to liver fibrosis. If untreated, the disease can cause life-threatening complications. The current treatment of schistosomiasis relies on a single drug, praziquantel (PZQ). However, there is increasing concern about emerging resistance to PZQ due to its frequent use., Methods: To identify potential alternative drugs for repurposing, the Open Global Health Library (OGHL) was screened in vitro, using two different screening workflows at two institutions, against adult S. mansoni couples and newly transformed schistosomula. This was followed by confirmation of the effects of the lead structures against adult worms., Results: In vitro screening at one of the institutions identified two fast-acting substances affecting worm physiology (OGHL00022, OGHL00121). The effects of the two lead structures were investigated in more detail by confocal laser scanning microscopy and 5-ethynyl 2´-deoxyuridine (EdU) assays to assess morphological effects and stem cell effects. Both substances showed negative effects on stem cell proliferation in S. mansoni but no further morphological changes. The EC 50 values of both compounds were determined, with values for compound OGHL00022 of 5.955 µM for pairing stability, 10.88 µM for attachment, and 18.77 µM for motility, while the values for compound OGHL00121 were 7.088 µM for pairing stability, 8.065 µM for attachment, and 6.297 µM for motility 24 h after treatment. Furthermore, S. mansoni couples were treated in vitro with these two lead structures simultaneously to check for additive effects, which were found with respect to reduced motility. The second in vitro screening, primarily against newly transformed schistosomula and secondarily against adult worms, identified four lead structures in total (OGHL00006, OGHL00022, OGHL00169, OGHL00217). In addition, one of the tested analogues of the hits OGHL00006, OGHL00169, and OGHL00217 showed effects on both stages., Conclusions: In two independent in vitro screening approaches against two stages of S. mansoni one common interesting structure with rapid effects was identified, OGHL00022, which provides opportunities for further development., Competing Interests: Declarations. Ethics approval and consent to participate: Not applicable. Consent for publication: Not applicable. Competing interests: SL is an employee of Merck Healthcare KGaA, Darmstadt, Germany. TS is an employee of Ares Trading S.A. (an affiliate of Merck KgaA, Darmstadt, Germany). MEU, MB, CH, JK and CGG declare that they have no competing interests., (© 2025. The Author(s).)

Published
2025
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29. Drug Interaction Studies of Cabamiquine:Ganaplacide Combination against Hepatic Plasmodium berghei .

Author

Gal IR, Demarta-Gatsi C, Fontinha D, Arez F, Wicha SG, Rottmann M, Nunes-Cabaço H, Blais J, Jain JP, Lakshminarayana SB, Brito C, Prudêncio M, Alves PM, and Spangenberg T

Subjects
Animals, Humans, Mice, Drug Interactions, Liver parasitology, Liver drug effects, Quinolines pharmacology, Quinolines chemistry, Drug Therapy, Combination, Cell Line, Hepatocytes drug effects, Hepatocytes parasitology, Plasmodium berghei drug effects, Antimalarials pharmacology, Antimalarials chemistry, Malaria drug therapy, Malaria parasitology
Abstract

New antimalarial combination therapies with novel modes of action are required to counter the emergence and spread of Plasmodium drug resistance against existing therapeutics. Here, we present a study to evaluate the preventive activity of a combination of clinical antimalarial drug candidates, cabamiquine and ganaplacide, that have multistage activity against the liver and blood stages of Plasmodium infection. Cabamiquine (DDD107498, M5717) inhibits parasite protein synthesis, and ganaplacide (KAF156) inhibits protein trafficking, blocks the establishment of new permeation pathways, and causes endoplasmic reticulum expansion. The pharmacodynamic parameters of a combination of the two compounds were assessed employing a pharmacometrics approach in conjunction with in vitro-in silico checkerboard analysis. The in vitro study was performed on a previously established 3D infection platform based on human hepatic cell lines that sustain infection by rodent P. berghei parasites. The in vivo efficacy of this drug combination was assessed against the liver stage of the P. berghei . Our results show that the combination of both drugs at the tested concentrations does not interfere with the drugs respective mode of action or affect hepatocyte cell viability. The drug combination was fully effective in preventing the appearance of blood stage parasites when a systemic plasma C av0-24 /EC 50 ratio >2 for ganaplacide and >5 for cabamiquine was achieved. These findings demonstrate that chemoprevention using a combination of cabamiquine and ganaplacide has the potential to target the asymptomatic liver stage of Plasmodium infection and prevent the development of parasitemia.

Published
2025
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30. High-transmission spectrometer for rapid resonant inelastic soft X-ray scattering (rRIXS) maps.

Author

Weinhardt L, Wansorra C, Steininger R, Spangenberg T, Hauschild D, and Heske C

Abstract

The design and first results of a high-transmission soft X-ray spectrometer operated at the X-SPEC double-undulator beamline of the KIT Light Source are presented. As a unique feature, particular emphasis was placed on optimizing the spectrometer transmission by maximizing the solid angle and the efficiencies of spectrometer gratings and detector. A CMOS detector, optimized for soft X-rays, allows for quantum efficiencies of 90% or above over the full energy range of the spectrometer, while simultaneously offering short readout times. Combining an optimized control system at the X-SPEC beamline with continuous energy scans (as opposed to step scans), the high transmission of the spectrometer, and the fast readout of the CMOS camera, enable the collection of entire rapid resonant inelastic soft X-ray scattering maps in less than 1 min. Series of spectra at a fixed energy can be taken with a frequency of up to 5 Hz. Furthermore, the use of higher-order reflections allows a very wide energy range (45 to 2000 eV) to be covered with only two blazed gratings, while keeping the efficiency high and the resolving power E/ΔE above 1500 and 3000 with low- and high-energy gratings, respectively., (open access.)

Published
2024
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31. Identification of potent and orally efficacious phosphodiesterase inhibitors in Cryptosporidium parvum-infected immunocompromised male mice.

Author

Ajiboye J, Teixeira JE, Gasonoo M, Mattice EB, Korwin-Mihavics B, Miller P, Cameron AC, Stebbins E, Campbell SD, Griggs DW, Spangenberg T, Meyers MJ, and Huston CD

Subjects
Animals, Male, Mice, Humans, Administration, Oral, Pyrimidines pharmacology, Pyrimidines administration & dosage, Pyrazoles pharmacology, Pyrazoles administration & dosage, Molecular Docking Simulation, Cryptosporidium parvum drug effects, Cryptosporidiosis drug therapy, Cryptosporidiosis parasitology, Immunocompromised Host, Phosphodiesterase Inhibitors pharmacology, Phosphodiesterase Inhibitors administration & dosage
Abstract

Cryptosporidium parvum and C. hominis are parasites that cause life-threatening diarrhea in children and immunocompromised people. There is only one approved treatment that is modestly effective for children and ineffective for AIDS patients. Here, screening 278 compounds from the Merck KGaA, Darmstadt, Germany collection and accelerated follow-up enabled by prior investigation of the compounds identifies a series of pyrazolopyrimidine human phosphodiesterase (PDE)-V (hPDE-V) inhibitors with potent anticryptosporidial activity and efficacy following oral administration in C. parvum-infected male mice. The lead compounds affect parasite host cell egress, inhibit both C. parvum and C. hominis, work rapidly, and have minimal off-target effects in a safety screening panel. Interestingly, the hPDE-V inhibitors sildenafil and the 4-aminoquinoline compound 7a do not affect Cryptosporidium. C. parvum expresses one PDE (CpPDE1) continuously during asexual growth, the inhibited life stage. According to homology modeling and docking, the lead compounds interact with CpPDE1. Bulkier amino acids (Val900 and His884) in the CpPDE1 active site replace alanines in hPDE-V and block sildenafil binding. Supporting this, sildenafil kills a CRISPR-engineered Cryptosporidium CpPDE1 V900A mutant. The CpPDE1 mutation also alters parasite susceptibility to pyrazolopyrimidines. CpPDE1 is therefore a validated pyrazolopyrimidine molecular target to exploit for target-based optimization for improved anticryptosporidial development., (© 2024. The Author(s).)

Published
2024
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32. Towards clinically relevant dose ratios for Cabamiquine and Pyronaridine combination using P. falciparum field isolate data.

Author

Maiga M, Dembele L, Courlet P, Khandelwal A, Dara A, Sogore F, Diakité O, Maiga FO, Dao F, Sissoko S, Barre Y, Goita S, Diakite M, Diakite SAS, Djimde AA, Oeuvray C, Spangenberg T, Wicha SG, and Demarta-Gatsi C

Subjects
Humans, Drug Therapy, Combination, Dose-Response Relationship, Drug, Drug Resistance drug effects, Plasmodium falciparum drug effects, Antimalarials pharmacology, Antimalarials administration & dosage, Antimalarials pharmacokinetics, Malaria, Falciparum drug therapy, Malaria, Falciparum parasitology, Naphthyridines administration & dosage, Naphthyridines pharmacology, Naphthyridines pharmacokinetics
Abstract

The selection and combination of dose regimens for antimalarials involve complex considerations including pharmacokinetic and pharmacodynamic interactions. In this study, we use immediate ex vivo P. falciparum field isolates to evaluate the effect of cabamiquine and pyronaridine as standalone treatments and in combination therapy. We feed the data into a pharmacometrics model to generate an interaction map and simulate meaningful clinical dose ratios. We demonstrate that the pharmacometrics model of parasite growth and killing provides a detailed description of parasite kinetics against cabamiquine-susceptible and resistant parasites. Pyronaridine monotherapy provides suboptimal killing rates at doses as high as 720 mg. In contrast, the combination of a single dose of 330 mg cabamiquine and 360 mg pyronaridine provides over 90% parasite killing in most of the simulated patients. The described methodology that combines a rapid, 3R-compliant in vitro method and modelling to set meaningful doses for new antimalarials could contribute to clinical drug development., (© 2024. The Author(s).)

Published
2024
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33. Absence of developmental and reproductive toxicity in rats, rabbits, and zebrafish embryos exposed to antimalarial drug cabamiquine.

Author

Gado A, Hewitt P, Ballard P, Tornesi B, Baeurle THH, Oeuvray C, Spangenberg T, and Demarta-Gatsi C

Subjects
Animals, Rabbits, Female, Rats, Pregnancy, Quinolines toxicity, Quinolines pharmacology, Embryo, Nonmammalian drug effects, Male, Maternal Exposure adverse effects, Fetal Development drug effects, Malaria drug therapy, Antimalarials toxicity, Antimalarials pharmacology, Zebrafish, Embryonic Development drug effects, Reproduction drug effects
Abstract

Background: When developing new antimalarial drugs, considering their potential use during pregnancy as preventive or curative therapy is crucial. This prevents the parasite from affecting embryonic development and reduces maternal and fetal death risks. Consequently, understanding the exposure and safety of antimalarial drugs during pregnancy is crucial, with well-designed animal studies playing a key role in this assessment., Methods: As part of the drug development program for cabamiquine, a series of developmental and reproductive toxicity studies were conducted in rats and rabbits. Additionally, the zebrafish embryo model was used to further improve embryo exposure, minimize confounding factors related to maternal toxicity, and assess developmental risks of cabamiquine., Results: In these studies, although maternal toxicity was observed, there were no cabamiquine-related adverse effects on fertility, embryonic, or fetal development at maternal exposures representing significant multiples (up to five and 10 times higher in rabbit and rats, respectively) than the exposure at the anticipated efficacious human dose. Similarly, no adverse effects were observed on ZF embryonic development, even though cabamiquine concentrations in the embryos were 10-fold higher than nominal concentrations., Conclusions: The results obtained in a full set of reproductive toxicity studies did not provide evidence of detrimental effects on the conceptuses and progeny at maternally nontoxic doses and exposures, still representing a multiple of the anticipated systemic exposures in women of childbearing potential (WOCBP). Cabamiquine can therefore be considered a suitable therapeutic option for WOCBP and pregnant women living in malaria-endemic regions by significantly reducing maternal and infant malaria death rates., (© 2024 The Author(s). Birth Defects Research published by Wiley Periodicals LLC.)

Published
2024
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34. Analysis of the Physicochemical Properties of Anti-Schistosomal Compounds to Identify Next-Generation Leads.

Author

González Cabrera D, Keiser J, and Spangenberg T

Abstract

To investigate the physicochemical properties of anti-schistosomal compounds reported between 2008 and 2023, a simple but extensive literature scrutiny was conducted. Keywords were searched in Chemical Abstracts Service (CAS) SciFinder and primary medicinal chemistry and pharmacology literature to locate publications with compounds displaying ex vivo and/or in vivo anti-schistosomal activity. A total of 57 repurposed U.S. Food and Drug Administration (FDA)-approved drugs, hits and their derivatives were manually extracted, curated and compared to known anti-schistosomal oral drugs in view of establishing trends of calculated critical molecular properties. From this analysis, it was determined that more than 65% of the compounds display cLogD 7.4 > 3 values, whereas oxamniquine, metrifonate and praziquantel (PZQ), previous and currently used oral anti-schistosomal drugs, possess lower cLogD 7.4 values (≤2.5). Furthermore, the lipophilicity associated with PZQ corresponds to a highly permeable and sparingly soluble compound, characteristics that favor drug absorption and compound penetration in the parasite. These physicochemical properties together with PZQ's anti-schistosomal activity make PZQ an essential medicine for the treatment of schistosomiasis and demonstrate the importance of finding the right balance among potency (e.g., EC 50 < 5 and 0.5 μM), cell permeability (e.g., P app > 2 × 10 6 cm/s) and kinetic aqueous solubility (e.g., >10 μM) to provide high-quality hits and/or leads for the discovery of new oral anti-schistosomal therapeutics., Competing Interests: The authors declare the following competing financial interest(s): T.S. is an employee of Ares Trading SA, Eysins, Switzerland, an affiliate of Merck KGaA, Darmstadt, Germany. This work was funded by Merck Healthcare KGaA, Darmstadt, Germany (CrossRef Funder ID: 10.13039/100009945)., (© 2024 The Authors. Published by American Chemical Society.)

Published
2024
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36. The Anthelmintic Activity of Praziquantel Analogs Correlates with Structure-Activity Relationships at TRPM PZQ Orthologs.

Author

Sprague DJ, Kaethner M, Park SK, Rohr CM, Harris JL, Maillard D, Spangenberg T, Lundström-Stadelmann B, and Marchant JS

Abstract

The anthelmintic drug praziquantel remains a key clinical therapy for treating various diseases caused by parasitic flatworms. The parasite target of praziquantel has remained undefined despite longstanding usage in the clinic, although a candidate ion channel target, named TRPM PZQ , has recently been identified. Intriguingly, certain praziquantel derivatives show different activities against different parasites: for example, some praziquantel analogs are considerably more active against cestodes than against schistosomes. Here we interrogate whether the different activities of praziquantel analogs against different parasites are also reflected by unique structure-activity relationships at the TRPM PZQ channels found in these different organisms. To do this, several praziquantel analogs were synthesized and functionally profiled against schistosome and cestode TRPM PZQ channels. Data demonstrate that structure-activity relationships are closely mirrored between parasites and their TRPM PZQ orthologs, providing further support for TRPM PZQ as the therapeutically relevant target of praziquantel., Competing Interests: The authors declare no competing financial interest., (© 2023 The Authors. Published by American Chemical Society.)

Published
2023
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37. Causal chemoprophylactic activity of cabamiquine against Plasmodium falciparum in a controlled human malaria infection: a randomised, double-blind, placebo-controlled study in the Netherlands.

Author

van der Plas JL, Kuiper VP, Bagchus WM, Bödding M, Yalkinoglu Ö, Tappert A, Seitzinger A, Spangenberg T, Bezuidenhout D, Wilkins J, Oeuvray C, Dhingra SK, Thathy V, Fidock DA, Smidt LCA, Roozen GVT, Koopman JPR, Lamers OAC, Sijtsma J, van Schuijlenburg R, Wessels E, Meij P, Kamerling IMC, Roestenberg M, and Khandelwal A

Subjects
Adult, Humans, Plasmodium falciparum, Netherlands, Healthy Volunteers, Double-Blind Method, Malaria, Falciparum drug therapy, Malaria, Falciparum prevention & control, Malaria, Falciparum parasitology, Antimalarials
Abstract

Background: Cabamiquine is a novel antimalarial that inhibits Plasmodium falciparum translation elongation factor 2. We investigated the causal chemoprophylactic activity and dose-exposure-response relationship of single oral doses of cabamiquine following the direct venous inoculation (DVI) of P falciparum sporozoites in malaria-naive, healthy volunteers., Methods: This was a phase 1b, randomised, double-blind, placebo-controlled, adaptive, dose-finding, single-centre study performed in Leiden, Netherlands. Malaria-naive, healthy adults aged 18-45 years were divided into five cohorts and randomly assigned (3:1) to receive cabamiquine or placebo. Randomisation was done by an independent statistician using codes in a permuted block schedule with a block size of four. Participants, investigators, and study personnel were masked to treatment allocation. A single, oral dose regimen of cabamiquine (200, 100, 80, 60, or 30 mg) or matching placebo was administered either at 2 h (early liver-stage) or 96 h (late liver-stage) after DVI. The primary endpoints based on a per-protocol analysis set were the number of participants who developed parasitaemia within 28 days of DVI, time to parasitaemia, number of participants with documented parasite blood-stage growth, clinical symptoms of malaria, and exposure-efficacy modelling. The impact of cabamiquine on liver stages was evaluated indirectly by the appearance of parasitaemia in the blood. The Clopper-Pearson CI (nominal 95%) was used to express the protection rate. The secondary outcomes were safety and tolerability, assessed in those who had received DVI and were administered one dose of the study intervention. The trial was prospectively registered on ClinicalTrials.gov (NCT04250363)., Findings: Between Feb 17, 2020 and April 29, 2021, 39 healthy participants were enrolled (early liver-stage: 30 mg [n=3], 60 mg [n=6], 80 mg [n=6], 100 mg [n=3], 200 mg [n=3], pooled placebo [n=6]; late liver-stage: 60 mg [n=3], 100 mg [n=3], 200 mg [n=3], pooled placebo [n=3]). A dose-dependent causal chemoprophylactic effect was observed, with four (67%) of six participants in the 60 mg, five (83%) of six participants in the 80 mg, and all three participants in the 100 and 200 mg cabamiquine dose groups protected from parasitaemia up to study day 28, whereas all participants in the pooled placebo and 30 mg cabamiquine dose group developed parasitaemia. A single, oral dose of 100 mg cabamiquine or higher provided 100% protection against parasitaemia when administered during early or late liver-stage malaria. The median time to parasitaemia in those with early liver-stage malaria was prolonged to 15, 22, and 24 days for the 30, 60, and 80 mg dose of cabamiquine, respectively, compared with 10 days for the pooled placebo. All participants with positive parasitaemia showed documented blood-stage parasite growth, apart from one participant in the pooled placebo group and one participant in the 30 mg cabamiquine group. Most participants did not exhibit any malaria symptoms in both the early and late liver-stage groups, and those reported were mild in severity. A positive dose-exposure-efficacy relationship was established across exposure metrics. The median maximum concentration time was 1-6 h, with a secondary peak observed between 6 h and 12 h in all cabamiquine dose groups (early liver-stage). All cabamiquine doses were safe and well tolerated. Overall, 26 (96%) of 27 participants in the early liver-stage group and ten (83·3%) of 12 participants in the late liver-stage group reported at least one treatment-emergent adverse event (TEAE) with cabamiquine or placebo. Most TEAEs were of mild severity, transient, and resolved without sequelae. The most frequently reported cabamiquine-related TEAE was headache. No dose-related trends were observed in the incidence, severity, or causality of TEAEs., Interpretation: The results from this study show that cabamiquine has a dose-dependent causal chemoprophylactic activity. Together with previously demonstrated activity against the blood stages combined with a half-life of more than 150 h, these results indicate that cabamiquine could be developed as a single-dose monthly regimen for malaria prevention., Funding: The healthcare business of Merck KGaA, Darmstadt, Germany., Competing Interests: Declaration of interests MB, ÖY, AT, AS, and AK are employed by the healthcare business of Merck KGaA, Darmstadt, Germany (the study sponsor). DB is employed by Merck Pty in Modderfontein, South Africa. CO and TS are employed by the Global Health Institute of Merck, Ares Trading in Eysins, Switzerland. WMB is a former (retired) employee of the Merck Institute for Pharmacometrics, Merck Serono in Lausanne, Switzerland. JW received funding for consulting with the healthcare business of Merck during the course of this study. All other authors declare no competing interests., (Copyright © 2023 Elsevier Ltd. All rights reserved.)

Published
2023
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38. Metabolism of (R)-Praziquantel versus the Activation of a Parasite Transient Receptor Potential Melastatin Ion Channel.

Author

Friedrich L, Park SK, Ballard P, Ho Baeurle TH, Maillard D, Bödding M, Keiser J, Marchant JS, and Spangenberg T

Subjects
Humans, Animals, Praziquantel pharmacology, Praziquantel chemistry, Schistosoma mansoni, Parasites, Transient Receptor Potential Channels, TRPM Cation Channels, Anthelmintics pharmacology, Anthelmintics therapeutic use
Abstract

Praziquantel (PZQ) is an essential anthelmintic drug recently established to be an activator of a Transient Receptor Potential Melastatin (TRPM PZQ ) ion channel in trematode worms. Bioinformatic, mutagenesis and drug metabolism work indicate that the cyclohexyl ring of PZQ is a key pharmacophore for activation of trematode TRPM PZQ , as well as serving as the primary site of oxidative metabolism which results in PZQ being a short-lived drug. Based on our recent findings, the hydrophobic cleft in schistosome TRPM PZQ defined by three hydrophobic residues surrounding the cyclohexyl ring has little tolerance for polarity. Here we evaluate the in vitro and in vivo activities of PZQ analogues with improved metabolic stability relative to the challenge of maintaining activity on the channel. Finally, an estimation of the respective contribution to the overall activity of both the parent and the main metabolite of PZQ in humans is reported., (© 2023 The Authors. ChemMedChem published by Wiley-VCH GmbH.)

Published
2023
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40. [ECMO support during the first two waves of the corona pandemic-a survey of high case volume centers in Germany].

Author

Supady A, Michels G, Lepper PM, Ferrari M, Wippermann J, Sabashnikov A, Thiele H, Hennersdorf M, Lahmer T, Boeken U, Gummert J, Tigges E, Muellenbach RM, Spangenberg T, Wengenmayer T, and Staudacher DL

Subjects
Female, Humans, Pandemics, Surveys and Questionnaires, Intensive Care Units, Germany, Extracorporeal Membrane Oxygenation methods
Abstract

Background: At the onset of the coronavirus pandemic, concerns were raised about sufficiency of available intensive care resources. In many places, routine interventions were postponed and criteria for the allocation of scarce resources were formulated. In Germany, some hospitals were at times seriously burdened during the course of the pandemic. Intensive care units in particular experienced a shortage of resources, which may have led to a restriction of services and a stricter indication setting for resource-intensive measures such as extracorporeal membrane oxygenation (ECMO). The aim of this work is to provide an overview of how these pressures were managed at large ECMO centers in Germany., Methods: One representative of each major ECMO referral center in Germany was invited to participate in an online survey in spring 2021., Results: Of 34 invitations that were sent out, the survey was answered by 23 participants. In all centers, routine procedures were postponed during the pandemic. Half of the centers increased the number of beds on which ECMO procedures could be offered. Nevertheless, in one-third of the centers, the start of at least one ECMO support was delayed because of a feared resource shortage. In 17% of centers, at least one patient was denied ECMO that he or she would have most likely received under prepandemic conditions., Conclusion: The results of this online survey indicate that the experienced pressures and resource constraints led some centers to be cautious about ECMO indications., (© 2022. The Author(s).)

Published
2023
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41. Propensity of selecting mutant parasites for the antimalarial drug cabamiquine.

Author

Stadler E, Maiga M, Friedrich L, Thathy V, Demarta-Gatsi C, Dara A, Sogore F, Striepen J, Oeuvray C, Djimdé AA, Lee MCS, Dembélé L, Fidock DA, Khoury DS, and Spangenberg T

Subjects
Animals, Mice, Amino Acids, Binding Sites, Disease Models, Animal, Antimalarials pharmacology, Parasites
Abstract

We report an analysis of the propensity of the antimalarial agent cabamiquine, a Plasmodium-specific eukaryotic elongation factor 2 inhibitor, to select for resistant Plasmodium falciparum parasites. Through in vitro studies of laboratory strains and clinical isolates, a humanized mouse model, and volunteer infection studies, we identified resistance-associated mutations at 11 amino acid positions. Of these, six (55%) were present in more than one infection model, indicating translatability across models. Mathematical modelling suggested that resistant mutants were likely pre-existent at the time of drug exposure across studies. Here, we estimated a wide range of frequencies of resistant mutants across the different infection models, much of which can be attributed to stochastic differences resulting from experimental design choices. Structural modelling implicates binding of cabamiquine to a shallow mRNA binding site adjacent to two of the most frequently identified resistance mutations., (© 2023. Springer Nature Limited.)

Published
2023
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42. Genetic profiles of Schistosoma haematobium parasites from Malian transmission hotspot areas.

Author

Agniwo P, Boissier J, Sidibé B, Dembélé L, Diakité A, Niaré DS, Akplogan A, Guindo H, Blin M, Dametto S, Ibikounlé M, Spangenberg T, and Dabo A

Subjects
Child, Animals, Humans, Schistosoma haematobium genetics, Disease Hotspot, Genetic Profile, Schistosoma genetics, Parasites, Schistosomiasis epidemiology, Schistosomiasis haematobia
Abstract

Background: Although schistosomiasis is a public health issue in Mali, little is known about the parasite genetic profile. The purpose of this study was to analyze the genetic profile of the schistosomes of Schistosoma haematobium group in school-aged children in various sites in Mali., Methods: Urine samples were collected from 7 to 21 November 2021 and subjected to a filtration method for the presence S. haematobium eggs. The study took place in two schistosomiasis endemic villages (Fangouné Bamanan and Diakalèl), qualified as hotspots according to the World Health Organization (WHO) definition. Molecular genotyping on both Cox1 and ITS2/18S was used for eggs' taxonomic assignation., Results: A total of 970 miracidia were individually collected from 63 school-aged children and stored on Whatman FTA cards for molecular analysis. After genotyping 42.0% (353/840) and 58.0% (487/840) of miracidia revealed Schistosoma bovis and S. haematobium Cox1 profiles, respectively; 95.7 (885/925) and 4.3% (40/925) revealed S. haematobium and S. haematobium/S. curassoni profiles for ITS/18S genes, respectively. There was a significant difference in the Cox1 and ITS2/18S profile distribution according to the village (P < 0.0001). Overall, 45.6% (360/789) were hybrids, of which 72.0% (322/447) were from Diakalèl. Three hybrids' profiles (Sb/Sc&#95;ShxSc with 2.3%; Sb/Sc&#95;ShxSh with 40.5%; Sh&#95;ShxSc with 2.8%) and one pure profile (Sh&#95;ShxSh with 54.4%) were identified., Conclusion: Our findings show, for the first time to our knowledge, high prevalence of hybrid schistosomes in Mali. More studies are needed on population genetics of schistosomes at the human and animal interface to evaluate the parasite's gene flow and its consequences on epidemiology of the disease as well as the transmission to humans., (© 2023. BioMed Central Ltd., part of Springer Nature.)

Published
2023
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43. Outcome of a polymer-free drug-coated coronary stent in bifurcation lesions-Pilot registry with serial OCT imaging.

Author

Wienemann H, Meincke F, Vach M, Heeger CH, Meyer A, Spangenberg T, Kuck KH, and Ghanem A

Subjects
Humans, Tomography, Optical Coherence, Coronary Vessels, Treatment Outcome, Coronary Angiography, Registries, Drug-Eluting Stents, Percutaneous Coronary Intervention, Coronary Artery Disease diagnostic imaging, Coronary Artery Disease surgery, Coronary Restenosis diagnostic imaging, Coronary Restenosis therapy
Abstract

Background: Polymer-free and carrier-free drug-coated stents (DCS) represent a novel therapeutic option for the treatment of coronary artery disease. The objective of this pilot registry is to evaluate the safety and efficacy of DCS implantation in bifurcation lesions., Methods: Overall, 23 consecutive patients with 24 lesions received a Biolimus A9-coated DCS for coronary bifurcation lesions. Patients were examined with quantitative coronary angiography (QCA) and optical coherence tomography (OCT) at 3-6 months of follow-up., Results: A total of 23 patients with 24 bifurcation lesions were included in this study. Nine (33.3%) lesions of eight patients revealed angiographical target lesion failure due to in-stent restenosis (ISR). In total, 19 patients with 20 bifurcation lesions were suitable for OCT analysis. A total of 2936 struts were analyzed and 14 struts (0.47%) were classified as malapposed. The mean luminal area (mm 2 ) was not different in lesions with ISR vs. lesions with no ISR (5.07 ± 2.0 vs. 5.73 ± 1.34, p = 0.39) at follow-up. Lesions with ISR showed higher mean neointimal burden (27.11 ± 10.59 vs. 13.93 ± 9.16%, respectively; p = 0.009). All of the patients who presented with significant ISR required percutaneous re-intervention., Conclusions: We observed a high rate of DCS ISR in bifurcation lesions, possibly related to increased inflammation and neoatherosclerosis. The small size of the study warrants careful interpretation of our results. Larger trials are necessary to expand knowledge of these findings., (© 2022. The Author(s), under exclusive licence to Springer Medizin Verlag GmbH, ein Teil von Springer Nature.)

Published
2023
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44. Anti-infectives Developed as Racemic Drugs in the 21st Century: Norm or Exception?

Author

Cabrera DG, Smith DA, Basarab GS, Duffy J, Spangenberg T, and Chibale K

Abstract

This viewpoint outlines the case for developing new chemical entities (NCEs) as racemates in infectious diseases and where both enantiomers and racemate retain similar on- and off-target activities as well as similar PK profiles. There are not major regulatory impediments for the development of a racemic drug, and minimizing the manufacturing costs becomes a particularly important objective when bringing an anti-infective therapeutic to the marketplace in the endemic settings of infectious diseases., Competing Interests: The authors declare the following competing financial interest(s): T.S. is an employee of Ares Trading SA, an affiliate of Merck KGaA, Darmstadt, Germany., (© 2023 The Authors. Published by American Chemical Society.)

Published
2023
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45. Perspective on Schistosomiasis Drug Discovery: Highlights from a Schistosomiasis Drug Discovery Workshop at Wellcome Collection, London, September 2022.

Author

Caldwell N, Afshar R, Baragaña B, Bustinduy AL, Caffrey CR, Collins JJ, Fusco D, Garba A, Gardner M, Gomes M, Hoffmann KF, Hsieh M, Lo NC, McNamara CW, Nono JK, Padalino G, Read KD, Roestenberg M, Spangenberg T, Specht S, and Gilbert IH

Subjects
Animals, London, Praziquantel pharmacology, Praziquantel therapeutic use, Schistosoma, Schistosomiasis drug therapy, Anthelmintics pharmacology, Anthelmintics therapeutic use
Abstract

In September 2022, the Drug Discovery Unit at the University of Dundee, UK, organised an international meeting at the Wellcome Collection in London to explore the current clinical situation and challenges associated with treating schistosomiasis. The aim of this meeting was to discuss the need for new treatments in view of the clinical situation and to ascertain what the key requirements would be for any potential new anti-schistosomals. This information will be essential to inform ongoing drug discovery efforts for schistosomiasis. We also discussed the potential drug discovery pathway and associated criteria for progressing compounds to the clinic. To date, praziquantel (PZQ) is the only drug available to treat all species causing schistosomiasis, but it is often unable to completely clear parasites from an infected patient, partially due to its inactivity against juvenile worms. PZQ-mediated mass drug administration campaigns conducted in endemic areas (e.g., sub-Saharan Africa, where schistosomiasis is primarily prevalent) have contributed to reducing the burden of disease but will not eliminate the disease as a public health problem. The potential for Schistosoma to develop resistance towards PZQ, as the sole treatment available, could become a concern. Consequently, new anthelmintic medications are urgently needed, and this Perspective aims to capture some of the learnings from our discussions on the key criteria for new treatments.

Published
2023
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46. [Extracorporeal Life Support in Critical Care Medicine].

Author

Ajouri J, Lepper PM, Spangenberg T, Schneider NRE, and Muellenbach RM

Subjects
Humans, Shock, Cardiogenic therapy, Shock, Cardiogenic etiology, Ventricular Function, Left, Critical Care, Retrospective Studies, Extracorporeal Membrane Oxygenation, Heart Arrest complications
Abstract

Veno-arterial extracorporeal life support (ECLS) may be indicated in patients with refractory heart failure. The list of conditions in which ECLS is successfully used is growing and includes cardiogenic shock following myocardial infarction, refractory cardiac arrest, septic shock with low cardiac output and severe intoxication. Femoral ECLS is the most common and often preferred ECLS-configuration in the emergency setting. Although femoral access is usually quick and easy to establish, it is also associated with specific adverse haemodynamic effects due to the direction of blood flow and access-site complications are inherent. Femoral ECLS provides adequate oxygen delivery and compensates for impaired cardiac output. However, retrograde blood flow into the aorta increases left ventricular afterload and may worsen left ventricular stroke work. Therefore, femoral ECLS is not equivalent to left ventricular unloading. Daily haemodynamic assessments are crucial and should include echocardiography and laboratory tests determining tissue oxygenation. Common complications include the harlequin-phenomenon, lower limb ischaemia or cerebral events and cannula site or intracranial bleeding. Despite a high incidence of complications and high mortality, ECLS is associated with survival benefits and better neurological outcomes in selected patient groups., Competing Interests: Erklärung zu finanziellen Interessen Forschungsförderung erhalten: nein; Honorar/geldwerten Vorteil für Referententätigkeit erhalten: nein; Bezahlter Berater/interner Schulungsreferent/Gehaltsempfänger: nein; Patent/Geschäftsanteile/Aktien (Autor/Partner, Ehepartner, Kinder) an im Bereich der Medizin aktiven Firma: nein; Patent/Geschäftsanteile/Aktien (Autor/Partner, Ehepartner, Kinder) an zu Sponsoren dieser Fortbildung bzw. durch die Fortbildung in ihren Geschäftsinteressen berührten Firma: nein Erklärung zu nichtfinanziellen Interessen Die Autorinnen/Autoren geben an, dass kein Interessenkonflikt besteht., (Thieme. All rights reserved.)

Published
2023
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47. Modulation of Host-Parasite Interactions with Small Molecules Targeting Schistosoma mansoni microRNAs.

Author

Hamway Y, Zimmermann K, Blommers MJJ, Sousa MV, Häberli C, Kulkarni S, Skalicky S, Hackl M, Götte M, Keiser J, da Costa CP, Spangenberg T, and Azzaoui K

Subjects
Animals, Host-Parasite Interactions, NF-kappa B analysis, Schistosoma mansoni genetics, Extracellular Vesicles chemistry, MicroRNAs genetics
Abstract

Parasites use different strategies of communication with their hosts. One communication channel that has been studied in recent years is the use of vesicle microRNAs to influence the host immune system by trematodes. sma-microRNA-10, secreted from Schistosoma mansoni , has been shown to influence the fate of host T-cells through manipulation of the NF-κB pathway. We have identified low molecular weight tool compounds that can interfere with this microRNA-mediated manipulation of the host immune system. We used a fragment-based screening approach by means of nuclear magnetic resonance (NMR) to identify binders to the precursor of the parasite sma-microRNA-10 present in their extracellular vesicles. The small fragments identified were used to select larger molecules. These molecules were shown to counteract the inhibition of NF-κB activity by sma-microRNA-10 in cell-based assays.

Published
2022
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48. Praziquantel Reduces Maternal Mortality and Offspring Morbidity by Enhancing Anti-Helminthic Immune Responses.

Author

Lacorcia M, Kugyelka R, Spechtenhauser L, Prodjinotho UF, Hamway Y, Spangenberg T, and da Costa CP

Subjects
Animals, Antibody Formation, Cytokines therapeutic use, Female, Humans, Maternal Mortality, Mebendazole therapeutic use, Mice, Morbidity, Praziquantel pharmacology, Praziquantel therapeutic use, Pregnancy, Schistosoma, Anthelmintics pharmacology, Anthelmintics therapeutic use, Schistosomiasis drug therapy
Abstract

Alongside the wide distribution throughout sub Saharan Africa of schistosomiasis, the morbidity associated with this chronic parasitic disease in endemic regions is often coupled with infection-driven immunomodulatory processes which modify inflammatory responses. Early life parasite exposure is theorized to drive immune tolerance towards cognate infection as well as bystander immune responses, beginning with in utero exposure to maternal infection. Considering that 40 million women of childbearing-age are at risk of infection worldwide, treatment with Praziquantel during pregnancy as currently recommended by WHO could have significant impact on disease outcomes in these populations. Here, we describe the effects of anthelminthic treatment on parasite-induced changes to fetomaternal cross talk in a murine model of maternal schistosomiasis. Praziquantel administration immediately prior to mating lead to clear re-awakening of maternal anti-parasite immune responses, with persistent maternal immune activation that included enhanced anti-schistosome cytokine responses. Clearance of parasites also improved capacity of dams to endure the additional pressure of pregnancy during infection. Maternal treatment also drove lasting functional alterations to immune system development of exposed offspring. Prenatal anthelminthic treatment skewed offspring immune responses towards parasite clearance and reduced morbidity during cognate infection. Maternal treatment also restored offspring protective IgE antibody responses directed against schistosome antigens, which were otherwise suppressed following exposure to untreated maternal infection. This was further associated with enhanced anti-schistosome cytokine responses from treatment-exposed offspring during infection. In the absence of cognate infection, exposed offspring further demonstrated imprinting across cellular populations. We provide further evidence that maternal treatment can restore a more normalized immune profile to such offspring exposed in utero to parasite infection, particularly in B cell populations, which may underlie improved responsiveness to cognate infection, and support the WHO recommendation of anthelminthic treatment during pregnancy., Competing Interests: TS is an employee of Ares Trading SA, an affiliate of Merck KGaA, Darmstadt, Germany. The remaining authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest. The authors declare that this study received funding from Merck KGaA, Darmstadt, Germany. The funder was involved in the design of the study, data interpretation and preparation of the manuscript., (Copyright © 2022 Lacorcia, Kugyelka, Spechtenhauser, Prodjinotho, Hamway, Spangenberg and da Costa.)

Published
2022
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49. Translation of liver stage activity of M5717, a Plasmodium elongation factor 2 inhibitor: from bench to bedside.

Author

Khandelwal A, Arez F, Alves PM, Badolo L, Brito C, Fischli C, Fontinha D, Oeuvray C, Prudêncio M, Rottmann M, Wilkins J, Yalkinoglu Ö, Bagchus WM, and Spangenberg T

Subjects
Animals, Humans, Liver parasitology, Peptide Elongation Factor 2, Plasmodium berghei, Antimalarials pharmacokinetics, Antimalarials therapeutic use, Malaria drug therapy, Malaria parasitology, Malaria prevention & control
Abstract

Background: Targeting the asymptomatic liver stage of Plasmodium infection through chemoprevention could become a key intervention to reduce malaria-associated incidence and mortality., Methods: M5717, a Plasmodium elongation factor 2 inhibitor, was assessed in vitro and in vivo with readily accessible Plasmodium berghei parasites. In an animal refinement, reduction, replacement approach, the in vitro IC 99 value was used to feed a Population Pharmacokinetics modelling and simulation approach to determine meaningful effective doses for a subsequent Plasmodium sporozoite-induced volunteer infection study., Results: Doses of 100 and 200 mg would provide exposures exceeding IC 99 in 96 and 100% of the simulated population, respectively., Conclusions: This approach has the potential to accelerate the search for new anti-malarials, to reduce the number of healthy volunteers needed in a clinical study and decrease and refine the animal use in the preclinical phase., (© 2022. The Author(s).)

Published
2022
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50. Pre-erythrocytic Activity of M5717 in Monotherapy and Combination in Preclinical Plasmodium Infection Models.

Author

Fontinha D, Arez F, Gal IR, Nogueira G, Moita D, Baeurle THH, Brito C, Spangenberg T, Alves PM, and Prudêncio M

Subjects
Drug Resistance, Drug Therapy, Combination, Humans, Antimalarials pharmacology, Antimalarials therapeutic use, Malaria drug therapy, Plasmodium
Abstract

Combination therapies have emerged to mitigate Plasmodium drug resistance, which has hampered the fight against malaria. M5717 is a potent multistage antiplasmodial drug under clinical development, which inhibits parasite protein synthesis. The combination of M5717 with pyronaridine, an inhibitor of hemozoin formation, displays potent activity against blood stage Plasmodium infection. However, the impact of this therapy on liver infection by Plasmodium remains unknown. Here, we employed a recently described 3D culture-based hepatic infection platform to evaluate the activity of the M5717-pyronaridine combination against hepatic infection by P. berghei . This effect was further confirmed in vivo by employing the C57BL/6J rodent Plasmodium infection model. Collectively, our data demonstrate that pyronaridine potentiates the activity of M5717 against P. berghei hepatic development. These preclinical results contribute to the validation of pyronaridine as a suitable partner drug for M5717, supporting the clinical evaluation of this novel antiplasmodial combination therapy.

Published
2022
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