Google scholar
Researchgate
Contact me (Dario.alayon@gmail.com) for PDF reprints
Peer-reviewed
2021
[39] Kvamme T, Mandelshtam M, Salnitska M, Ojeda DI & Lindelöw Å (2021) A new cryptic Trypophloeus Fairmaire, 1868 species in Northern Fennoscandia (Coleoptera, Curculionidae) revealed by DNA analyses. Norwegian Journal of Entomology 68:44–66.
[38] García-Mir Lluís, Ojeda DI, Fuertes-Aguilar J (2021) The complete chloroplast genome of Malva wigandii (Alef.) M.F. Ray (Malvaceae, Malvoideae). Mitochondrial DNa partB 6:1181-1182.
[37] Jaen-Molina R, Marrero-Rodriguez A, Caujape-Castells J, Ojeda DI (2021) Molecular phylogenetics of Lotus (Leguminosae) with emphasis in the tempo and patterns of colonizations in the Macaronesia region. Molecular Phylogenetics and Evolution 154:106970.
2020
[36] de la Estrella M, Cervantes S, Janssens S, Forest F, Hardy O, Ojeda DI (2020) The impact of rainforest area reduction in the Guineo-Congolian region on the tempo of diversification and habitat shifts in the Berlinia clade (Leguminosae). Journal of Biogeography 47:7228-2740.
[35] Koenen EJM, Ojeda DI, Steeves R, Migliore J, Bakker FT, Wieringa JJ, Kidner C, Hardy OJ, Pennington RT, Herendeen PS, Bruneau A, Hughes CE (2020) The origin of the Legumes is a complex paleopolyploid phylogenomic tangle closely associated with the Cretaceous-Paleogene (K-Pg) mass extinction event. Systematic Biology 70:508-526.
[34] Demenou BB, Migliore J, Heuertz M, Monthe FS, Ojeda DI, Wieringa JJ, Dauby G, Albreht L, Boom A, Hardy OJ (2020) Plastome phylogeography in two African rain forest legume trees reveals that Dahomey Gap populations originate from the Cameroon volcanic line. Molecular Phylogenetics and Evolution 150: 106854.
[33] Herrero ML, Brurberg MB, Ojeda DI, Roleda MY (2020) Occurrence and pathogenicity of Pythium (Oomycota) on Ulva species (Chlorophyta) at different salinities. Algae 35: 79-89.
[32] Koenen EJM, Ojeda DI, Steeves R, Migliore J, Bakker FT, Wieringa JJ, Kidner C, Hardy OJ, Pennington RT, Bruneau A, Hughes CE (2020) Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies. New Phytologist 225: 1355-1369.
2019
[31] Ojeda DI, Mattila T, Ruttink T, Kujala S, Karkkainen K, Pekka-Verta J, Pyhajarvi T (2019) Utilization of tissue ploidy level variation in de novo transcriptome assembly of Pinus sylvesris. G3:Genes, Genomes, Genetics 9: 3409-3421.
[30] de la Estrella M, Wieringa J, Breteler F, Ojeda DI (2019) Re-evaluation of the genus Englerodendron (Leguminosae-Detarioideae), including Isomacrolobium and Pseudomacrolobium. Australian Systematic Botany 32: 564-571.
[29] Tsui, CKM, Beauseigle, S, Ojeda, DI, Rice AV, Cooke JEK, Sperling FAH, Roe AD, Hamelin RC (2019) Fine-scale genetic structure and relatedness in fungi associated with the mountain pine beetle. Canadian Journal of Forest Research 48: 933-941.
[28] Ojeda DI, Koenen E, Cervantes-Arango S, de la Estrella M, Banguera-Hinestroza, Janssens S, Migliore J, Demenou B, Bruneau A, Forest F, and Hardy OJ (2019) Phylogenomic analyses reveal an exceptionally high number of evolutionary shifts in a florally diverse clade of African legumes. Molecular Phylogenetics and Evolution 137: 156-167.
[27] Feau N, Ojeda DI, Beauseigle S, Bilodeau GJ, Brar A, Cervantes-Arango S, Dale AL, Dhillon B, Hammett C, Herath P, Shamoun SF, Tsui CKM, Tanguay P, and Hamelin RH (2019) Genome-enhanced detection and identification of the sudden oak death pathogen Phytophthora ramorum and the Port Orford cedar root pathogen Phytophthora lateralis. Plant Pathology 68: 878-888.
[26] Neji M, Gorel A, Ojeda DI, Duminil J, Kastally C, Steppe K, Fayolle A and Hardy OJ (2019) Comparative analysis of two sister Erythrophelum species (Leguminosae) reveal constrasting transcriptome-wide responses to early drought stress. Gene 694: 50-62.
2018
[25] Feau N, Beauseigle S, Bergeron M, Bilodeau GJ, Birol I, Cervantes-Arango S, Dhillon B, Dale AL, Herath P, Jones SJM, Lamarche J, Ojeda DI, Sakalidis ML, Taylor G, Tsui CKM, Uzunovic A, Yueh H, Tanguay P, Hamelin RC. (2018) Genome-enhanced detection and identification (GEDI) of plant pathogens. PeerJ 6: e4392.
[24] Yang JY, Ojeda DI, Santos-Guerra A, Jaén-Molina R, Caujape-Castells J and Cronk QC (2018) Population differentiation in relation to conservation: nuclear microsatellite variation in the Canary Island endemic Lotus sessilifolius (Fabaceae). Conservation Genetic Resources. 10: 219-227.
2017
[23] Boehn MA, Ojeda DI and Cronk QC (2017) Dissecting the 'bacon and eggs' phenotype: transcriptomics of post-anthesis colour change in Lotus. Annals of Botany 120:563–575.
[22] Ojeda DI, Tsui CKM, Feau N, Capron A, Dhillon B, Zhang Y, Massoumi AS, Boone CK, Carroll, AL, Cooke JEK, Roe AD, Sperling FAH. and Hamelin RC (2017) Genetic and genomic evidence of niche partitioning and adaptive radiation in mountain pine beetle fungal symbionts. Molecular Ecology 26:2077-2091.
[21] Legume Phylogeny Working Group (LPWG) (2017) A new subfamily classification of the Leguminosae based on a taxonomically comprehensive phylogeny. Taxon 66:44-77.
[20] Ojeda DI, Jaén-Molina R, Santos-Guerra A, Caujape-Castells J and Cronk QC (2017) Temporal, but not spatial, changes in expression patterns of petal identity genes are associated with loss of papillate conical cells and the shift to bird pollination in Macaronesian Lotus (Leguminosae). Plant Biology 19:420-427.
2016
[19] Moraes AP, Olmos Simões A, Ojeda DI, de Barros F, Forni-Martins ER (2016) Detecting mechanisms of karyotype evolution in Heterotaxis (Orchidaceae). PLoS ONE 11: e0165960.
[18] Ojeda DI, Valido A, Fernández de Castro AJ, Ortega-Olivencia A, Fuertes-Aguilar J, Carvalho JA, Santos-Guerra A (2016) Pollinator shifts drive petal epidermal evolution on the Macaronesian Islands bird-flowered species. Biology Letters 12: 20160022.
[17] Stewart A, Zahiri D, Djoumad R, Freschi A, Lamarche, J, Holden D, Cervantes, S, Ojeda DI, et al (2016) A multi-species TaqMan PCR assay for the identification of Asian gypsy moths (Lymantria spp.) and other invasive Lymantriines of biosecurity concern to North America. PLoS ONE 11: e0160878.
[16] Herath P, Beauseigle S, Dhillon D, Ojeda DI, Bilodeau, B, et al. (2016) Anthropogenic signature in the incidence and distribution of an emerging pathogen of poplars. Biological Invasions 18: 1147–1161.
2015
[15] Lamarche J, Potvin A, Pelletier G, Stewart D, Feau N, Ojeda, DI, et al. (2015) Molecular detection of 10 of the most unwanted alien forest pathogens in Canada using real-time PCR. PLoS ONE 10: e0134265.
2014
[14] Ojeda, D.I., Santos-Guerra, A., Oliva-Tejera, F., Jaén -Molina, R. Caujapé-Castilles, J. Marrero, A. Cronk, Q.C.B. (2014) DNA barcodes successfully identified Macaronesian Lotus (Leguminosae) species within early diverged lineages of Cape Verde and mainland Africa. AoB Plants. doi: 10.1093/aobpla/plu050.
2013
[13]. Ojeda, D.I., Dhillon, B., Tsui, K.M.C. and Hamelin, R. (2013) Single-nucleotide polymorphism discovery in Leptographium longiclavatum, a mountain pine beetle-associated symbiotic fungus, using whole-genome resequencing. Molecular Ecology Resources 14: 401-410.
[12]. Ojeda, D.I. (2013) The Macaronesian bird-flowered element as a model system to study the evolution of ornithophilous floral traits. Vieraea 41: 73-89 .
[11]. Ojeda, D.I., Santos-Guerra, A., Oliva-Tejera, F., Valido, A., Jaén-Molina, R. Xinxin, X., Caujapé-Castilles, J. Marrero, A. Cronk, Q.C.B. (2013) Bird-pollinated Macaronesian Lotus (Leguminosae) evolved within a group of entomophilous ancestors with post-anthesis flower colour change. Perspectives in Plant Ecology, Evolution and Systematics 15: 193-204.
2012
[10]. Ojeda, I., Santos-Guerra, A., Oliva-Tejera, F., Jaén -Molina, R. Caujapé-Castilles, J. Marrero, A. Cronk, Q.C.B. (2012) Comparative micromorphology of petals in Macaronesian Lotus (Leguminosae) reveals a loss of papillose conical cells during the evolution of bird pollination. International Journal of Plant Sciences 173: 365-374 (Journal cover).
[9]. Ojeda, I., Santos-Guerra, A., Oliva-Tejera, F., Jaén -Molina, R. Caujapé-Castilles, J. Marrero, A. Cronk, Q.C.B. (2012) The origin of bird pollination in Macaronesian Lotus (Loteae, Leguminosae). Molecular Phylogenetics and Evolution 62:306–318.
2011
[8]. Ojeda, I., Santos-Guerra, A. (2011) The intersection of conservation and horticulture: bird-pollinated Lotus species from the Canary Islands (Leguminosae). Biodiversity and Conservation 20:3501-3516.
2009 and before
[7]. Ojeda, I, Francisco-Ortega, J. and Cronk Q.C.B. (2009) Evolution of petal epidermal micromorphology in Leguminosae and its use as a marker of petal identity. Annals of Botany 104: 1099-1110.
[6]. Ojeda, I, Carnevali, G, and Romero-Gonzales, G. (2009) Nitidobulbon, a new genus of Maxillariinae (Orchidaceae). Novon 19, 96-101.
[5]. Cronk, Q.C.B, Ojeda, I. (2008) Bird-pollinated flowers in an evolutionary and molecular context. Journal of Experimental Botany 59: 715-727.
[4]. Blanco, M.A., Carnevali, G, Whitten, M., Singer, R., Koehler, S., Williams, N.H., Ojeda I, Neubig, K.M. and Endara, L. (2007) Generic realignments in Maxillariinae (Orchidaceae). Lankesteriana 7: 515-537.
[3]. Cronk, Q.C.B, Ojeda, I, and Pennington, R.T. (2006) Legume comparative genomics: progress in phylogenetics and phylogenomics. Current Opinion in Plant Biology 9: 99-103.
[2]. Ojeda I, Carnevali, G. and Romero, G. (2005) New species and combinations in Heterotaxis Lindley (Maxillariinae: Orchidaceae). Novon 15: 572-582.
[1]. Ojeda I, Carnevali G, Whitten M. and Williams N. (2003) Phylogeny of Heterotaxis Lindl. complex (Maxillariinae): evolution of vegetative architecture and pollination syndromes. Lankesteriana 7: 45-47.
Book contributions
[4]. Carnevali, G. and Ojeda I. (2005) Caulathron. In: Vanishing Beauty. Native Costa Rican Orchids Vol. 1. Pupplin F. (eds). Editorial de la Universidad de Costa Rica (Ed), 92-95.
[3]. Ojeda I, and Carnevali, G. (2005) Heterotaxis. In: Vanishing Beauty.Native Costa Rican Orchids Vol. 1. Pupplin F. (eds). Editorial de la Universidad de Costa Rica (Ed), 364-367.
[2]. Ojeda, I. Carnevali, G., Whitten, M. and Pridgeon, A. (2009) Heterotaxis Lindl. In Genera Orchidacearum 5 Epidendroideae
(Part II). Pridgeon, A.M., Cribb, P.J., Chase, M.W. and Rasmussen, F.N. (eds). Oxford University Press (Ed), 147-151.
[1]. Ojeda, I., Carnevali, G., Pridgeon, A. M., Veitch, N.C. and Grayer, R.J. (2009) Nitidobulbon I. Ojeda, Carnevali & G. A. Romero. In Genera Orchidacearum 5, Epidendroideae (Part II). Pridgeon, A.M., Cribb, P.J., Chase, M.W. and Rasmussen, F.N. (eds). Oxford University Press (Ed), 183-187.
Non peer-reviewed articles
Ojeda, I. and Cronk, Q.C.B. (2006) Changes in flower morphology are associated with differences in epidermal cell type on the petals of two species of Lotus (Leguminosae) with different pollination syndromes. In 1st Mexican Conference of Graduate Students and Researchers in Canada (FEMEX 2006), Ottawa, ON.
Researchgate
Contact me (Dario.alayon@gmail.com) for PDF reprints
Peer-reviewed
2021
[39] Kvamme T, Mandelshtam M, Salnitska M, Ojeda DI & Lindelöw Å (2021) A new cryptic Trypophloeus Fairmaire, 1868 species in Northern Fennoscandia (Coleoptera, Curculionidae) revealed by DNA analyses. Norwegian Journal of Entomology 68:44–66.
[38] García-Mir Lluís, Ojeda DI, Fuertes-Aguilar J (2021) The complete chloroplast genome of Malva wigandii (Alef.) M.F. Ray (Malvaceae, Malvoideae). Mitochondrial DNa partB 6:1181-1182.
[37] Jaen-Molina R, Marrero-Rodriguez A, Caujape-Castells J, Ojeda DI (2021) Molecular phylogenetics of Lotus (Leguminosae) with emphasis in the tempo and patterns of colonizations in the Macaronesia region. Molecular Phylogenetics and Evolution 154:106970.
2020
[36] de la Estrella M, Cervantes S, Janssens S, Forest F, Hardy O, Ojeda DI (2020) The impact of rainforest area reduction in the Guineo-Congolian region on the tempo of diversification and habitat shifts in the Berlinia clade (Leguminosae). Journal of Biogeography 47:7228-2740.
[35] Koenen EJM, Ojeda DI, Steeves R, Migliore J, Bakker FT, Wieringa JJ, Kidner C, Hardy OJ, Pennington RT, Herendeen PS, Bruneau A, Hughes CE (2020) The origin of the Legumes is a complex paleopolyploid phylogenomic tangle closely associated with the Cretaceous-Paleogene (K-Pg) mass extinction event. Systematic Biology 70:508-526.
[34] Demenou BB, Migliore J, Heuertz M, Monthe FS, Ojeda DI, Wieringa JJ, Dauby G, Albreht L, Boom A, Hardy OJ (2020) Plastome phylogeography in two African rain forest legume trees reveals that Dahomey Gap populations originate from the Cameroon volcanic line. Molecular Phylogenetics and Evolution 150: 106854.
[33] Herrero ML, Brurberg MB, Ojeda DI, Roleda MY (2020) Occurrence and pathogenicity of Pythium (Oomycota) on Ulva species (Chlorophyta) at different salinities. Algae 35: 79-89.
[32] Koenen EJM, Ojeda DI, Steeves R, Migliore J, Bakker FT, Wieringa JJ, Kidner C, Hardy OJ, Pennington RT, Bruneau A, Hughes CE (2020) Large‐scale genomic sequence data resolve the deepest divergences in the legume phylogeny and support a near‐simultaneous evolutionary origin of all six subfamilies. New Phytologist 225: 1355-1369.
2019
[31] Ojeda DI, Mattila T, Ruttink T, Kujala S, Karkkainen K, Pekka-Verta J, Pyhajarvi T (2019) Utilization of tissue ploidy level variation in de novo transcriptome assembly of Pinus sylvesris. G3:Genes, Genomes, Genetics 9: 3409-3421.
[30] de la Estrella M, Wieringa J, Breteler F, Ojeda DI (2019) Re-evaluation of the genus Englerodendron (Leguminosae-Detarioideae), including Isomacrolobium and Pseudomacrolobium. Australian Systematic Botany 32: 564-571.
[29] Tsui, CKM, Beauseigle, S, Ojeda, DI, Rice AV, Cooke JEK, Sperling FAH, Roe AD, Hamelin RC (2019) Fine-scale genetic structure and relatedness in fungi associated with the mountain pine beetle. Canadian Journal of Forest Research 48: 933-941.
[28] Ojeda DI, Koenen E, Cervantes-Arango S, de la Estrella M, Banguera-Hinestroza, Janssens S, Migliore J, Demenou B, Bruneau A, Forest F, and Hardy OJ (2019) Phylogenomic analyses reveal an exceptionally high number of evolutionary shifts in a florally diverse clade of African legumes. Molecular Phylogenetics and Evolution 137: 156-167.
[27] Feau N, Ojeda DI, Beauseigle S, Bilodeau GJ, Brar A, Cervantes-Arango S, Dale AL, Dhillon B, Hammett C, Herath P, Shamoun SF, Tsui CKM, Tanguay P, and Hamelin RH (2019) Genome-enhanced detection and identification of the sudden oak death pathogen Phytophthora ramorum and the Port Orford cedar root pathogen Phytophthora lateralis. Plant Pathology 68: 878-888.
[26] Neji M, Gorel A, Ojeda DI, Duminil J, Kastally C, Steppe K, Fayolle A and Hardy OJ (2019) Comparative analysis of two sister Erythrophelum species (Leguminosae) reveal constrasting transcriptome-wide responses to early drought stress. Gene 694: 50-62.
2018
[25] Feau N, Beauseigle S, Bergeron M, Bilodeau GJ, Birol I, Cervantes-Arango S, Dhillon B, Dale AL, Herath P, Jones SJM, Lamarche J, Ojeda DI, Sakalidis ML, Taylor G, Tsui CKM, Uzunovic A, Yueh H, Tanguay P, Hamelin RC. (2018) Genome-enhanced detection and identification (GEDI) of plant pathogens. PeerJ 6: e4392.
[24] Yang JY, Ojeda DI, Santos-Guerra A, Jaén-Molina R, Caujape-Castells J and Cronk QC (2018) Population differentiation in relation to conservation: nuclear microsatellite variation in the Canary Island endemic Lotus sessilifolius (Fabaceae). Conservation Genetic Resources. 10: 219-227.
2017
[23] Boehn MA, Ojeda DI and Cronk QC (2017) Dissecting the 'bacon and eggs' phenotype: transcriptomics of post-anthesis colour change in Lotus. Annals of Botany 120:563–575.
[22] Ojeda DI, Tsui CKM, Feau N, Capron A, Dhillon B, Zhang Y, Massoumi AS, Boone CK, Carroll, AL, Cooke JEK, Roe AD, Sperling FAH. and Hamelin RC (2017) Genetic and genomic evidence of niche partitioning and adaptive radiation in mountain pine beetle fungal symbionts. Molecular Ecology 26:2077-2091.
[21] Legume Phylogeny Working Group (LPWG) (2017) A new subfamily classification of the Leguminosae based on a taxonomically comprehensive phylogeny. Taxon 66:44-77.
[20] Ojeda DI, Jaén-Molina R, Santos-Guerra A, Caujape-Castells J and Cronk QC (2017) Temporal, but not spatial, changes in expression patterns of petal identity genes are associated with loss of papillate conical cells and the shift to bird pollination in Macaronesian Lotus (Leguminosae). Plant Biology 19:420-427.
2016
[19] Moraes AP, Olmos Simões A, Ojeda DI, de Barros F, Forni-Martins ER (2016) Detecting mechanisms of karyotype evolution in Heterotaxis (Orchidaceae). PLoS ONE 11: e0165960.
[18] Ojeda DI, Valido A, Fernández de Castro AJ, Ortega-Olivencia A, Fuertes-Aguilar J, Carvalho JA, Santos-Guerra A (2016) Pollinator shifts drive petal epidermal evolution on the Macaronesian Islands bird-flowered species. Biology Letters 12: 20160022.
[17] Stewart A, Zahiri D, Djoumad R, Freschi A, Lamarche, J, Holden D, Cervantes, S, Ojeda DI, et al (2016) A multi-species TaqMan PCR assay for the identification of Asian gypsy moths (Lymantria spp.) and other invasive Lymantriines of biosecurity concern to North America. PLoS ONE 11: e0160878.
[16] Herath P, Beauseigle S, Dhillon D, Ojeda DI, Bilodeau, B, et al. (2016) Anthropogenic signature in the incidence and distribution of an emerging pathogen of poplars. Biological Invasions 18: 1147–1161.
2015
[15] Lamarche J, Potvin A, Pelletier G, Stewart D, Feau N, Ojeda, DI, et al. (2015) Molecular detection of 10 of the most unwanted alien forest pathogens in Canada using real-time PCR. PLoS ONE 10: e0134265.
2014
[14] Ojeda, D.I., Santos-Guerra, A., Oliva-Tejera, F., Jaén -Molina, R. Caujapé-Castilles, J. Marrero, A. Cronk, Q.C.B. (2014) DNA barcodes successfully identified Macaronesian Lotus (Leguminosae) species within early diverged lineages of Cape Verde and mainland Africa. AoB Plants. doi: 10.1093/aobpla/plu050.
2013
[13]. Ojeda, D.I., Dhillon, B., Tsui, K.M.C. and Hamelin, R. (2013) Single-nucleotide polymorphism discovery in Leptographium longiclavatum, a mountain pine beetle-associated symbiotic fungus, using whole-genome resequencing. Molecular Ecology Resources 14: 401-410.
[12]. Ojeda, D.I. (2013) The Macaronesian bird-flowered element as a model system to study the evolution of ornithophilous floral traits. Vieraea 41: 73-89 .
[11]. Ojeda, D.I., Santos-Guerra, A., Oliva-Tejera, F., Valido, A., Jaén-Molina, R. Xinxin, X., Caujapé-Castilles, J. Marrero, A. Cronk, Q.C.B. (2013) Bird-pollinated Macaronesian Lotus (Leguminosae) evolved within a group of entomophilous ancestors with post-anthesis flower colour change. Perspectives in Plant Ecology, Evolution and Systematics 15: 193-204.
2012
[10]. Ojeda, I., Santos-Guerra, A., Oliva-Tejera, F., Jaén -Molina, R. Caujapé-Castilles, J. Marrero, A. Cronk, Q.C.B. (2012) Comparative micromorphology of petals in Macaronesian Lotus (Leguminosae) reveals a loss of papillose conical cells during the evolution of bird pollination. International Journal of Plant Sciences 173: 365-374 (Journal cover).
[9]. Ojeda, I., Santos-Guerra, A., Oliva-Tejera, F., Jaén -Molina, R. Caujapé-Castilles, J. Marrero, A. Cronk, Q.C.B. (2012) The origin of bird pollination in Macaronesian Lotus (Loteae, Leguminosae). Molecular Phylogenetics and Evolution 62:306–318.
2011
[8]. Ojeda, I., Santos-Guerra, A. (2011) The intersection of conservation and horticulture: bird-pollinated Lotus species from the Canary Islands (Leguminosae). Biodiversity and Conservation 20:3501-3516.
2009 and before
[7]. Ojeda, I, Francisco-Ortega, J. and Cronk Q.C.B. (2009) Evolution of petal epidermal micromorphology in Leguminosae and its use as a marker of petal identity. Annals of Botany 104: 1099-1110.
[6]. Ojeda, I, Carnevali, G, and Romero-Gonzales, G. (2009) Nitidobulbon, a new genus of Maxillariinae (Orchidaceae). Novon 19, 96-101.
[5]. Cronk, Q.C.B, Ojeda, I. (2008) Bird-pollinated flowers in an evolutionary and molecular context. Journal of Experimental Botany 59: 715-727.
[4]. Blanco, M.A., Carnevali, G, Whitten, M., Singer, R., Koehler, S., Williams, N.H., Ojeda I, Neubig, K.M. and Endara, L. (2007) Generic realignments in Maxillariinae (Orchidaceae). Lankesteriana 7: 515-537.
[3]. Cronk, Q.C.B, Ojeda, I, and Pennington, R.T. (2006) Legume comparative genomics: progress in phylogenetics and phylogenomics. Current Opinion in Plant Biology 9: 99-103.
[2]. Ojeda I, Carnevali, G. and Romero, G. (2005) New species and combinations in Heterotaxis Lindley (Maxillariinae: Orchidaceae). Novon 15: 572-582.
[1]. Ojeda I, Carnevali G, Whitten M. and Williams N. (2003) Phylogeny of Heterotaxis Lindl. complex (Maxillariinae): evolution of vegetative architecture and pollination syndromes. Lankesteriana 7: 45-47.
Book contributions
[4]. Carnevali, G. and Ojeda I. (2005) Caulathron. In: Vanishing Beauty. Native Costa Rican Orchids Vol. 1. Pupplin F. (eds). Editorial de la Universidad de Costa Rica (Ed), 92-95.
[3]. Ojeda I, and Carnevali, G. (2005) Heterotaxis. In: Vanishing Beauty.Native Costa Rican Orchids Vol. 1. Pupplin F. (eds). Editorial de la Universidad de Costa Rica (Ed), 364-367.
[2]. Ojeda, I. Carnevali, G., Whitten, M. and Pridgeon, A. (2009) Heterotaxis Lindl. In Genera Orchidacearum 5 Epidendroideae
(Part II). Pridgeon, A.M., Cribb, P.J., Chase, M.W. and Rasmussen, F.N. (eds). Oxford University Press (Ed), 147-151.
[1]. Ojeda, I., Carnevali, G., Pridgeon, A. M., Veitch, N.C. and Grayer, R.J. (2009) Nitidobulbon I. Ojeda, Carnevali & G. A. Romero. In Genera Orchidacearum 5, Epidendroideae (Part II). Pridgeon, A.M., Cribb, P.J., Chase, M.W. and Rasmussen, F.N. (eds). Oxford University Press (Ed), 183-187.
Non peer-reviewed articles
Ojeda, I. and Cronk, Q.C.B. (2006) Changes in flower morphology are associated with differences in epidermal cell type on the petals of two species of Lotus (Leguminosae) with different pollination syndromes. In 1st Mexican Conference of Graduate Students and Researchers in Canada (FEMEX 2006), Ottawa, ON.