YouTube video on ‘The First Mammals’

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Figure 1. Thrinaxodon, a burrowing synapsid from the Early Triassic was similar in size and proportion to the Late Permian ancestor of all archosauriformes, Youngoides (Fig. 2). These similar basal taxa were the genesis for all later mammals, dinosaurs and birds.  ” data-image-caption=”

Figure 1. Thrinaxodon, a burrowing synapsid from the Early Triassic was similar in size and proportion to the Late Permian ancestor of all archosauriformes, Youngoides (Fig. 2). These similar basal taxa were the genesis for all later mammals, dinosaurs and birds. 

” data-medium-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2016/03/thrinaxodon-youngoides.jpg?w=288″ data-large-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2016/03/thrinaxodon-youngoides.jpg?w=584″ tabindex=”0″ role=”button” class=”size-full wp-image-22335″ src=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2016/03/thrinaxodon-youngoides.jpg” alt=”Figure 1. Thrinaxodon, a burrowing synapsid from the Early Triassic was similar in size and proportion to the Late Permian ancestor of all archosauriformes, Youngoides (Fig. 2). These similar basal taxa were the genesis for all later mammals, dinosaurs and birds. ” width=”584″ height=”608″ />

Figure 1. Thrinaxodon, a burrowing synapsid from the Early Triassic was similar in size and proportion to the Late Permian ancestor of all archosauriformes, Youngoides (Fig. 2). These similar basal taxa were the genesis for all later mammals, dinosaurs and birds. From 2016.

Figure 2. Eomaia holotype exposed in dorsal view and reconstructed as originally published and revised here.

Figure 3. Monodelphis mother with her growing brood of young clinging to her fur and nipples. ” data-image-caption=”

Figure 3. Monodelphis mother with her growing brood of young clinging to her fur and nipples.

” data-medium-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2021/06/monodelphys_mom.jpg?w=300″ data-large-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2021/06/monodelphys_mom.jpg?w=584″ tabindex=”0″ role=”button” class=”size-full wp-image-56538″ src=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2021/06/monodelphys_mom.jpg” alt=”Figure 3. Monodelphis mother with her growing brood of young clinging to her fur and nipples.” width=”584″ height=”385″ />

Figure 3. Monodelphis mother with her growing brood of young clinging to her fur and nipples.

Figure 5. Repenomamus giganticus reconstructed. ” data-image-caption=”

Figure 5. Repenomamus giganticus reconstructed.

” data-medium-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2016/08/repenomamus-recon588.jpg?w=300″ data-large-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2016/08/repenomamus-recon588.jpg?w=584″ tabindex=”0″ role=”button” class=”size-full wp-image-23678″ src=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2016/08/repenomamus-recon588.jpg” alt=”Figure 5. Repenomamus giganticus reconstructed.” width=”584″ height=”238″ />

Figure 5. Repenomamus giganticus reconstructed.

Figure 2. A new reconstruction of the skull of Volaticotherium along with the skull of Morganucodon to scale. See text for details. ” data-image-caption=”

Figure 2. A new reconstruction of the skull of Volaticotherium along with the skull of Morganucodon to scale. See text for details.

” data-medium-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2018/08/volaticotherium_recon588.jpg?w=210″ data-large-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2018/08/volaticotherium_recon588.jpg?w=584″ tabindex=”0″ role=”button” class=”size-full wp-image-32266″ src=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2018/08/volaticotherium_recon588.jpg” alt=”Figure 2. A new reconstruction of the skull of Volaticotherium along with the skull of Morganucodon to scale. See text for details.” width=”584″ height=”836″ />

Figure 6. A new reconstruction of the skull of Volaticotherium along with the skull of Morganucodon to scale. Note the odd molars. No descendants are known yet.

Figure 1. Zhangheotherium reconstructed. The tail is unknown. The high scapulae indicate great strength in the pectoral region, likely for arboreal locomotion in a taxon of this size. Zhangheotherium nests as a basal pangolin. It was preserved in ventral view. Here the epipubes are identified as pubes, which is otherwise not shown. ” data-image-caption=”

Figure 1. Zhangheotherium reconstructed. The tail is unknown. The high scapulae indicate great strength in the pectoral region, likely for arboreal locomotion in a taxon of this size. Zhangheotherium nests as a basal pangolin. It was preserved in ventral view. Here the epipubes are identified as pubes, which is otherwise not shown.

” data-medium-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2016/08/zhangheotherium-recon5881.jpg?w=300″ data-large-file=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2016/08/zhangheotherium-recon5881.jpg?w=584″ tabindex=”0″ role=”button” class=”size-full wp-image-23783″ src=”https://pterosaurheresies.wordpress.com/wp-content/uploads/2016/08/zhangheotherium-recon5881.jpg” alt=”Figure 1. Zhangheotherium reconstructed. The tail is unknown. The high scapulae indicate great strength in the pectoral region, likely for arboreal locomotion in a taxon of this size. Zhangheotherium nests as a basal pangolin. It was preserved in ventral view. Here the epipubes are identified as pubes, which is otherwise not shown.” width=”584″ height=”252″ />

Figure 7. Zhangheotherium reconstructed. The tail is unknown. The high scapulae indicate great strength in the pectoral region, likely for arboreal locomotion in a taxon of this size. Zhangheotherium nests as a basal pangolin. It was preserved in ventral view. Here the epipubes are identified as pubes, which is otherwise not shown.