An Expanded View on the Morphological Diversity of Long-Nosed Antlion Larvae Further Supports a Decline of Silky Lacewings in the Past 100 Million Years

Simple Summary The insect group Neuroptera (lacewings) is often claimed to have been more diverse in the past than today. The same appears to have also been the case not only for the entire group Neuroptera, but also for several of its ingroups. Silky lacewings (Psychopsidae) are represented by relatively few species today. Their larvae, also called long-nosed antlions, can easily be identified by the following characteristics: they resemble antlion larvae, lack teeth in their stylets (mouthparts for catching prey), have trumpet-shaped attachment structures on their legs, and have prominent forward-directed upper lips (labra, singular labrum). Therefore, these larvae can also be recognised in the fossil record. An earlier study demonstrated a decline in the morphological diversity of long-nosed antlion larvae over the past 100 million years. Here, we report several dozen new fossil long-nosed antlion larvae. With these, we expand the earlier quantitative analysis. Moreover, in this study, we can show that the morphological diversity of long-nosed antlion larvae has decreased over the past 100 million years. However, we apparently do not have the full original morphological diversity of long-nosed antlions available, as there is no sign of visible saturation yet. Abstract Lacewings have been suggested to be a relict group. This means that the group of lacewings, Neuroptera, should have been more diverse in the past, which also applies to many ingroups of Neuroptera. Psychopsidae, the group of silky lacewings, is one of the ingroups of Neuroptera which is relatively species-poor in the modern fauna. Larvae of the group Psychopsidae, long-nosed antlions, can be easily identified as such in being larvae of antlion-like lacewings without teeth in their stylets (=compound structure of mandible and maxilla), with empodia (=attachment structures on legs) and with a prominent forward-protruding labrum. Therefore, such larvae can also be recognised in the fossil record. An earlier study demonstrated a decline in the morphological diversity of long-nosed antlion larvae over the past 100 million years. Here, we report several dozen new long-nosed antlion larvae and expand the earlier quantitative study. Our results further corroborate the decline of silky lacewings. Yet, a lack of an indication of saturation indicates that we have still not approached the original diversity of long-nosed antlions in the Cretaceous.


Introduction
The term "biodiversity" describes the overall variety of organisms around the world or in a certain habitat and plays an important role for our ecosystems. For years, people have seen a decline of biodiversity in different ecosystems [1][2][3][4][5][6][7][8][9][10], resulting in various efforts to protect species and their habitats. Most decline can be seen among representatives of the group Insecta, such as bees, beetles, or butterflies [2,5]. All of these play an important role (2) Specimen 54 (PED 0267) is preserved in Cretaceous Myanmar amber ( Figure 1E). Only the head capsule is present, but it is largely covered by dirt or debris concealing the outer rim and labrum. The specimen has an estimated length of 14 mm. This specimen was not included in the final analysis. (3) Specimen 55 (PED 0322) is preserved in Cretaceous Myanmar amber. Both lateral sides are accessible. The head is only accessible in the lateral view ( Figure 2F,G). The labrum seems to have a triangular shape in the dorsal view. The antennae bear prominent setae at the distal ends. Trumpet-shaped empodia at the end of the locomotory (2) Specimen 54 (PED 0267) is preserved in Cretaceous Myanmar amber ( Figure 1E). Only the head capsule is present, but it is largely covered by dirt or debris concealing the outer rim and labrum. The specimen has an estimated length of 14 mm. This specimen was not included in the final analysis.
(3) Specimen 55 (PED 0322) is preserved in Cretaceous Myanmar amber. Both lateral sides are accessible. The head is only accessible in the lateral view ( Figure 2F,G). The labrum seems to have a triangular shape in the dorsal view. The antennae bear prominent setae at the distal ends. Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 2H). The specimen has an approximate length of 3.9 mm. This specimen was not included in the final analysis.  Figure 3A) and ventral ( Figure 3B,C) sides are accessible. The labrum is trident-like with a larger spine-like protrusion in the middle, but with two smaller spinelike protrusions next to the large spine on each side ( Figure 3D,E); hence, it is not a trident in the strict sense, as it has five and not three prongs. No empodium is apparent, although (4) Specimen 56 (PED 0379) is preserved in Cretaceous Myanmar amber ( Figure 3). The dorsal ( Figure 3A) and ventral ( Figure 3B,C) sides are accessible. The labrum is tridentlike with a larger spine-like protrusion in the middle, but with two smaller spine-like protrusions next to the large spine on each side ( Figure 3D,E); hence, it is not a trident in the strict sense, as it has five and not three prongs. No empodium is apparent, although the claws are well preserved ( Figure 3F). The specimen has an approximate length of 5.5 mm.
Insects 2023, 14, x FOR PEER REVIEW 6 of 52 the claws are well preserved ( Figure 3F). The specimen has an approximate length of 5.5 mm. (5) Specimen 57 (PED 0382) is preserved in Cretaceous Myanmar amber ( Figure 4). The dorsal ( Figure 4A,B) and ventral ( Figure 4C) sides are accessible. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 4D). An empodium is apparent ( Figure 4E). The specimen has an approximate length of 8.6 mm.   Figure 4A,B) and ventral ( Figure 4C) sides are accessible. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 4D). An empodium is apparent ( Figure 4E). The specimen has an approximate length of 8.6 mm.   Figure 5A,B) and ventral ( Figure 5C) sides are accessible. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 5E). The locomotory appendages are partly covered by a whitish coating (hereafter called Verlumung; adjective: verlumt) ( Figure 5D). The specimen has an approximate length of 9.9 mm.  Figure 5A,B) and ventral ( Figure 5C) sides are accessible. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 5E). The locomotory appendages are partly covered by a whitish coating (hereafter called Verlumung; adjective: verlumt) ( Figure 5D). The specimen has an approximate length of 9.9 mm. (7) Specimen 59 (PED 0412) is preserved in Cretaceous Myanmar amber ( Figure  6D,E). The ventral side is accessible with parts of the abdomen being verlumt ( Figure  6D,E). The dorsal side is largely concealed by dirt and partly by verlumt. One stylet is separated from the head capsule. The labrum is broad, pentagonal in the dorsal view, and bears small spine-like elevations at the corners. The specimen is located in a corner of the amber piece and the distal part of its abdomen appears to be missing. The specimen has an approximate length of 2.8 mm.   Figure 6D,E). The ventral side is accessible with parts of the abdomen being verlumt ( Figure 6D,E). The dorsal side is largely concealed by dirt and partly by verlumt. One stylet is separated from the head capsule. The labrum is broad, pentagonal in the dorsal view, and bears small spine-like elevations at the corners. The specimen is located in a corner of the amber piece and the distal part of its abdomen appears to be missing. The specimen has an approximate length of 2.8 mm. (8) Specimen 60 (PED 0430) is preserved in Cretaceous Myanmar amber. It is accessible from the dorsal side ( Figure 7D,E). The labrum is trident-like with a large bifurcated middle spine-like protrusion and two smaller spine-like protrusions next to the large spine. The antennae bear prominent setae at the distal ends. Trumpet-shaped empodia at the end of the locomotory appendages are visible. Parts of the abdomen appear to be missing. The specimen has an approximate length of 3.6 mm.  Figure 7D,E). The labrum is trident-like with a large bifurcated middle spine-like protrusion and two smaller spine-like protrusions next to the large spine. The antennae bear prominent setae at the distal ends. Trumpet-shaped empodia at the end of the locomotory appendages are visible. Parts of the abdomen appear to be missing. The specimen has an approximate length of 3.6 mm. (9) Specimen 61 (PED 0440) is preserved in Cretaceous Myanmar amber. It is accessible from the dorsal side ( Figure 8A,B), but strongly verlumt from the ventral side. The labrum is triangular to pentagonal in the dorsal view. The antennae bear prominent setae at the distal ends. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The specimen has an approximate length of 1.2 mm. (9) Specimen 61 (PED 0440) is preserved in Cretaceous Myanmar amber. It is accessible from the dorsal side ( Figure 8A,B), but strongly verlumt from the ventral side. The labrum is triangular to pentagonal in the dorsal view. The antennae bear prominent setae at the distal ends. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The specimen has an approximate length of 1.2 mm.  (Figure 2A,B) and ventral ( Figure 2C) sides are accessible. The labrum is trapezoidal in the dorsal view with a large V-shaped split distally ( Figure 2D). The antennae bear prominent setae at the distal ends. Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 2E). The specimen has an approximate length of 1.5 mm.
(11) Specimen 63 (PED 0535) is preserved in Cretaceous Myanmar amber ( Figure 7A-C). The dorsal ( Figure 7C) and ventral ( Figure 7A,B) sides are accessible. The labrum is triangular in the dorsal view. The antennae bear prominent setae at the distal ends. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The abdomen is partly verlumt from the dorsal side. The specimen has an approximate length of 1.8 mm.  (Figure 2A,B) and ventral ( Figure 2C) sides are accessible. The labrum is trapezoidal in the dorsal view with a large V-shaped split distally ( Figure 2D). The antennae bear prominent setae at the distal ends. Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 2E). The specimen has an approximate length of 1.5 mm.
(11) Specimen 63 (PED 0535) is preserved in Cretaceous Myanmar amber ( Figure 7A-C). The dorsal ( Figure 7C) and ventral ( Figure 7A,B) sides are accessible. The labrum is triangular in the dorsal view. The antennae bear prominent setae at the distal ends. Trumpetshaped empodia at the end of the locomotory appendages are visible. The abdomen is partly verlumt from the dorsal side. The specimen has an approximate length of 1.8 mm.
(12) Specimen 64 (PED 0584) is preserved in Cretaceous Myanmar amber ( Figure 1D). The dorsal and ventral sides are strongly verlumt. Only the head and parts of the thorax are present. The labrum is triangular to pentagonal in the dorsal view. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The specimen has an estimated length of 3.1-3.5 mm. This specimen was not included in the final analysis.
(13) Specimen 65 (PED 0612) is preserved in Cretaceous Myanmar amber ( Figure 6A-C). It is accessible from the ventral side ( Figure 6A,B), but strongly verlumt. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 6C). The specimen has an approximate length of 6.9 mm.
(14) Specimen 66 (PED 0621) is preserved in Cretaceous Myanmar amber ( Figure 9). The dorsal ( Figure 9A,B) and ventral ( Figure 9C) sides are accessible, but are partly concealed by dirt or Verlumung. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 9D,E). The antennae bear prominent setae at the distal ends. The abdomen appears slim and elongated. The specimen has an approximate length of 5.7 mm.  Figure 1D). The dorsal and ventral sides are strongly verlumt. Only the head and parts of the thorax are present. The labrum is triangular to pentagonal in the dorsal view. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The specimen has an estimated length of 3.1-3.5 mm. This specimen was not included in the final analysis.
(13) Specimen 65 (PED 0612) is preserved in Cretaceous Myanmar amber ( Figure 6A-C). It is accessible from the ventral side ( Figure 6A,B), but strongly verlumt. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 6C). The specimen has an approximate length of 6.9 mm.
(14) Specimen 66 (PED 0621) is preserved in Cretaceous Myanmar amber ( Figure 9). The dorsal ( Figure 9A,B) and ventral ( Figure 9C) sides are accessible, but are partly concealed by dirt or Verlumung. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 9D,E). The antennae bear prominent setae at the distal ends. The abdomen appears slim and elongated. The specimen has an approximate length of 5.7 mm.   Figure 1C). The dorsal and ventral sides are accessible, but strongly verlumt. Only the head is present, but a large area of the ventral side appears to be ground off near the neck region. The labrum appears to be trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine. The specimen has an estimated length of 12.4-15.8 mm. This specimen was not included in the final analysis.
(15) Specimen 67 (PED 0625) is preserved in Cretaceous Myanmar amber ( Figure 1C). The dorsal and ventral sides are accessible, but strongly verlumt. Only the head is present, but a large area of the ventral side appears to be ground off near the neck region. The labrum appears to be trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine. The specimen has an estimated length of 12.4-15.8 mm. This specimen was not included in the final analysis.
(16) Specimen 68 (PED 0662) is preserved in Cretaceous Myanmar amber ( Figure 10). The dorsal ( Figure 10A) and ventral ( Figure 10B,C) sides are accessible, but are partly concealed by dirt and Verlumung. The labrum is mostly concealed by Verlumung, but appears relatively broad and short ( Figure 10D). The specimen has an approximate length of 8.3 mm. with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 11F). Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 11G). Large parts of the abdomen and thorax are concealed by a crack in the amber. The specimen has a measured length of approximately 5.0 mm, but an estimated length between 9.2-10.5 mm.   Figure  11D-G). The ventral side is accessible, but partly verlumt ( Figure 11D,E). The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 11F). Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 11G). Large parts of the abdomen and thorax are concealed by a crack in the amber. The specimen has a measured length of approximately 5.0 mm, but an estimated length between 9.2-10.5 mm.  The ventral side is accessible, but is strongly concealed by dirt and Verlumung ( Figure 11A,B). The labrum is triangular in the dorsal view ( Figure 11C). The antennae bear prominent setae at the distal ends. A part of the abdomen appears to be missing. The specimen has an estimated length of 2.5-2.7 mm.  Figure 1A). The dorsal and ventral sides are accessible, but are strongly concealed by dirt and Verlumung. The head seems to be turned sideways or experienced a deformation. Due to Verlumung, the shape of the labrum is not clearly discernible. The specimen has an approximate length of 15.7 mm. This specimen was not included in the final analysis.
(20) Specimen 72 (PED 0932) is preserved in Cretaceous Myanmar amber. The dorsal ( Figure 12C) and ventral ( Figure 12A,B) sides are accessible, but are partly concealed by dirt and Verlumung. The labrum is trident-like with a large bifurcated middle spine-like protrusion and two smaller spine-like protrusions next to the large spine ( Figure 12D,E). The eyes are visible from the lateral view. The antennae bear prominent setae at the distal ends. The abdomen and thorax are mostly concealed. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The specimen has an estimated length of 5.4-5.9 mm.    Figure 13A,B) and ventral ( Figure 13C) sides are accessible, but are strongly concealed by dirt and Verlumung. The labrum is triangular with a shallow cleft distally. The abdomen appears slim and elongated. The specimen has an approximate length of 10.5 mm.   Figure 12I). The antennae bear prominent setae at the distal ends. The specimen has an approximate length of 2.0 mm.
(24) Specimen 76 (PED 1627) is preserved in Cretaceous Myanmar amber ( Figure 15). The dorsal ( Figure 15A,B) and ventral ( Figure 15C) sides are accessible, but are strongly concealed by dirt and Verlumung. The labrum appears relatively broad, short, and pentagonal in the dorsal view ( Figure 15D,E). Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 15F). The specimen has an approximate length of 10.1 mm.  Figure 15). The dorsal ( Figure 15A,B) and ventral ( Figure 15C) sides are accessible, but are strongly concealed by dirt and Verlumung. The labrum appears relatively broad, short, and pentagonal in the dorsal view ( Figure 15D,E). Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 15F). The specimen has an approximate length of 10.1 mm.
(25) Specimen 77 (PED 1666) is preserved in Cretaceous Myanmar amber ( Figure 16). The dorsal ( Figure 16A,B) and ventral ( Figure 16C) sides are accessible. The labrum is triangular to pentagonal in the dorsal view. The antennae bear prominent setae at the distal ends ( Figure 16D). Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 16F). Some setae have a peculiar fan-like shape ( Figure 16E). The specimen has an approximate length of 1.9 mm. Insects 2023, 14, x FOR PEER REVIEW 19 of 52  Figure 16). The dorsal ( Figure 16A,B) and ventral ( Figure 16C) sides are accessible. The labrum is triangular to pentagonal in the dorsal view. The antennae bear prominent setae at the distal ends ( Figure 16D). Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 16F). Some setae have a peculiar fan-like shape ( Figure 16E). The specimen has an approximate length of 1.9 mm.  Figure 17C) and ventral ( Figure 17A,B) sides are accessible, but are strongly concealed by dirt and Verlumung. Half of one stylet is missing distally. The labrum appears pentagonal, but well rounded in the dorsal view ( Figure 17D). Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 17E). The specimen has an approximate length of 2.9 mm.  Figure 17C) and ventral ( Figure 17A,B) sides are accessible, but are strongly concealed by dirt and Verlumung. Half of one stylet is missing distally. The labrum appears pentagonal, but well rounded in the dorsal view ( Figure 17D). Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 17E). The specimen has an approximate length of 2.9 mm.  Figure 18C) and ventral ( Figure 18A,B) sides are accessible, but are partly concealed by dirt and Verlumung. The labrum appears pentagonal in the dorsal view, and quite broad and short with a broad cleft distally ( Figure 18D). The abdomen appears to be missing its distal end, which was presumably ground off. Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 18E). The specimen has a measured length of approximately 7.6 mm, but an estimated length between 10.4-10.8 mm.  Figure 18C) and ventral ( Figure 18A,B) sides are accessible, but are partly concealed by dirt and Verlumung. The labrum appears pentagonal in the dorsal view, and quite broad and short with a broad cleft distally ( Figure 18D). The abdomen appears to be missing its distal end, which was presumably ground off. Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 18E). The specimen has a measured length of approximately 7.6 mm, but an estimated length between 10.4-10.8 mm.  Figure 19). The dorsal ( Figure 19A,B) and ventral ( Figure 19C) sides are accessible. The stylets are partly concealed. The labrum is broad, pentagonal in the dorsal view, and bears small spine-like elevations at the corners ( Figure 19D). No clear indications of an empodium are apparent ( Figure 19E). The specimen has an approximate length of 7.7 mm.  Figure 19). The dorsal ( Figure 19A,B) and ventral ( Figure 19C) sides are accessible. The stylets are partly concealed. The labrum is broad, pentagonal in the dorsal view, and bears small spine-like elevations at the corners ( Figure 19D). No clear indications of an empodium are apparent ( Figure 19E). The specimen has an approximate length of 7.7 mm.  Figure 20C) sides are accessible. The specimen appears to be the best preserved one among the new specimens. The labrum appears almost square-shaped in the dorsal view, with one bigger cleft in the middle distally and two flanking smaller clefts at the edges ( Figure 20D). The antennae bear prominent setae at the distal ends. The thorax and abdomen are well-preserved and the subdivisions are easily recognisable. Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 20E). The specimen has an approximate length of 3.5 mm.  Figure 20C) sides are accessible. The specimen appears to be the best preserved one among the new specimens. The labrum appears almost square-shaped in the dorsal view, with one bigger cleft in the middle distally and two flanking smaller clefts at the edges ( Figure 20D). The antennae bear prominent setae at the distal ends. The thorax and abdomen are well-preserved and the subdivisions are easily recognisable. Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 20E). The specimen has an approximate length of 3.5 mm.  Figure  14C,D). The ventral side is accessible. Only the head, neck, and parts of the prothorax are present. The labrum appears almost square-shaped in the dorsal view, with one bigger cleft in the middle distally and two flanking smaller clefts at the edges. The antennae bear prominent setae at the distal ends. The specimen has an estimated length of 3.9-4.3 mm.
(32) Specimen 84 (PED 1884) is preserved in Cretaceous Myanmar amber ( Figure  8C,D). The dorsal side is accessible, but is partly concealed by dirt and Verlumung. The labrum is trident-like with a large bifurcated middle spine-like protrusion and two smaller spine-like protrusions next to the large spine. The specimen has an approximate length of 3.4 mm.  Figure 14C,D). The ventral side is accessible. Only the head, neck, and parts of the prothorax are present. The labrum appears almost square-shaped in the dorsal view, with one bigger cleft in the middle distally and two flanking smaller clefts at the edges. The antennae bear prominent setae at the distal ends. The specimen has an estimated length of 3.9-4.3 mm.
(32) Specimen 84 (PED 1884) is preserved in Cretaceous Myanmar amber ( Figure 8C,D). The dorsal side is accessible, but is partly concealed by dirt and Verlumung. The labrum is trident-like with a large bifurcated middle spine-like protrusion and two smaller spine-like protrusions next to the large spine. The specimen has an approximate length of 3.4 mm.
(33) Specimen 85 (PED 1887) is preserved in Cretaceous Myanmar amber ( Figure 21A-C). The ventral side is accessible, but is partly concealed by dirt and Verlumung ( Figure 21A,B). One stylet is missing about one half distally. The labrum is broad, pentagonal in the dorsal view, and bears small spine-like elevations at the corners ( Figure 21C). The antennae bear prominent setae at the distal ends ( Figure 21C). The head capsule is separated from the body, with the whole neck region and parts of the adjacent head capsule missing. The body is missing the majority of the thorax and abdomen. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The specimen has an estimated length of 4.5 mm. This specimen was not included in the final analysis.  Figure  21A-C). The ventral side is accessible, but is partly concealed by dirt and Verlumung (Figure 21A,B). One stylet is missing about one half distally. The labrum is broad, pentagonal in the dorsal view, and bears small spine-like elevations at the corners ( Figure 21C). The antennae bear prominent setae at the distal ends ( Figure 21C). The head capsule is separated from the body, with the whole neck region and parts of the adjacent head capsule missing. The body is missing the majority of the thorax and abdomen. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The specimen has an estimated length of 4.5 mm. This specimen was not included in the final analysis.  Figure 22A) sides are accessible, but are partly concealed by dirt and Verlumung. The antennae bear prominent setae at the distal ends. The labrum is trident-like with a large bifurcated middle spine-like protrusion and two smaller spine-like protrusions next to the large spine ( Figure 22D). The abdomen appears  Figure 22A) sides are accessible, but are partly concealed by dirt and Verlumung. The antennae bear prominent setae at the distal ends. The labrum is trident-like with a large bifurcated middle spine-like protrusion and two smaller spine-like protrusions next to the large spine ( Figure 22D). The abdomen appears to be missing its distal end. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The specimen has a measured length of approximately 4.0 mm, but an estimated length between 5.6-6.8 mm. to be missing its distal end. Trumpet-shaped empodia at the end of the locomotory appendages are visible. The specimen has a measured length of approximately 4.0 mm, but an estimated length between 5.6-6.8 mm.  Figure  21D-G). The dorsal side is accessible, but is partly concealed by dirt and Verlumung (Figure 21D,E). The labrum is triangular in the dorsal view ( Figure 21F,G). The antennae bear prominent setae at the distal ends. Parts of the abdomen seem to be concealed or missing. The specimen has a measured length of approximately 1.3 mm, but an estimated length between 2.3-2.8 mm.   Figure 21D-G). The dorsal side is accessible, but is partly concealed by dirt and Verlumung ( Figure 21D,E). The labrum is triangular in the dorsal view ( Figure 21F,G). The antennae bear prominent setae at the distal ends. Parts of the abdomen seem to be concealed or missing. The specimen has a measured length of approximately 1.3 mm, but an estimated length between 2.3-2.8 mm.
(36) Specimen 88 (PED 1967) is preserved in Cretaceous Myanmar amber ( Figure 23). The dorsal (Figure 23A,B) and ventral ( Figure 23C) sides are accessible, but are largely concealed by dirt and Verlumung. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine ( Figure 23D). The specimen has an approximate length of 11.9 mm. concealed by dirt and Verlumung. The labrum is trident-like with a larger spine-like protrusion in the middle and two smaller spine-like protrusions next to the large spine (Figure 23D). The specimen has an approximate length of 11.9 mm. (37) Specimen 89 (PED 2056) is preserved in Cretaceous amber from Myanmar (Figure 24). The specimen is well accessible in the dorsal view ( Figure 24A,B), but is partly concealed by dirt in the ventral view ( Figure 24C). The labrum is prominent, being triangular symmetric to trapezium-like in the dorsal view and relatively elongated. Trumpetshaped empodia at the end of the locomotory appendages are visible ( Figure 24D). The posterior trunk is missing. The specimen has an approximate length of 4.1 mm.  Figure 24). The specimen is well accessible in the dorsal view ( Figure 24A,B), but is partly concealed by dirt in the ventral view ( Figure 24C). The labrum is prominent, being triangular symmetric to trapezium-like in the dorsal view and relatively elongated. Trumpet-shaped empodia at the end of the locomotory appendages are visible ( Figure 24D (38) Specimen 90 (PED 2171) is preserved in Cretaceous amber from Myanmar (Figure 25). The specimen is largely concealed by dirt and Verlumung in the ventral ( Figure  25A,B) and dorsal views ( Figure 25C). The labrum is prominent, being triangular symmetric to trapezium-like and relatively elongated. Each distal end of the walking appendages bears a trumpet-shaped empodium ( Figure 25D). The specimen has an approximate length of 2.6 mm.  Figure 25). The specimen is largely concealed by dirt and Verlumung in the ventral ( Figure 25A,B) and dorsal views ( Figure 25C). The labrum is prominent, being triangular symmetric to trapezium-like and relatively elongated. Each distal end of the walking appendages bears a trumpet-shaped empodium ( Figure 25D). The specimen has an approximate length of 2.6 mm.  Figure 26A,B) and dorsal views ( Figure 26C), but is partly concealed by Verlumung and dirt particles in the dorsal and ventral views. The labrum is prominent, being triangular symmetric to trapezium-like and relatively elongated ( Figure 26D). The antennae bear prominent setae distally ( Figure  26E). Each distal end of the walking appendages bears a trumpet-shaped empodium (Figure 26F). The specimen has an approximate length of 2.2 mm.  Figure 26). The specimen is well accessible in the ventral ( Figure 26A,B) and dorsal views ( Figure 26C), but is partly concealed by Verlumung and dirt particles in the dorsal and ventral views. The labrum is prominent, being triangular symmetric to trapeziumlike and relatively elongated ( Figure 26D). The antennae bear prominent setae distally ( Figure 26E). Each distal end of the walking appendages bears a trumpet-shaped empodium ( Figure 26F). The specimen has an approximate length of 2.2 mm. (40) Specimen 92 (PED 2311) is preserved in Cretaceous amber from Myanmar (Figure 27). The specimen is well accessible in the dorsal ( Figure 27A,B) and ventral views ( Figure 27C), but is partly concealed by Verlumung and dirt particles in the dorsal and ventral views. The labrum is prominent, being triangular symmetric to trapezium-like and very elongated. The specimen has an approximate length of 1.3 mm.  Figure 27). The specimen is well accessible in the dorsal ( Figure 27A,B) and ventral views ( Figure 27C), but is partly concealed by Verlumung and dirt particles in the dorsal and ventral views. The labrum is prominent, being triangular symmetric to trapezium-like and very elongated. The specimen has an approximate length of 1.3 mm.   Figure 28B). The trunk is missing completely, with only the head preserved. The head is well accessible in the dorsal view. The labrum is prominent, pentagonal, and relatively broad. The specimen has an approximate length of 1.8 mm.
(42) Specimen 94 (PED 2446) is preserved in Cretaceous amber from Myanmar ( Figure 28A). The trunk is missing completely, with only the head preserved. The head is well accessible in the dorsal view. The labrum is prominent, triangular, and relatively elongated. The antennae bear prominent setae distally. The specimen has an approximate length of 2 mm.
(43) Specimen 95 (PED 2448) is preserved in Cretaceous amber from Myanmar ( Figure 28C). The specimen is largely concealed by dirt particles in the dorsal and ventral views, with only the rough outline apparent. The specimen has an approximate size of 5 mm. This specimen was not included in the final analysis.
(44) Specimen 96 (PED 2432) is preserved in Cretaceous amber from Myanmar ( Figure 29). The specimen is well accessible in the ventral (Figure 29A,B) and dorsal views ( Figure 29C), but is partly concealed by Verlumung and dirt particles in the dorsal and ventral views. The labrum is prominent and simple triangular to pentagonal. The specimen has an approximate length of 8.5 mm.  (Figure 28C). The specimen is largely concealed by dirt particles in the dorsal and ventral views, with only the rough outline apparent. The specimen has an approximate size of 5 mm. This specimen was not included in the final analysis.
(44) Specimen 96 (PED 2432) is preserved in Cretaceous amber from Myanmar (Figure 29). The specimen is well accessible in the ventral ( Figure 29A,B) and dorsal views ( Figure 29C), but is partly concealed by Verlumung and dirt particles in the dorsal and ventral views. The labrum is prominent and simple triangular to pentagonal. The specimen has an approximate length of 8.5 mm. (45) Specimen 97 is preserved in Baltic amber. It was configured by Ross [104] (his Figure 150, p. 87). Although the original photograph is relatively small and a large bubble conceals parts of the body, some general aspects can be well recognised ( Figure 30A). The specimen was overlooked by Haug et al. [18]. The length was approximately 3 mm. The repository was not stated, but a similar-appearing specimen in an image repository was stated to show a specimen from the Natural History Museum, London.
(46) Specimen 98 is preserved in Baltic amber. The specimen was not directly investigated, but high-quality images ( Figure 30B) were provided by Marius Veta (www.am-   Figure 150, p. 87). Although the original photograph is relatively small and a large bubble conceals parts of the body, some general aspects can be well recognised ( Figure 30A). The specimen was overlooked by Haug et al. [18]. The length was approximately 3 mm. The repository was not stated, but a similar-appearing specimen in an image repository was stated to show a specimen from the Natural History Museum, London.

Shape Analysis
The results of the shape analyses are provided in Supplementary Materials File S2. Head and stylets: The shape analysis of the head capsule with stylets resulted in six effective principal components (PCs), summarizing 94.2% of the overall References in the form of [XX] are not permitted in the images. Please move it to the figure caption. If necessary, please use the format of "Author+Year" instead in the images, and all mentioned references should be cited in the caption.of the dataset. PC1 explains 52.5% of the overall variation. PC1 is dominated by the shape of the head and the mandibles. It describes very slender to very broad head shapes, with broad and long-to-narrow and short mandibles. Low values indicate a slender head with distally tapering mandibles, while high values indicate a broad head with mandibles that are in the distal region as broad as in the proximal region.
PC2 explains 24.8% of the overall variation. PC2 is dominated by the shape of the mandibles and the length of the head capsule, also focusing on the length of the labrum. Low values indicate a long head and labrum with relatively straight mandibles, while high values indicate a small head and small labrum with strongly curved mandible tips. PC3 explains 7.5% of the overall variation. It is dominated by the length of the labrum. It describes a tapering-to-flattened labrum, yet the shape of the mandibles also influences this PC. Low values indicate an elongated tapering labrum with strongly curved mandible tips, while high values indicate a flattened, round labrum with straight mandible tips.
PC4 explains 3.9% of the overall variation. It is dominated by the length of the labrum. It describes long-to-short labra, yet the shape of the mandibles also seems to influence this PC. Low values indicate a long tapering labrum with mandibles that are in the distal region as broad as in the proximal region, while high values indicate a short tapering labrum with mandibles that are broad in the proximal region and tapering in the distal region.
PC5 explains 3.0% of the overall variation. It is dominated by the shape of the labrum and the shape of the mandibles. Low values indicate a short tapering labrum and mandibles that are broad in the proximal region and tapering in the distal region, while high (46) Specimen 98 is preserved in Baltic amber. The specimen was not directly investigated, but high-quality images ( Figure 30B) were provided by Marius Veta (www. ambertreasure4u.com, accessed on 23 December 2022).

Shape Analysis
The results of the shape analyses are provided in Supplementary Materials File S2. Head and stylets: The shape analysis of the head capsule with stylets resulted in six effective principal components (PCs), summarizing 94.2% of the overall References in the form of [XX] are not permitted in the images. Please move it to the figure caption. If necessary, please use the format of "Author+Year" instead in the images, and all mentioned references should be cited in the caption.of the dataset. PC1 explains 52.5% of the overall variation. PC1 is dominated by the shape of the head and the mandibles. It describes very slender to very broad head shapes, with broad and long-to-narrow and short mandibles. Low values indicate a slender head with distally tapering mandibles, while high values indicate a broad head with mandibles that are in the distal region as broad as in the proximal region.
PC2 explains 24.8% of the overall variation. PC2 is dominated by the shape of the mandibles and the length of the head capsule, also focusing on the length of the labrum. Low values indicate a long head and labrum with relatively straight mandibles, while high values indicate a small head and small labrum with strongly curved mandible tips. PC3 explains 7.5% of the overall variation. It is dominated by the length of the labrum. It describes a tapering-to-flattened labrum, yet the shape of the mandibles also influences this PC. Low values indicate an elongated tapering labrum with strongly curved mandible tips, while high values indicate a flattened, round labrum with straight mandible tips.
PC4 explains 3.9% of the overall variation. It is dominated by the length of the labrum. It describes long-to-short labra, yet the shape of the mandibles also seems to influence this PC. Low values indicate a long tapering labrum with mandibles that are in the distal region as broad as in the proximal region, while high values indicate a short tapering labrum with mandibles that are broad in the proximal region and tapering in the distal region.
PC5 explains 3.0% of the overall variation. It is dominated by the shape of the labrum and the shape of the mandibles. Low values indicate a short tapering labrum and mandibles that are broad in the proximal region and tapering in the distal region, while high values indicate a broad curved labrum with mandibles that are in the distal region as broad as in the proximal region.
PC6 explains 2.5% of the overall variation. It is dominated by the shape of the labrum, the mandibles, and the posterior head capsule. It describes a concave posterior rim and a tapering labrum with tapering mandibles to a convex posterior rim and a broad labrum with mandibles that are in the distal region as broad as in the proximal region.
Head capsule: The shape analysis of the head capsule resulted in eight effective principal components, summarizing 93.8% of the overall variation in the dataset. PC1 explains 45.1% of the overall variation. PC1 is dominated by the shape of the head, especially focusing on the posterior rim. It describes a convex-to-concave posterior rim, yet the shape of the labrum also influences this PC. Low values indicate a convex posterior edge of the head with a tapering labrum, while high values indicate a concave posterior rim with a rounded labrum.
PC2 explains 18.6% of the overall variation. It is dominated by the shape of the head and describes rectangular-to-trapezium-like head capsules. Low values indicate a rectangular head with a round posterior and anterior rim, while high values indicate a round head with a tapered posterior and anterior rim.
PC3 explains 9.6% of the overall variation. It is dominated by the shape of the posterior rim and the length of the labrum. Low values indicate a posterior rim with an elongated labrum, while high values indicate a rectangular head with a short tapering labrum. PC4 explains 7.5% of the overall variation. It is dominated by the shape of the posterior rim and the length of the labrum. Low values indicate a concave posterior rim with an elongated labrum, while high values indicate a round posterior rim with a short labrum.
PC5 explains 4.0% of the overall variation. It is dominated by the shape of the head capsule, yet the length of the labrum also seems to influence this PC. Low values indicate a trapezium-like head with a short labrum, while high values indicate a rectangular head with an elongated labrum.
PC6 explains 3.2% of the overall variation. It is dominated by the width of the head. It describes the lateral anterior rim of the head, yet the shape of the labrum also seems to influence this PC. Low values indicate a wide lateral anterior rim with a tapering labrum, while high values indicate a somewhat rectangular head with a broad labrum.
PC7 explains 2.7% of the overall variation. It is dominated by the shape of the labrum. Low values indicate an elongated tapering labrum, while high values indicate a widerounded labrum.
PC8 explains 2.2% of the overall variation. It is dominated by the shape of the anterior rim of the head. Low values indicate a tapering median anterior rim, while high values indicate a rectangular anterior rim.
Stylets: The shape analysis of the stylets resulted in four effective principal components, summarizing 96.5% of the overall variation in the dataset. Body outline without stylets: The shape analysis of the entire body without stylets resulted in eight effective principal components, summarizing 92.9% of the overall variation in the dataset. PC1 explains 39.5% of the overall variation. It is dominated by the shape of the thorax. Low values indicate a relatively concave thorax with a fluent transition between thorax and posterior trunk, while high values indicate a relatively convex thorax with a clear distinction from the posterior trunk.
PC2 explains 18.7% of the overall variation. It is dominated by the position of the narrowest part of the body, yet the length of the labrum also seems to influence this PC. Low values indicate a further anteriorly located narrowest part of the body and an elongated tapering labrum, while high values indicate a further posteriorly located narrowest part of the body and a shortened round labrum.
PC3 explains 12.3% of the overall variation. It is dominated by the shape of the head. Low values indicate a rectangular shape of the head, while high values indicate a tapering rim of the head. PC4 explains 7.8% of the overall variation. It appears to be dominated by similar phenomena as PC3. Low values indicate a rectangular head, while high values indicate a round tapering head.
PC5 explains 5.3% of the overall variation. It is dominated by the shape of the labrum and describes round-to-tapering labra. Low values indicate a convex anterior rim with a round wide labrum, while high values indicate a concave anterior rim with a tapering labrum. PC6 explains 4.3% of the overall variation. It is dominated by the position of the narrowest part of the body. Low values indicate a further anteriorly located narrowest part of the body, while high values indicate a further posteriorly located narrowest part of the body.
PC7 explains 3.1% of the overall variation. It is dominated by the position of the narrowest part of the body and the shape of the labrum. Low values indicate a further anteriorly located narrowest part of the body with a tapering labrum, while high values indicate a further posteriorly located narrowest part of the body with a shortened round labrum.
PC8 explains 2.0% of the overall variation. It seems to be dominated by the width of the head. Low values indicate a head as wide in the anterior region as in the posterior region, while high values indicate a head that is wide in the anterior region and narrow in the posterior region.

General Observation: Loss of Diversity
This study of long-nosed antlions has expanded the analysis performed by Haug et al. [18], which had already found a decrease, or loss, of morphological diversity from the Cretaceous to the modern fauna. As we have only added new fossil forms, it is not surprising that this picture did not change. Still, we can recognise some differences to the earlier study. Moreover, more specimens may offer access to small details, such as the small fan-like setae observed in one of the specimens.

Head and Stylet Shape
Although the original study concentrated on head capsule shape [18], most follow-up studies on larvae of other lineages of Neuroptera have used the head capsule together with the stylets [17,[19][20][21][24][25][26]112]. This analysis ( Figure 31) is also most comparable in its results to the earlier study. The morphospace occupation is the largest in the Cretaceous, is smaller in the Eocene, and even smaller in the modern fauna.
Yet, the relative sizes are different from the earlier study, being even larger in the Cretaceous. This should not be surprising, as many types of larvae that can be recognised on a qualitative level among the Cretaceous larvae are absent in the Eocene and modern fauna. Among these are many of the larvae with a trident-like labrum. Basically, the left half of the morphospace is occupied by trident-bearing larvae ( Figure 31). Among these are also larvae with new morphologies: one with the middle spine of the trident being bifurcated but longer than in the already known larvae (specimen 84; Figure 8C) and one with more spines, i.e., five (specimen 56; Figure 3).
Moreover, other areas of the morphospace represent morphologies not seen in the modern fauna but now recognised by new specimens (Figure 31). In the upper right area of the morphospace, there are larvae with very broad labra (e.g., specimen 79; Figure 18). In the lower right of the morphospace, larvae plot which have relatively long labra in comparison to the rest of the head capsule, but are otherwise not special in their shape (e.g., specimen 94; Figure 28A).
The influence of the new Cretaceous larvae is also seen when comparing the occupation of the morphospace of the larvae used in Haug et al. [18] and that of all of the Cretaceous larvae ( Figure 32). It shows that the new specimens significantly increase the morphospace occupation. This implies that there is still no saturation effect, i.e., adding new specimens still increases the morphospace by adding new types of morphologies. Yet, the relative sizes are different from the earlier study, being even larger in the Cretaceous. This should not be surprising, as many types of larvae that can be recognised on a qualitative level among the Cretaceous larvae are absent in the Eocene and modern fauna. Among these are many of the larvae with a trident-like labrum. Basically, the left half of the morphospace is occupied by trident-bearing larvae ( Figure 31). Among these are also larvae with new morphologies: one with the middle spine of the trident being bifurcated but longer than in the already known larvae (specimen 84; Figure 8C) and one with more spines, i.e., five (specimen 56; Figure 3).
Moreover, other areas of the morphospace represent morphologies not seen in the modern fauna but now recognised by new specimens (Figure 31). In the upper right area of the morphospace, there are larvae with very broad labra (e.g., specimen 79; Figure 18). In the lower right of the morphospace, larvae plot which have relatively long labra in comparison to the rest of the head capsule, but are otherwise not special in their shape (e.g., specimen 94; Figure 28A).
The influence of the new Cretaceous larvae is also seen when comparing the occupation of the morphospace of the larvae used in Haug et al. [18] and that of all of the Cretaceous larvae ( Figure 32). It shows that the new specimens significantly increase the

Stylet Shape
The stylet of long-nosed antlions is character-poor in comparison to other larvae of the group Myrmeleontiformia. In many other larvae, there are teeth that can vary in size, number, and position, but such teeth seem to have been secondarily lost in long-nosed antlions [113,114].
The main aspect that seems to vary within the stylet shape in long-nosed antlions is the curvature. In many fossils, the stylets seem stronger curved than in the modern larvae ( Figure 33). A factor that seems to have not been strongly picked up by the shape analysis

Stylet Shape
The stylet of long-nosed antlions is character-poor in comparison to other larvae of the group Myrmeleontiformia. In many other larvae, there are teeth that can vary in size, number, and position, but such teeth seem to have been secondarily lost in long-nosed antlions [113,114].
The main aspect that seems to vary within the stylet shape in long-nosed antlions is the curvature. In many fossils, the stylets seem stronger curved than in the modern larvae ( Figure 33). A factor that seems to have not been strongly picked up by the shape analysis is the slenderness (or thickness) of the stylets. It appears that the trident-bearing larvae have slenderer stylets (Figure 31), but also vary strongly in curvature. Similar to the plot of head and stylets, the Cretaceous larvae occupy the largest area of the morphospace, and this largely includes those of other groups. An important difference to plotting head together with stylets is that the occupation of the morphospace of the modern larvae is larger than that of the Eocene larvae. Yet, some Eocene larvae plot outside the range of the modern larvae, emphasising again that the Eocene fauna also differs from the modern fauna concerning insect larvae [115].

Head Capsule Shape
Also in the head capsule shape, the Cretaceous larvae occupy the largest area, largely including the area of other groups (Figure 34). Similar to the stylets, the modern larvae occupy a larger area than the Eocene larvae. This is different to the earlier study by Haug Similar to the plot of head and stylets, the Cretaceous larvae occupy the largest area of the morphospace, and this largely includes those of other groups. An important difference to plotting head together with stylets is that the occupation of the morphospace of the modern larvae is larger than that of the Eocene larvae. Yet, some Eocene larvae plot outside the range of the modern larvae, emphasising again that the Eocene fauna also differs from the modern fauna concerning insect larvae [115].

Head Capsule Shape
Also in the head capsule shape, the Cretaceous larvae occupy the largest area, largely including the area of other groups ( Figure 34). Similar to the stylets, the modern larvae occupy a larger area than the Eocene larvae. This is different to the earlier study by Haug et al. [18]. It is even more surprising as two new larvae from the Eocene were added to the dataset. It seems most likely that this difference to the earlier study is caused by the new Cretaceous larvae, as they have polarised the morphospace in a different way. analyses for Eocene and modern larvae indicates that a major difference in the Eocene larvae is the relative size of the stylets in relation to the head capsule.  Another aspect to mention in this aspect is that, unlike in the stylets, the area occupied by Eocene larvae is entirely inside the area of the modern larvae. The fact that the combined analysis (of head and stylets) provides a different view than the two separate analyses for Eocene and modern larvae indicates that a major difference in the Eocene larvae is the relative size of the stylets in relation to the head capsule.

Body Shape including Stylets
This dataset is smaller than those of the anterior body structures. Still, some important observations are provided. The general pattern with the Cretaceous larvae occupying the largest area is also found here ( Figure 35). Yet, the size difference to the area of the modern larvae is much smaller. Moreover, the modern larvae (and some Eocene larvae) occupy areas where no Cretaceous larvae plot. This indicates that not only were certain body shapes lost, but also new ones evolved that were not yet present in the Cretaceous. It has been previously noted that modern myrmeleontiformian larvae often appear broader, while many Cretaceous larvae appear overall slenderer [114]. In other groups of lacewings, more extreme trunk shapes were already present in the Cretaceous [116].

Body Shape including Stylets
This dataset is smaller than those of the anterior body structures. Still, some important observations are provided. The general pattern with the Cretaceous larvae occupying the largest area is also found here ( Figure 35). Yet, the size difference to the area of the modern larvae is much smaller. Moreover, the modern larvae (and some Eocene larvae) occupy areas where no Cretaceous larvae plot. This indicates that not only were certain body shapes lost, but also new ones evolved that were not yet present in the Cretaceous. It has been previously noted that modern myrmeleontiformian larvae often appear broader, while many Cretaceous larvae appear overall slenderer [114]. In other groups of lacewings, more extreme trunk shapes were already present in the Cretaceous [116]. The morphologies lost seem not only to be slenderer; in addition, the shapes have relatively larger heads and also longer stylets. This phenomenon of more elongated structures in the Cretaceous has been noted in other lacewing lineages [117][118][119][120][121]. The morphologies lost seem not only to be slenderer; in addition, the shapes have relatively larger heads and also longer stylets. This phenomenon of more elongated structures in the Cretaceous has been noted in other lacewing lineages [117][118][119][120][121].

Body Shape without Stylets
As we have noted regards the difference in stylets in the Cretaceous larvae, it should not be surprising that when considering the body outline without the stylets, the overall picture changes. Now, the largest occupied area is represented by the modern fauna ( Figure 36). Still, the very slender bodies of some Cretaceous larvae are not represented in the modern fauna. One might argue that only three larvae plotting outside the mod-ern morphospace may be insignificant. Yet, qualitative observations have also already hinted to the fact that myrmeleontiformian larvae had slenderer appearances in the Cretaceous [90,113,114,118]. In the light of this background, it seems likely that the difference in fossils is indeed true signal. The function of the slenderer trunk remains unclear. Yet, we need to assume that the broader trunk evolved independently several times within the modern myrmeleontiformian lineages (see discussion in [114]).

Body Shape without Stylets
As we have noted regards the difference in stylets in the Cretaceous larvae, it should not be surprising that when considering the body outline without the stylets, the overall picture changes. Now, the largest occupied area is represented by the modern fauna (Figure 36). Still, the very slender bodies of some Cretaceous larvae are not represented in the modern fauna. One might argue that only three larvae plotting outside the modern morphospace may be insignificant. Yet, qualitative observations have also already hinted to the fact that myrmeleontiformian larvae had slenderer appearances in the Cretaceous [90,113,114,118]. In the light of this background, it seems likely that the difference in fossils is indeed true signal. The function of the slenderer trunk remains unclear. Yet, we need to assume that the broader trunk evolved independently several times within the modern myrmeleontiformian lineages (see discussion in [114]). The fact that the stylets seem to play a major role in the variability in the Cretaceous larvae emphasises that the loss of morphology is likely coupled to a loss of ecological roles (see discussion in [114,119]). The differences in body shape, and the shift thereof, The fact that the stylets seem to play a major role in the variability in the Cretaceous larvae emphasises that the loss of morphology is likely coupled to a loss of ecological roles (see discussion in [114,119]). The differences in body shape, and the shift thereof, furthermore indicate not only a loss, but a change in ecological roles. A comparable observation was made for long-necked antlions (larvae of Crocinae [19]).

The Cretaceous Fauna and Its Peculiarities
As has been indicated, at a certain point, we should expect a kind of saturation effect when adding new specimens. At this point, new specimens should strongly resemble already-known ones. However, this is not yet the case.
Among the aberrant, now extinct forms, there are especially animals with unusual labra. Presumably, the different labrum shape also means differences in details of the feeding ecology. Moreover, the new observed morphotypes can be mostly recognised based on different labrum shapes. Unfortunately, it is still unknown how the labrum is involved in feeding for modern long-nosed antlions. In other raptorial larvae, for example, in beetles, it has been demonstrated that the shape of the labrum (and mandibles) can be directly coupled to a specialised feeding strategy (e.g., [129]). We can therefore only assume that most differences of the here-described fossil larvae and their modern counterparts are indeed related to differences in feeding strategies, but details remain unclear.
Besides lacewing larvae, among holometabolan larvae, only snakefly larvae (hence, larvae of Raphidioptera, closely related to Neuroptera) show certain peculiarities in the Cretaceous [154][155][156]. While we do not yet have quantitative data for all of these groups, it appears that the group Neuropterida, including Neuroptera, Raphidioptera, and also Megaloptera [157][158][159], had many morphologies resulting from their earlier radiations still present in the Cretaceous, but which are now extinct. This assumption is consistent with the idea that neuropteridans were part of the early radiation of Holometabola and fulfilled ecological functions nowadays performed by representatives of other groups.

Growth and Morphotypes
Among other lacewing larvae, parts of the ontogenetic sequences could be recognised, providing at least first hints for recognising morphotypes or even species. So far, this has not been possible for long-nosed antlions. Haug et al. [18] speculated that larvae with bifurcated labra could always represent earlier stages. As many of these are trident-bearing larvae ( Figure 37A), they should hence be smaller stages of trident-bearing larvae without a bifurcation in the middle spine ( Figure 37B). Indeed, specimens with bifurcated labra are on average smaller, yet both groups show considerable variation in size, indicating that each morphotype seems to be represented by several different stages. Furthermore, there is a single specimen of the trident-bearing type possessing additional spines (in fact, a pentadent-bearing type), probably representing yet another morphotype closer related to the trident-bearing types ( Figure 37D). So far, only a single species of a larva with a tridenttype labrum could be formally recognised (Acanthopsychops triaina [113]). Yet, the large variability of the morphology clearly indicates that several species are likely represented among these larvae. Furthermore, the larvae with very broad labra ( Figure 37C) likely represent not just several different stages but also several morphotypes, which again likely represent different species.
represented among these larvae. Furthermore, the larvae with very broad labra ( Figure  37C) likely represent not just several different stages but also several morphotypes, which again likely represent different species. Despite the additional material, no clear ontogenetic sequences can be recognised. The main challenge in this case is that on the extant side, very little is known about the larval sequences, usually only via single-specimen reports [28,47,94,[160][161][162][163][164], with the work of Tillyard [165] being the sole exception. Hence, besides more fossil material, for improving the situation, more extant specimens are required. So far, visits to collections (in Europe and Australia) have not yet provided additional specimens; hence, only aimed fieldwork may solve this issue.

Conclusions
Despite the taxonomic limitations, the analysis of fossil larvae with quantitative methods has again shown a significant loss of diversity in silky lacewings, more precisely the morphology and, coupled to this, ecology of their larvae. Although we could increase Despite the additional material, no clear ontogenetic sequences can be recognised. The main challenge in this case is that on the extant side, very little is known about the larval sequences, usually only via single-specimen reports [28,47,94,[160][161][162][163][164], with the work of Tillyard [165] being the sole exception. Hence, besides more fossil material, for improving the situation, more extant specimens are required. So far, visits to collections (in Europe and Australia) have not yet provided additional specimens; hence, only aimed fieldwork may solve this issue.

Conclusions
Despite the taxonomic limitations, the analysis of fossil larvae with quantitative methods has again shown a significant loss of diversity in silky lacewings, more precisely the morphology and, coupled to this, ecology of their larvae. Although we could increase the size of the dataset significantly, we still do not see any effect of saturation, indicating that we are still seeing just a part of the original diversity back in the Cretaceous.