Material from Dr. David Menton
Answersingenesis.org
Origin of Feathers Do feathered dinosaurs exist?
Feathers have long been considered to be unique to birds. Certainly all living birds have feathers of some kind,
while no living creature other than birds has been found to have a cutaneous appendage even remotely similar to a feather. Since most evolutionists are certain that birds evolved from dinosaurs (or at least are closely related to them), there has been an intense effort to find dinosaur fossils that show some suggestion of feathers or “protofeathers.” With such observer bias, one must be skeptical of recent widely publicized reports of feathered dinosaurs.
Dinosaurs are reptiles, and so it is not surprising that fossil evidence has shown them to have a scaly skin typical of reptiles. For example, a recently discovered well-preserved specimen of Compsognathus (a small theropod dinosaur of the type believed to be most closely related to birds) showed unmistakable evidence of scales but alas—no feathers.7
Still, there have been
many claims of feathered dinosaurs, particularly from fossils found in Liaoning province in northeastern China.8 The earliest feathered dinosaur from this source is the very unbird-like dinosaur
Sinosauropteryx, which lacks any evidence of structures that could be shown to be feather-like.
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Structures described as “protofeathers” in the dinosaur fossils
Sinosauropteryx and
Sinithosaurus are filamentous and sometimes have interlaced structures bearing no obvious resemblance to feathers.
It now appears likely that these filaments (often referred to as “dino-fuzz”) are actually connective tissue fibers (collagen) found in the deep dermal layer of the skin. Feduccia laments that “the major and most worrying problem of the feathered dinosaur hypothesis is that the integumental structures have been homologized with avian feathers on the basis of anatomically and paleontologically unsound and misleading information.”
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Complicating matters even further is the fact that true birds have been found among the Liaoning province fossils in the same layers as their presumed dinosaur ancestors. The obvious bird fossil
Confuciusornis sanctus, for example, has long slender tail feathers resembling those of a modern scissor-tail flycatcher. Two taxa (
Caudipteryx and
Protarchaeopteryx) that were thought to be dinosaurs with true feathers are now generally conceded to be flightless birds.
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Thus far, the only obvious dinosaur fossil with obvious feathers that was “found” is Archaeoraptor liaoningensis. This so-called definitive feathered dinosaur was reported with much fanfare in the November 1999 issue of National Geographic but has since been shown to be a fraud.
What would it prove if features common to one type of animal were found on another? Nothing. Simply put, God uses various designs with various creatures. Take the platypus, for example—a mosaic. It has several design features that are shared with other animals, and yet it is completely distinct. So if a dinosaur (or mammal) is ever found with feathers, it would call into question our human criteria for classification, not biblical veracity. What’s needed to support evolution is not an unusual mosaic of complete traits, but a trait in transition, such as a “scale-feather,” what creationist biologists would call a “sceather.”
Feathers and scales are dissimilar.
If birds evolved from dinosaurs or any other reptile, then feathers must have evolved from reptilian scales. Evolutionists are so confident that feathers evolved from scales that they often claim that feathers are very similar to scales. The popular Encarta computerized encyclopedia (1997) describes feathers as a “horny outgrowth of skin peculiar to the bird but similar in structure and origin to the scales of fish and reptiles.”12
In actual fact, feathers are profoundly different from scales in both their structure and growth. Feathers grow individually from tube-like follicles similar to hair follicles. Reptilian scales, on the other hand, are not individual follicular structures but rather comprise a continuous sheet on the surface of the body. Thus, while feathers grow and are shed individually (actually in symmetrically matched pairs!), scales grow and are shed as an entire sheet of skin.
Left: bird feather and reptile scales
The feather vane is made up of hundreds of barbs, each bearing hundreds of barbules interlocked with tiny hinged hooklets. This incredibly complex structure bears not the slightest resemblance to the relatively simple reptilian scale. Still, evolutionists continue to publish imaginative scenarios of how long-fringed reptile scales evolved by chance into feathers, but evidence of “sceathers” eludes them.
Origin of Flight
One of the biggest problems for evolutionists is explaining the origin of flight. To make matters worse, evolutionists believe that the flying birds evolved before the nonflying birds, such as penguins.
The theropod type of dinosaur that is believed to have evolved into flying birds is, to say the least, poorly designed for flight. These dinosaurs have small forelimbs that typically can’t even reach their mouths. It is not clear what theropods, such as the well-known T. rex, did with their tiny front limbs. It is obvious that they didn’t walk, feed, or grasp prey with them, and they surely didn’t fly with them!
Another problem is that this bipedal type of dinosaur had a long heavy tail to balance the weight of a long neck and large head. Decorating such a creature with feathers would hardly suffice to get it off the ground or be of much benefit in any other way.
“Bird-hipped” vs. “lizard-hipped” dinosaurs
All dinosaurs are divided into two major groups based on the structure of their hips (pelvic bones): the lizard-hipped dinosaurs (saurischians) and the bird-hipped dinosaurs (ornithiscians). The main difference between the two hip structures is that the pubic bone of the bird-hipped dinosaurs is directed toward the rear (as it is in birds) rather than entirely to the front (as it is in mammals and reptiles).
But in most other respects, the bird-hipped dinosaurs, including such huge quadrupedal sauropods as Brachiosaurus and Diplodocus, are even less bird-like than the lizard-hipped, bipedal dinosaurs such as the theropods. This point is rarely emphasized in popular accounts of dinosaur/bird evolution.
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Warm-blooded vs. cold-blooded
Seemingly forgotten in all the claims that birds are essentially dinosaurs (or at least that they evolved from dinosaurs) is the fact that dinosaurs are reptiles. There are many differences between birds and reptiles, including the fact that (with precious few exceptions) living reptiles are cold-blooded creatures, while birds and mammals are warm-blooded. Indeed, even compared to most mammals, birds have exceptionally high body temperatures resulting from a high metabolic rate.
The difference between cold- and warm-blooded animals isn’t simply in the relative temperature of the blood but rather in their ability to maintain a constant body core temperature. Thus, warm-blooded animals such as birds and mammals have internal physiological mechanisms to maintain an essentially constant body temperature; they are more properly called “endothermic.” In contrast, reptiles have a varying body temperature influenced by their surrounding environment and are called “ectothermic.” An ectothermic animal can adjust its body temperature behaviorally (e.g., moving between shade and sun), even achieving higher body temperature than a so-called warm-blooded animal, but this is done by outside factors.
In an effort to make the evolution of dinosaurs into birds seem more plausible, some evolutionists have argued that dinosaurs were also endothermic,1 but there is no clear evidence for this.2
One of the lines of evidence for endothermic dinosaurs is based on the microscopic structure of dinosaur bones. Fossil dinosaur bones have been found containing special microscopic structures called osteons (or Haversian systems). Osteons are complex concentric layers of bone surrounding blood vessels in areas where the bone is dense. This arrangement is assumed by some to be unique to endothermic animals and thus evidence that dinosaurs are endothermic, but such is not the case. Larger vertebrates (whether reptiles, birds, or mammals) may also have this type of bone. Even tuna fish have osteonal bone in their vertebral arches.
Another argument for endothermy in dinosaurs is based on the eggs and assumed brood behavior of dinosaurs, but this speculation too has been challenged.3 There is in fact no theropod brooding behavior not known to occur in crocodiles and other cold-blooded living reptiles.
Alan Feduccia, an expert on birds and their evolution, has concluded that “there has never been, nor is there now, any evidence that dinosaurs were endothermic.”4 Feduccia says that despite the lack of evidence “many authors have tried to make specimens conform to the hot-blooded theropod dogma.”
The three-fingered hand
One of the main lines of evidence cited by evolutionists for the evolution of birds from theropod dinosaurs is the three-fingered “hand” found in both birds and theropods. The problem is that recent studies have shown that there is a digital mismatch between birds and theropods.
Most terrestrial vertebrates have an embryological development based on the five-fingered hand. In the case of birds and theropod dinosaurs, two of the five fingers are lost (or greatly reduced) and three are retained during development of the embryo. If birds evolved from theropods, one would expect the same three fingers to be retained in both birds and theropod dinosaurs, but such is not the case. Evidence shows that the fingers retained in theropod dinosaurs are fingers 1, 2, and 3 (the “thumb” is finger 1) while the fingers retained in birds are 2, 3, and 4.5
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Avian vs. reptilian lung
One of the most distinctive features of birds is their lungs. Bird lungs are small in size and nearly rigid, but they are, nevertheless, highly efficient to meet the high metabolic needs of flight. Bird respiration involves a unique “flow-through ventilation” into a set of nine interconnecting flexible air sacs sandwiched between muscles and under the skin. The air sacs contain few blood vessels and do not take part in oxygen exchange, but rather function like bellows to move air through the lungs.
Bird “lung”
The air sacs permit a unidirectional flow of air through the lungs resulting in higher oxygen content than is possible with the bidirectional air flow through the lungs of reptiles and mammals. The air flow moves through the same tubes at different times both into and out of the lungs of reptiles and mammals, and this results in a mixture of oxygen-rich air with oxygen-depleted air (air that has been in the lungs for awhile). The unidirectional flow through bird lungs not only permits more oxygen to diffuse into the blood but also keeps the volume of air in the lungs nearly constant, a requirement for maintaining a level flight path.
Reptile lung
If theropod dinosaurs are the ancestors of birds, one might expect to find evidence of an avian-type lung in such dinosaurs. While fossils generally do not preserve soft tissue such as lungs, a very fine theropod dinosaur fossil (Sinosauropteryx) has been found in which the outline of the visceral cavity has been well preserved. The evidence clearly indicates that this theropod had lung and respiratory mechanics similar to that of a crocodile—not a bird.6 Specifically, there was evidence of a diaphragm-like muscle separating the lung from the liver, much as you see in modern crocodiles (birds lack a diaphragm). These observations suggest that this theropod was similar to an ectothermic reptile, not an endothermic bird. Information from Answersingenesis.org. Dr. David Menton
Day 6 of Creation: And God made the beasts of the earth according to their kinds...everything that creeps on the earth according to its kind. And God saw that it was good. Genesis 1:24
Day 5 of Creation: So God created...every winged bird according to its kind. And God saw that it was good. Genesis 1: 20
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