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While we can go for extended periods without most nutrients, the limit without water is only a few days.
|
Most people can survive only a few days without water.
|
entails
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Without water the human body will survive only a few days.
|
Most people can survive only a few days without water.
|
entails
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All reptiles (including birds) have eggs with amniotic membranes (which some lay and others retain inside their bodies until hatching).
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Most reptiles lay amniotic eggs.
|
entails
|
Amniotic Eggs Unlike amphibians, reptiles produce amniotic eggs (see Figure 19.23).
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Most reptiles lay amniotic eggs.
|
entails
|
Describe an amniotic egg and explain its significance in the evolution of reptiles, birds, and mammals.
|
Most reptiles lay amniotic eggs.
|
neutral
|
Describe the amniotic egg and reptile reproduction.
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Most reptiles lay amniotic eggs.
|
neutral
|
Dinosaurs and Reptiles Reptile is a term that refers to tetrapods (four-legged vertebrate) that lay an amniotic egg , have limb skeletons modified for fully terrestrial locomotion , and are ancestral to birds and mammals.
|
Most reptiles lay amniotic eggs.
|
entails
|
Early reptiles and the amniotic egg
|
Most reptiles lay amniotic eggs.
|
neutral
|
Most reptiles lay amniotic eggs covered with leathery or calcareous shells.
|
Most reptiles lay amniotic eggs.
|
entails
|
Reptiles have amniotic eggs with hard or leathery shells, requiring internal fertilization.
|
Most reptiles lay amniotic eggs.
|
entails
|
Reptiles possess yet another marvelous terrestrial adaptation, the amniotic egg.
|
Most reptiles lay amniotic eggs.
|
entails
|
The amniotic egg is the key feature in the development of the reptiles.
|
Most reptiles lay amniotic eggs.
|
entails
|
They lay amniotic eggs as do all reptiles.
|
Most reptiles lay amniotic eggs.
|
entails
|
Unlike amphibians, reptiles produce amniotic eggs (see Figure below ).
|
Most reptiles lay amniotic eggs.
|
entails
|
and new illustrations of reptile skin and the amniotic egg are added.
|
Most reptiles lay amniotic eggs.
|
neutral
|
embryonic gill slits and a notochord a stream-lined body and jaws amniotic eggs and internal fertilization paired fins and a post-anal tail Unlike reptiles, birds lay eggs.
|
Most reptiles lay amniotic eggs.
|
neutral
|
A turtle can not walk out of its shell, the carapace is fused with the ribs of the turtle.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
entails
|
A turtle s shell is actually made up of its ribs joined together and covered with a thin layer of skin.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
entails
|
Also, unlike most bony fishes, sharks do not have wel-developed ribs or a swim bladder.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
neutral
|
Because the ribs are still cartilaginous (instead of bony), they bend, and rib cage volume actually decreases.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
neutral
|
For example, turtles have only eight pairs of ribs, which are developed into a bony or cartilagenous carapace and plastron, while snakes have numerous ribs running along the full length of their trunk.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
entails
|
In several ethnic groups, most significantly the Japanese, the tenth rib is sometimes a floating rib, as it lacks a cartilaginous connection to the seventh rib.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
neutral
|
In tortoises and turtles, the ribs are fused to a rigid shell.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
entails
|
The ability of MR to detect the presence and undesirable thermal increases at acoustic obstacle such as cartilaginous and bony ribs is demonstrated.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
neutral
|
The bony covering, often fused to the ribs, on the upper and lower surfaces of the body of a turtle.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
entails
|
There is a slightly increased ( For large saddle defects involving bony and cartilaginous dorsum, rib cartilage makes excellent graft material.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
neutral
|
They have a special bony or cartilaginous shell developed from their ribs that acts as a shield.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
entails
|
Turtles are reptiles of the order Chelonii or Testudines characterised by a special bony or cartilaginous shell developed from their ribs and acting as a shield.
|
Most turtle bodies are covered by a special bony or cartilaginous shell developed from their ribs.
|
entails
|
includes fundamentals of rock mechanics and applications of stress and strain theory to the origin of structures, tectonics of mountain-building, and global plate tectonics.
|
Mountain building and earthquakes are some of the responses of rocks when subected to stress.
|
entails
|
Most of this energy is in the form of the kinetic energy of the emitted electron.
|
Moving electrons have a form of kinetic energy called electrical energy.
|
neutral
|
This mechanical energy is then converted into electrical energy, that is, the kinetic energy of electrons moving through wires, by electric generators.
|
Moving electrons have a form of kinetic energy called electrical energy.
|
entails
|
STRENGTH TRAINING Loss of muscle mass (sarcopenia) with age in humans is well documented.
|
Muscle atrophy due to age is called sarcopenia.
|
entails
|
Sarcopenia and Mitochondrial Function in Aging (submitted for funding;
|
Muscle atrophy due to age is called sarcopenia.
|
neutral
|
Sarcopenia means loss of muscle mass.
|
Muscle atrophy due to age is called sarcopenia.
|
entails
|
Sarcopenia, the age-related loss of muscle, is a key factor of the central problem.
|
Muscle atrophy due to age is called sarcopenia.
|
entails
|
Sarcopenia, the loss in muscle mass, related to aging, starts at age 25.
|
Muscle atrophy due to age is called sarcopenia.
|
entails
|
Different muscles are not represented equally in the motor cortex, as seen in. 2.
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
Genetic activity in the cerebral cortex, which is involved in thought processes, and the cerebellum, which is involved in muscle and motor skill coordination, were studied in both groups of mice.
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
However, I think that teaching muscle mechanics with (human) motor behaviour and motor control in mind will make the topics more interesting.
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
Skeleton, Muscle, and Motor Control.
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
Specific neuron to specific muscle Spatially represent body in primary motor cortex.
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
The heart is a muscle, but it is not controlled by motor neurons.
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
The motor control area of the Cortex is the first to be Myelinated.
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
The motor cortex within the cerebral cortex of the brain is known to control voluntary respiration because the motor cortex controls voluntary muscle movement.
|
Muscle groups are controlled by the motor cortex .
|
entails
|
There is no danger of confusing heart and lungs, or nerves and muscles, or the visual cortex with the motor cortex, or a school with a garage, and so on.
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
Upon the performance of simple finger motor tasks, subjects with CBD experienced lower levels of activity in the parietal cortex, sensorimotor cortex, and supplementary motor cortex than those individuals tested in a control group.
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
muscle physiology, neural mechanisms, including motor control;
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
muscles and motor mechanisms;
|
Muscle groups are controlled by the motor cortex .
|
neutral
|
Control of the cell cycle in normal and cancer cells.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
neutral
|
Genes causing cancer found in normal cell.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
neutral
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
entails
|
Mutations that lead to cancer usually occur in genes that control the cell cycle.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
entails
|
Normally, tumor suppressor genes constrain or eliminate these renegade cells, but mutations can disable these genes in cancer cells.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
neutral
|
Other known cancer genes are simply mutations of normal genes that control cell proferation which effectively take off the brakes, and the cells to divide out of control.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
entails
|
Researchers have learned that cancer is caused by changes (called mutations or alterations) in genes that control normal cell growth and cell death.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
entails
|
Some toxins cause cancers without causing gene mutations in the affected cells.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
neutral
|
These genes may be inactivated as part of the development of epithelial cancers, releasing the mutated cell from normal cellular controls.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
neutral
|
This can kill cells, cause tumors, and cancers, and mutations in genes.
|
Mutations in regulatory genes that normally control the cell cycle cause cancer.
|
neutral
|
A Natural Resources and Biodiversity Bank Chapter 3.
|
Biodiversity is an important natural resource in and of itself
|
neutral
|
As development continues on Caye Caulker and elsewhere in Belize, it is important to protect the natural resources that contribute to the beauty and biodiversity of the area.
|
Biodiversity is an important natural resource in and of itself
|
neutral
|
Biodiversity and conservation of natural resources.
|
Biodiversity is an important natural resource in and of itself
|
neutral
|
Guyana's biodiversity is an important natural resource that, if used wisely, can help substantially in the development of this country.
|
Biodiversity is an important natural resource in and of itself
|
entails
|
He emphasized the importance of PGRFA as critical components of biodiversity, and the sovereign rights of States over their natural resources.
|
Biodiversity is an important natural resource in and of itself
|
neutral
|
Macro-policies of a social nature are extremely important in providing the human resources needed to implement Biodiversity Prospecting Frameworks.
|
Biodiversity is an important natural resource in and of itself
|
neutral
|
Protection of biodiversity and natural resources.
|
Biodiversity is an important natural resource in and of itself
|
neutral
|
Sections on biodiversity, resources and references and scientific names are included.
|
Biodiversity is an important natural resource in and of itself
|
neutral
|
her research is on the history of concepts of biodiversity and natural resources;
|
Biodiversity is an important natural resource in and of itself
|
neutral
|
5.1.8 Mercury Elemental mercury is a metallic element that is liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury (Hydrargyrum) is the only metal which is liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury Mercury, symbol Hg, is the only metal that is a liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury has many industrial uses, as it is the only metal that is a liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury has relatively weak bonds for a metal and melts at -39 degrees Celsius, so it is a liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury is a heavy metal which exists in a liquid state and evaporates at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury is so poor at forming metallic bonds that it is liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury is the only metal that is in liquid form at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury is the only metallic element that is a liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury is unique in being the only metallic element that is liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury, a metal with such a low melting point that it's a liquid at room temperature, binds to sulfur atoms in living cells and destroys important enzymes, such as those that control nerve cells.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Mercury, for example, is mercury which is a metal but is liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Metallic bonds are variable in strength, giving rise to metals such as mercury (liquid at room temperature) and tungsten (melts at 3407 degrees Celsius).
|
Mercury is the one metal that melts below room temperature.
|
entails
|
Metallic mercury is a liquid at room temperature.
|
Mercury is the one metal that melts below room temperature.
|
entails
|
A jellyfish has no respitory, circulatory, or excretionary organs.
|
A jellyfish does not have a circulatory system.
|
entails
|
Annelids have closed circulatory systems.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Daphnia have open circulatory systems.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Have partially open circulatory system.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Humans have an open circulatory system.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Jellyfish are such a unique kind of marine animal that they actually dont have a specialized circulatory system.
|
A jellyfish does not have a circulatory system.
|
entails
|
Name parts and give the functions of the circulatory system.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Name the general components of the circulatory system.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Name two types of circulatory systems which occur in the animals we have studied in this section of the course.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Simple animals consisting of a single cell layer, such as the (a) sponge, or only a few cell layers, such as the (b) jellyfish, do not have a circulatory system.
|
A jellyfish does not have a circulatory system.
|
entails
|
They all have circulatory systems.
|
A jellyfish does not have a circulatory system.
|
neutral
|
They have a more efficient circulatory system;
|
A jellyfish does not have a circulatory system.
|
neutral
|
They have a very sophisticated circulatory system;
|
A jellyfish does not have a circulatory system.
|
neutral
|
Two basic types of circulatory systems A.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Venoms and poisons of jellyfish and other marine animals can induce damage to the human nervous and circulatory systems.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Vertebrates have a closed circulatory system.
|
A jellyfish does not have a circulatory system.
|
neutral
|
Zebras have a closed circulatory system.
|
A jellyfish does not have a circulatory system.
|
neutral
|
the function of each type of blood vessel in the circulatory system.
|
A jellyfish does not have a circulatory system.
|
neutral
|
6. Use some mothballs
|
Naphthalens is a chemical which is commonly used in mothballs.
|
neutral
|
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