Answer:
The answer is: <u>horizontal plate of</u><u> </u><u>palatine bone</u> and <u>palatine process</u> of the maxilla bone.
Explanation:
The nasal cavity is the bilateral air-filled space present above the roof of the mouth and behind the nose, that forms the interior of the nose.
The hard palate forms the roof of mouth and floor of the nasal cavity. The bones of the hard palate that are present on the <u>floor of nasal cavity </u><u>are the horizontal plate of</u><u> palatine bone</u><u> and </u><u>palatine process</u><u> of the maxilla bone.</u>
Answer:
Pulmonary circulation
Explanation:
is the movement of blood from the heart to the lungs for oxygenation, then back to the heart again. Oxygen-depleted blood from the body leaves the systemic circulation when it enters the right atrium through the superior and inferior venae cavae.
Answer
A. The client may be less sensitive to the effects of a neuromuscular blocking agent.
A. The client may be less sensitive to the effects of a neuromuscular blocking agent.B. Succinylcholine shouldn’t be used; pancuronium may be used in a lower dosage.
A. The client may be less sensitive to the effects of a neuromuscular blocking agent.B. Succinylcholine shouldn’t be used; pancuronium may be used in a lower dosage.C. Pancuronium shouldn’t be used; succinylcholine may be used in a lower dosage.
A. The client may be less sensitive to the effects of a neuromuscular blocking agent.B. Succinylcholine shouldn’t be used; pancuronium may be used in a lower dosage.C. Pancuronium shouldn’t be used; succinylcholine may be used in a lower dosage.D. Pancuronium and succinylcholine both require cautious administration.
Answer:
The processing power of the mammalian brain is derived from the tremendous interconnectivity of its neurons. An individual neuron can have several thousand synaptic connections. While these associations yield computational power, it is the modification of these synapses that gives rise to the brain's capacity to learn, remember and even recover function after injury. Inter-connectivity and plasticity come at the price of increased complexity as small groups of synapses are strengthened and weakened independently of one another (Fig. 1). When one considers that new protein synthesis is required for the long-term maintenance of these changes, the delivery of new proteins to the synapses where they are needed poses an interesting problem (Fig. 1). Traditionally, it has been thought that the new proteins are synthesized in the cell body of the neuron and then shipped to where they are needed. Delivering proteins from the cell body to the modified synapses, but not the unmodified ones, is a difficult task. Recent studies suggest a simpler solution: dendrites themselves are capable of synthesizing proteins. Thus, proteins could be produced locally, at or near the synapses where they are needed. This is an elegant way to achieve the synapse specific delivery of newly synthesized proteins.
Explanation:
