Homeostasis

Question 1

Physiology

Answer 1

-how living organisms function, from molecules to human beings

Question 2

Homeostasis

Answer 2

• defining feature of physiology
• involves the maintenance of nearly constant conditions in the internal environment
• control of numerous Vital parameters- arterial pressure, blood volume, body temperature, nutrients
• dynamic constancy

Question 3

Steady state

Answer 3

• maintenance of nearly constant conditions over time
• not the same as equilibrium
• need to put in energy

Question 4

Equilibrium

Answer 4

• a system when its solute concentrations and other parameters are constant in time without requiring the input of energy from metabolism or other sources
• no energy

Question 5

Cell environment response to changes

Answer 5

• single cells maintain their internal environment in response to changes in the external environment
• semi-permeable cell membrane facilitated the process that provided nutrients to the cell using diffusion, endocytosis etc
• damage to plasma membrane= impair metabolic function, lead to cell death if cell can’t restore homeostasis
• human body contains 100 trillion

Question 6

Multicellular organisms adapt to changes

Answer 6

• in multicellular organisms the basic homeostatic mechanisms of single celled organisms are mirrored by integration of specialized organ systems that create a stable environment for cells
• allows for specialization of cellular functions and a layer of protection for the systems
  ex: lungs exchange gases, digestive tract- uptake of nutrients and water

Question 7

Organs vs organ systems

Answer 7

-Organs- 2 or more kinds of tissues
-Organ systems- collection of organs that perform a general function
- 11:
Circulatory, Digestive, Endocrine, Immune, Integumentary, Lymphatic, Musculoskeletal, Nervous, Reproductive, Respiratory, Urinary
-the functions of organ systems are essential to survival of the body

Question 8

Concept of mass balance

Answer 8

• for a system at steady state for metabolism means that any substance taken in by the body is nearly equal to the amount leaving the body plus that removed by metabolism
• the central compartment (POOL) is usually extracellular fluid (which includes blood plasma)
• it receives substances from intake, synthesis, and release from cells
• it loses by excretion, metabolism, and upstake into cells
• in steady state it is in balance

Question 9

Basal metabolic rate (BMR)

Answer 9

• energy expenditure at rest (kcal/hr/sq meter body surface area)
• largest in daily energy useage (60%), thermic effect of food 8%, nonexercise activity (7%), purposeful physical activity (25%)
• all the chemical processes involved in energy production, energy release and growth- anabolic (formation) or catabolic (breakdown)

Question 10

Resting metabolic rate

Answer 10

• 70 kg man requires 2100 kcal/day
• BMR is less than RMR
• RMR increased in males because of increased muscle
• RMR declines with age (reduced muscle)
• Increased by thyroid hormone, growth hormone, testosterone, epi/norepi
• RMR is higher in people living in arctic vs tropical regions (10-20%)
• malnutrition decreases metabolic rate
• components of energy expenditure

Question 11

Homeostasis and maintaining body fluid balance and electrolytes

Answer 11

• net fluid balance- fluid input needs to match fluid output
• if intake (from food and beverages) exceeds output (urine, fluid in feces, insensible losses), the organism is in positive balance, and urine volume will increase to eliminate excess fluid
• negative fluid balance occurs when intake is less than output, in this case integrated responses will increase thirst and decrease additional fluid losses, until homeostasis is restored

Question 12

Elements in Extracellular fluid are tightly controlled

Answer 12

• need to maintain control over numerous vital parameters to survive and grow
• some elements are controlled within extremely narrow ranges (pH) whereas others fluctuate over broader ranges (plasma glucose)
• loss of control over one or more of these manifests as illness and requires medical attention.
• oxygen, carbon dioxide, sodium ion, potassium ion, calcium, chloride, bicarbonate ion, glucose, body temp, acid-base

Question 13

Homeostasis is a dynamic process

Answer 13

• external environmental conditions that can be far from constant, common physiological variables in healthy humans are maintained within a predictable range
• some variables undergo fairly dramatic swings over the course of a day, yet are still considered to be in balance
• after a typical meal blood glucose levels rise considerably
• hemostatic compensatory mechanisms (endocrine) quickly respond to restore blood glucose to pre-meal levels without overshooting to a significant degree in the opposite direction

Question 14

Negative feedback

Answer 14

• major process used to maintain a stable internal environment (homeostasis)
• it is the initation of responses that counter deviations of a controlled variable from a normal range
• negative feedback loops often operate as part of a larger network of control

Question 15

Feedforward control

Answer 15

• also regulates body systems, particularly when a change with time is desirable (heart rate and breathing increase in anticipation of exercise_
• feedforward and negative feedback also act in combination

Question 16

Positive feedback

Answer 16

-accelerates a process and thus can be unstable; it is less common in nature than negative feedback, but important in many cases

Question 17

Negative Feedback at Molecular Level

Answer 17

• Homeostatic control is redundant, exerted at many levels
• enzyme: product formed from a substrate by an enzyme negatively feeds back to inhibit further activation of the enzyme- end product inhibition, can be done by chemical modification of the enzyme by reaction product
• ex: energy stores depleted, glucose is metabolized to make ATP. Atp levels restore, inhibit specific enzymes that breakdown glucose

Question 18

Negative Feedback at Systems Level

Answer 18

• major control of the synthesis and secretion of thyroid hormones from the thyroid gland is via the hypothalamic-pituitary axis
• thyrotropin-releasing hormone (TRH) from the hypothalamus acts on the anterior pituitary gland to increase secretion of the thyroid stimulating hormone (TSH)
• TSH acts on the thyroid gland to increase synthesis and secretion of TH
• TH acts on target tissues through body to increase BMR and heat generation
• TH neg feeds on anterior pituitary to prevent too much or too little TSH release
• common to endocrine system- adrenal gland, gonads

Question 19

Gain

Answer 19

• capacity of the system to restore a controlled variable to its set point after a perturbation
• the degree of effectiveness with which a control system maintains constant conditions is determined by the gain of negative feedback
• the higher the gain, the better it is to restore a controlled variable to its set point in response to a perturbation
• gain= correction/remaining error, it is 4 for baroreceptor system. In response to hemorrhage the person would get thirsty
• feedback for temp has gain of 25-30

Question 20

Problems with positive feedback

Answer 20

• recovery of heart pumping by negative feedback after 1 L blood lost
• death is caused by positive feedback when 2 L removed
• the initiating stimulus causes more of the same- decreased blood pressure, decreased blood flow to the heart- the heart is weakened further- diminishing blood flow and death

Question 21

Useful positive feedback

Answer 21

• blood clotting after vessel rupture
• uterine contractions during childbirth
• estrogen effects on the pituitary-hypothalamus before ovulation
• generation of an all or none action potential via Na+ channel activation
• calcium-induced calcium release in heart

Question 22

Generalization about Homeostasis

Answer 22

• stability of internal environment based on balancing inputs and outputs
• in neg feedback a change in variable being regulated brings about the responses that tend to move the variable in the direction opposite the original change- that is, back toward the initial value (set point)
• cannot maintain complete constant- there is a narrow range of normal valves
• set points can be reset higher or lower
• all homeostatic control systems can’t all be regulated in the normal ranges in every environmental challenges- need hierarchy of importance