Term
| some functions of the respiratory system |
|
Definition
| -Ventilation (breathing)
-Gas exchange
-O2 utilization and CO2 production
[image]
[image] |
|
|
Term
| how the respiratory system functions for ventilation (breathing) |
|
Definition
To move air into and out of respiratory system.
[image] |
|
|
Term
| how the respiratory system functions for gas exchange |
|
Definition
-External respiration
-Internal respiration
-Pressure gradients generate diffusion
[image] |
|
|
Term
| how the respiratory system functions for O2 utilization and CO2 production |
|
Definition
Cellular respiration
[image] |
|
|
Term
|
Definition
gas exchange between air and capillaries in the lungs
[image] |
|
|
Term
|
Definition
gas exchange between systemic capillaries and tissues of the body
[image] |
|
|
Term
| 2 zones in the airway passages |
|
Definition
-Conducting zone
-respiratory zone
[image] |
|
|
Term
|
Definition
-Outside the lungs – nasal passages --> pharynx --> epiglottis --> larynx (glottis)
-Inside the lungs – trachea (1) --> bronchus (2 branches) --> bronchiole --> … --> terminal bronchiole
[image] |
|
|
Term
|
Definition
Respiratory bronchiole --> … --> alveolar sacs
[image] |
|
|
Term
| diameter, length, number, and area of different parts of the airway |
|
Definition
|
|
Term
| how collapsing of the trachea and the rest of the conducting zone is prevented |
|
Definition
| rings of cartilage around the trachea and bronchi |
|
|
Term
| Functions of the Conducting Zone of the airways |
|
Definition
-Passage of air
-Warming
-Humidification
-Filtration
-Immune surveillance
[image] |
|
|
Term
| where does the water for humidification in the airway come from? |
|
Definition
|
|
Term
| the role of the mucociliary apparatus |
|
Definition
removing particulates in the conducting zone
-you wind up either swallowing it or coughing it out
[image] |
|
|
Term
| Functions of the Respiratory Zone |
|
Definition
-Passage of air
-Gas exchange
-Immune surveillance
[image] |
|
|
Term
| number, size, and shape of alveoli |
|
Definition
| -Total # = ~300 x 106
-0.25 - 0.5 mm in diameter
-Total area = 60 - 80 m2
[image] |
|
|
Term
| the 2 types of cells in the alveolar wall |
|
Definition
-Type I alveolar cells
-Type II alveolar cells
[image] |
|
|
Term
| function of Type I alveolar cells |
|
Definition
the major lining cells, accounts for 95-97% of total surface area
[image] |
|
|
Term
| function of Type II alveolar cells |
|
Definition
production of surfactants
[image] |
|
|
Term
|
Definition
-~0.3 μm
-barrier between blood and air that allows gas exchange to occur
[image] |
|
|
Term
| depiction of the net capillaries form over the alveoli |
|
Definition
|
|
Term
| depiction of the air-blood barrier |
|
Definition
|
|
Term
| the Layers of the respiratory membrane: |
|
Definition
1. Fluid layer with surfactant. (Surfactant coats the inside of the alveolus).
2. Type I alveolar cell membranes.
(3. Narrow interstitial space, if any.)
4. Capillary endothelial cell membranes.
[image] |
|
|
Term
| depiction of the thoracic cavity in its context |
|
Definition
|
|
Term
| Thoracic cavity surrounded by... |
|
Definition
rib cage (chest wall) and the respiratory muscles.
[image] |
|
|
Term
| Pleural (intra-pleural) space |
|
Definition
-Thin fluid layer between visceral pleura covering lungs (visceral) and parietal pleura lining thoracic cavity walls.
-*Air-free, potential space --> lungs cling to inside of thorax.
-basically makes the lungs adhere to the thoracic cavity
[image][image] |
|
|
Term
|
Definition
muscle between thoracic & abdominal cavities
[image] |
|
|
Term
|
Definition
-active process:
1. Contraction of diaphragm --> ↑ thoracic vol vertically
2. Parasternal and external intercostals contract --> raising the ribs --> ↑ thoracic vol laterally (horizontally); makes the rib cage bigger
[image] |
|
|
Term
|
Definition
muscles between the ribs that cause the thoracic cavity to expand horizontally (laterally)
[image] |
|
|
Term
| the 2 types of expiration in breathing |
|
Definition
-quiet expiration
-forced expiration
[image] |
|
|
Term
|
Definition
| passive process, relaxation of inspiratory muscles.
[image] |
|
|
Term
|
Definition
| active process assisted by the abdominal muscles.
[image] |
|
|
Term
| some functions of the respiratory system |
|
Definition
| -Ventilation (breathing)
-Gas exchange
-O2 utilization and CO2 production
[image]
[image] |
|
|
Term
| how the respiratory system functions for ventilation (breathing) |
|
Definition
To move air into and out of respiratory system.
[image] |
|
|
Term
| how the respiratory system functions for gas exchange |
|
Definition
-External respiration
-Internal respiration
-Pressure gradients generate diffusion
[image] |
|
|
Term
| how the respiratory system functions for O2 utilization and CO2 production |
|
Definition
Cellular respiration
[image] |
|
|
Term
|
Definition
gas exchange between air and capillaries in the lungs
[image] |
|
|
Term
|
Definition
gas exchange between systemic capillaries and tissues of the body
[image] |
|
|
Term
| 2 zones in the airway passages |
|
Definition
-Conducting zone
-respiratory zone
[image] |
|
|
Term
|
Definition
-Outside the lungs – nasal passages --> pharynx --> epiglottis --> larynx (glottis)
-Inside the lungs – trachea (1) --> bronchus (2 branches) --> bronchiole --> … --> terminal bronchiole
[image] |
|
|
Term
|
Definition
Respiratory bronchiole --> … --> alveolar sacs
[image] |
|
|
Term
| diameter, length, number, and area of different parts of the airway |
|
Definition
|
|
Term
| how collapsing of the trachea and the rest of the conducting zone is prevented |
|
Definition
| rings of cartilage around the trachea and bronchi |
|
|
Term
| Functions of the Conducting Zone of the airways |
|
Definition
-Passage of air
-Warming
-Humidification
-Filtration
-Immune surveillance
[image] |
|
|
Term
| where does the water for humidification in the airway come from? |
|
Definition
|
|
Term
| the role of the mucociliary apparatus |
|
Definition
removing particulates in the conducting zone
-you wind up either swallowing it or coughing it out
[image] |
|
|
Term
| Functions of the Respiratory Zone |
|
Definition
-Passage of air
-Gas exchange
-Immune surveillance
[image] |
|
|
Term
| number, size, and shape of alveoli |
|
Definition
| -Total # = ~300 x 106
-0.25 - 0.5 mm in diameter
-Total area = 60 - 80 m2
[image] |
|
|
Term
| the 2 types of cells in the alveolar wall |
|
Definition
-Type I alveolar cells
-Type II alveolar cells
[image] |
|
|
Term
| function of Type I alveolar cells |
|
Definition
the major lining cells, accounts for 95-97% of total surface area
[image] |
|
|
Term
| function of Type II alveolar cells |
|
Definition
production of surfactants
[image] |
|
|
Term
|
Definition
-~0.3 μm
-barrier between blood and air that allows gas exchange to occur
[image] |
|
|
Term
| depiction of the net capillaries form over the alveoli |
|
Definition
|
|
Term
| depiction of the air-blood barrier |
|
Definition
|
|
Term
| the Layers of the respiratory membrane: |
|
Definition
1. Fluid layer with surfactant. (Surfactant coats the inside of the alveolus).
2. Type I alveolar cell membranes.
(3. Narrow interstitial space, if any.)
4. Capillary endothelial cell membranes.
[image] |
|
|
Term
| depiction of the thoracic cavity in its context |
|
Definition
|
|
Term
| Thoracic cavity surrounded by... |
|
Definition
rib cage (chest wall) and the respiratory muscles.
[image] |
|
|
Term
| Pleural (intra-pleural) space |
|
Definition
-Thin fluid layer between visceral pleura covering lungs (visceral) and parietal pleura lining thoracic cavity walls.
-*Air-free, potential space --> lungs cling to inside of thorax.
-basically makes the lungs adhere to the thoracic cavity
[image][image] |
|
|
Term
|
Definition
muscle between thoracic & abdominal cavities
[image] |
|
|
Term
|
Definition
-active process:
1. Contraction of diaphragm --> ↑ thoracic vol vertically
2. Parasternal and external intercostals contract --> raising the ribs --> ↑ thoracic vol laterally (horizontally); makes the rib cage bigger
[image] |
|
|
Term
|
Definition
muscles between the ribs that cause the thoracic cavity to expand horizontally (laterally)
[image] |
|
|
Term
| the 2 types of expiration in breathing |
|
Definition
-quiet expiration
-forced expiration
[image] |
|
|
Term
|
Definition
| passive process, relaxation of inspiratory muscles.
[image] |
|
|
Term
|
Definition
| active process assisted by the abdominal muscles.
[image] |
|
|
Term
|
Definition
-At a constant temperature P1V1 = P2V2
-Thoracic expansion and contraction -> air movement
-pressure and volume have an inverse relationship in the lungs
[image] |
|
|
Term
| How do we get O2 into the body and CO2 out of the body? |
|
Definition
-Ventilation = air in and out of lungs
-Results from pressure differences (gradient) induced by changes in lung volumes
-Pressure (P) gradient – results in net gas flow & diffusion from high P to low P
[image] |
|
|
Term
| flow of O2 and CO2 in respiration |
|
Definition
| -For PO2 – alveolar space > blood plasma > interstitial fluid > cytosol > mitochondria
-For PCO2 – mitochondria > cytosol > interstitial fluid > blood plasma > alveoli
-this flow is caused by partial pressures
[image] |
|
|
Term
| the 3 pressures to follow in respiration |
|
Definition
-Atmospheric
-Alveolar (Intrapulmonary)
-Pleural (Intrapleural)
[image] |
|
|
Term
|
Definition
|
|
Term
| Alveolar (Intrapulmonary) pressure |
|
Definition
at rest, during inspiration, during expiration
[image] |
|
|
Term
| Pleural (Intrapleural) pressure |
|
Definition
at rest, during inspiration, during expiration
[image] |
|
|
Term
| the 3 phases of breathing |
|
Definition
-at rest
-inspiration
-expiration
[image] |
|
|
Term
| the interplay between the recoil of the lungs and the chest wall |
|
Definition
| -The lung tends to recoil inward and the chest wall outward
-*These recoil forces in opposite directions create a negative (sub-atmospheric) pleural pressure: -3 to -4 mm Hg relative to atmospheric and alveolar pressures.
+-> Lungs expand and contract along with the thoracic cavity.
[image] |
|
|
Term
| What happens if the pleural space is disrupted by air or fluid? |
|
Definition
lungs basically collapse due to the greater pleural space
-Air (pneumothorax) or fluid (hydrothorax, generically) -> relative negative pressure lost -> lung lobes collapse.
-New pressure gradient -> pneumothorax.
[image] |
|
|
Term
|
Definition
separates each side of thorax; this is why only one lung is affected by the disruption of the pleural space
[image] |
|
|
Term
| Mechanics of Breathing (Ventilation) during inspiration |
|
Definition
-Contraction of inspiratory muscles --> ↑ chest vol --> ↑ pleural vol --> ↓ pleural P --> ↑ lung vol --> ↓ alveolar P
---> atmospheric P > alveolar P --> generation of pressure gradient --> air to flows into the lung
-Energy -> muscular contraction -> works against the elastic recoil forces of the lung. |
|
|
Term
| Mechanics of Breathing (Ventilation) during expiration |
|
Definition
-↓ lung vol --> ↑ alveolar pressure above atmosphere (alveolar P > atmospheric P) --> air goes out
-Elastic recoil forces of the lung contribute to change in pressure gradient. |
|
|
Term
| how alveolar and pleural pressure change during inspiration and expiration |
|
Definition
|
|
Term
|
Definition
ALWAYS lower than alveolar P & atmospheric P
-ALWAYS negative (sub-atmospheric) |
|
|
Term
|
Definition
| may be “-” (inspiration) or “+” (expiration) |
|
|
Term
|
Definition
Trans-pulmonary P = Δ P across the wall of the lung
Δ P across the wall of the lung = Alveolar P – Pleural P
-Always positive
-Increasing difference vs. decreasing difference. |
|
|
Term
|
Definition
-tidal vol (TV)
-inspiratory reserve vol (IRV)
-expiratory reserve vol (ERV)
-residual vol (RV)
[image] |
|
|
Term
|
Definition
-inspiratory capacity (IC)
-functional residual capacity (FRC)
-vital capacity (VC)
-total lung capacity (TLC)
[image] |
|
|
Term
| Timed vital capacity (or forced expiration volume for the 1st second, FEV1) |
|
Definition
normal is > 80%
-this is the amount of air you can force out of your lungs within the first second of a forceful breath out
-can be used to assess lung function
[image] |
|
|
Term
|
Definition
the volume of gas inspired or expired in an unforced respiratory cycle at rest
[image] |
|
|
Term
|
Definition
the volume of gas remaining in the lungs after a maximum expiration
[image] |
|
|
Term
|
Definition
the total amount of gas in the lungs after a maximum inspiration
[image] |
|
|
Term
|
Definition
the maximum amount of gas that can be expired after a maximum inspiration
[image] |
|
|
Term
|
Definition
regions of the airways that are ventilated but no gas exchange occurs
[image] |
|
|
Term
|
Definition
anatomic dead space + alveolar dead space
[image] |
|
|
Term
|
Definition
| -*Air in the conducting airways of respiratory system that does NOT participate in the gas exchange.
-Not all of the inspired air reaches the alveoli.
-Inhaled fresh air mixed with expired air in anatomical dead space.
[image] |
|
|
Term
| Alveolar or functional dead space |
|
Definition
-*Air in the respiratory zone that is ventilated but does NOT participate in gas exchange.
-Due to lack of blood flow to those alveoli.
[image] |
|
|
Term
| Ventilation-Perfusion Ratio (V/Q) |
|
Definition
| -VA = alveolar ventilation
-Q = blood flow
-For efficient gas exchange (O2 in, CO2 out), want level of ventilation to match blood flow in alveoli. V/Q ≈ 0.8
-VA is greater in the apices of the lungs -> high V/Q – overventilated and underperfused
-Q is greater in the basal lung lobes -> low V/Q – underventilated and overperfused
[image] |
|
|
Term
| the part of the lungs that is overventilated and underperfused and why that is |
|
Definition
| VA is greater in the apices of the lungs -> high V/Q – overventilated and underperfused
[image] |
|
|
Term
| the part of the lungs that is underventilated and overperfused and why that is |
|
Definition
Q is greater in the basal lung lobes -> low V/Q – underventilated and overperfused
[image] |
|
|
Term
| ideal Ventilation-Perfusion Ratio (V/Q) |
|
Definition
| 0.8
-For efficient gas exchange (O2 in, CO2 out), want level of ventilation to match blood flow in alveoli. |
|
|
Term
| why putting COVID-19 patients on their sternum helps them breathe |
|
Definition
| because it helps open up some lung space on the dorsal side |
|
|
Term
| what Systemic arterioles (e.g., muscle beds) do in response to low arterial O2 levels (PaO2) |
|
Definition
| they dilate if arterial O2 levels (PaO2) are low -> more blood with O2 delivered. |
|
|
Term
| what Pulmonary arterioles do in response to alveolar O2 (PAO2) levels |
|
Definition
| they constrict if alveolar O2 levels (PAO2) are low. Dilate if PAO2 high.
[image] |
|
|
Term
| the factors affecting ventilation |
|
Definition
-compliance
-elastance (elasticity)
-surface tension |
|
|
Term
|
Definition
distensibility (stretchability)
-Change in lung vol per change in transpulmonary P
+Compliance = ΔV/ΔP
-100 x more distensible than a balloon
-Compliance is affected by elastance (2) ; and surface tension (3) |
|
|
Term
|
Definition
recoil ability, resistance to distension
-Elasticity = 1/compliance
-Tendency to return to initial size after distension.
-High content of elastin proteins
-Elastic tension ↑ during inspiration and ↓ during expiration |
|
|
Term
| Compliance is affected by... |
|
Definition
-elastance
-surface tension |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
Reflects the work needed to ↑ surface area of a liquid at an interface.
[image] |
|
|
Term
|
Definition
P in alveoli is directly proportional to surface tension; and inversely proportional to radius of alveoli.
-T is the same for same interface.
-For the same T, smaller alveoli have higher P to collapse than larger alveoli.
-r=2 (P=T) vs. r=1 (P=2T) --> collapse of smaller alveoli
-↑ P --> ↓ compliance --> takes more energy to expand.
[image] |
|
|
Term
| equation for the Law of Laplace |
|
Definition
P = (2 x T) / r
where P = pressure, T = surface tension, and r = radius
[image] |
|
|
Term
|
Definition
-Produced by type II alveolar cells (pneumocytes).
1. Phospholipids – amphipathic; act as surfactant
2. Surfactant proteins – help distribute phospholipids.
[image] |
|
|
Term
| functions of surfactants in the lungs |
|
Definition
-Lower surface tension --> ↑ compliance.
-Prevent collapse of smaller alveoli.
+As alveoli radius decreases, surfactant’s ability to lower surface tension increases. |
|
|
Term
| Newborn respiratory distress syndrome |
|
Definition
-Occurs in ~10% of premature neonates.
-Underdeveloped anatomy.
-Surfactant insufficiency; not enough surfactant and thus less compliance, making it harder to breathe.
-Every breath is like the first breath.
[image][image] |
|
|
Term
| how the alveoli in Newborn respiratory distress syndrome differ from those in healthy newborns |
|
Definition
|
|
Term
| some ways Newborn respiratory distress syndrome can be treated |
|
Definition
-administering surfactants endotrachially
-corticosteroids; stimulate development of type I and type II pneumocytes |
|
|
Term
| Restrictive Disorders (breathing) |
|
Definition
| -Ex., pulmonary fibrosis
-Accumulation of fibrous connective tissue in alveolar wall.
-↓ vital capacity; normal FEV1; ↓ compliance
-*Reduced lung volume
[image] |
|
|
Term
| examples of restrictive pulmonary disorders |
|
Definition
|
|
Term
| the phase of breathing affected by restrictive disorders |
|
Definition
|
|
Term
| Obstructive Disorders (breathing) |
|
Definition
| -Ex., asthma, cystic fibrosis
-Vital capacity may be normal; FEV1 is < 80%
-*Reduced airflow
[image][image] |
|
|
Term
| examples of pulmonary Obstructive Disorders |
|
Definition
|
|
Term
| the phase of breathing affected by obstructive disorders |
|
Definition
|
|
Term
|
Definition
-alveolar tissue is destroyed, compliance
-Chronic progressive; reduces surface area for gas exchange
-Cigarette smoking --> ↑ WBC proteinases secretion --> ↑ destruction tissue proteins ↑ collapse of alveolar sacs
[image] |
|
|
Term
|
Definition
chronic obstructive pulmonary disease
-Asthma & emphysema |
|
|
Term
|
Definition
| the law of partial pressures
-The pressure exerted by each component in a gaseous mixture is independent of other gases in the mixture, and the total pressure of the mixture of gases is equal to the sum of the separate pressures.
-PB = PCO2 + PO2 + PN2 + PH2O = 760 mm Hg atmospheric pressure (PB = barometric pressure
-Movement of individual gases |
|
|
Term
|
Definition
C = kP
-Concentration of gas in liquid = solubility x partial pressure in liquid.
-At equilibrium, partial pressure is equal on both gas and liquid sides, but # of molecules varies depending on solubility of the gas.
[image] |
|
|
Term
|
Definition
C = kP
Concentration of gas in liquid (C) = solubility (k) x partial pressure in liquid (P) |
|
|
Term
|
Definition
| dissolved in blood plasma |
|
|
Term
| depiction of how partial pressures dictate the movement of O2 and CO2 |
|
Definition
| [image]
PA = partial pressure alveolar
Pa = partial pressure arterial
Pv = partial pressure venous |
|
|
Term
| blood flow rate in pulmonary vs. systemic circulation |
|
Definition
Rate of blood flow through the pulmonary circulation = flow rate through the systemic circulation
that is, the amount of blood entering the pulmonary circulation is equal to the amount of blood entering the systemic circulation |
|
|
Term
| depiction of the path blood takes from the tissues --> right heart --> lungs --> left heart --> tissues |
|
Definition
[image]
Please know the path of blood through the heart, lungs, and systemic circulation. |
|
|
Term
| why Pulmonary vascular resistance is lower than systemic vascular resistance |
|
Definition
because of less smooth muscle in the pulmonary vessels
this may be to prevent rupture of vessels in the lungs |
|
|
Term
| the pressure gradient for O2 is 64, but the one for CO2 is only 5, so why does it work? |
|
Definition
| because CO2 has a much higher diffusion rate in fluid/tissue phase vs. O2
Solubility coefficient CO2/solubility coefficient O2 = 0.57/0.024 = 23.75/1
-Need a much higher diffusion gradient for O2 to supply enough molecules to tissues to produce ATP.
-Much lower diffusion gradient for CO2 needed to bring enough molecules to lung for exhalation. |
|
|
Term
| where the O2 is in the blood |
|
Definition
| -Dissolved O2 (< 2%)
-Hb-O2 (> 98%) |
|
|
Term
| amount of hemoglobin in red blood cells and how much O2 they carry |
|
Definition
| 280 million Hb/Red Blood Cell
-Each Hb has 4 polypeptide chains (2 alpha, 2 beta) and 4 hemes
-*1 heme binds to 1 O2, thus 1 Hb binds to 4 O2 maximally
[image] |
|
|
Term
|
Definition
| ↓ RBCs -> [Hb] below normal |
|
|
Term
|
Definition
| ↑ RBCs -> [Hb] above normal |
|
|
Term
|
Definition
| controls Hb production
-Production stimulated by PCO2 delivery to kidneys |
|
|
Term
| some types of hemoglobin associated with health problems |
|
Definition
-Methemoglobin
-Carboxyhemoglobin |
|
|
Term
|
Definition
| Fe2+ oxidized -> Fe3+, cannot bind with O2
-Brown blood, brownish-blue mucous membranes
-this can be caused by nitrates and other substances that can oxidize hemoglobin
-can be treated by reducing agents such as methylene blue and ascorbic acid |
|
|
Term
|
Definition
| (CO-Hb) – carbon monoxide.
-The bond with CO is 210x stronger than the bond with O2.
-Transport of O2 to tissues is impaired.
-the CO can't be used for oxidative phosphorylation |
|
|
Term
|
Definition
| [image]
-X-axis denotes PO2 (mm Hg)
-Y-axis denotes O2 saturation rate (%) or O2 content (mL O2 /dL blood)
-The higher the PO2, the higher Hb-O2 saturation |
|
|
Term
| the pathway by which O2 is loaded onto hemoglobin and the saturation it reaches |
|
Definition
| Gas exchange at alveolar space → loading of O2 → oxygenated blood → PO2 = 100 mm Hg → O2-Hb is ~98%
[image] |
|
|
Term
| the pathway by which O2 is unloaded off of hemoglobin and the saturation it reaches |
|
Definition
| At peripheral tissues → unloading of O2 → deoxygenated blood → PO2 = to 40 mm Hg → O2-Hb is ~ 75%
[image] |
|
|
Term
| why muscles use myoglobin |
|
Definition
| to maintain a steady O2 supply |
|
|
Term
| depiction of the cooperative binding of hemoglobin to O2 and how it changes affinity to O2 |
|
Definition
|
|
Term
| the Hb-O2 Curve shifting to the left indicates... |
|
Definition
| increased affinity of Hb for O2
[image] |
|
|
Term
| the Hb-O2 Curve shifting to the right indicates... |
|
Definition
| decreased affinity of Hb for O2
[image] |
|
|
Term
| what increased affinity of hemoglobin to O2 means in the lungs and tissues |
|
Definition
| -for the lungs, it means loading a little more O2 onto the hemoglobin
-for the tissues, it means more O2 remains on the hemoglobin in the tissues
[image] |
|
|
Term
| what decreased affinity of hemoglobin to O2 means in the lungs and tissues |
|
Definition
| -for the lungs, it means a little less O2 being loaded onto the hemoglobin
-for the tissues, it means a lot more O2 unloaded in the tissues
[image] |
|
|
Term
| when the Hb-O2 curve shifts to the right |
|
Definition
| when there's more need for O2 in the tissues
[image] |
|
|
Term
| some factors that cause the Hb-O2 curve to shift to the right |
|
Definition
| -↓ pH (acidosis) → right shift
-↑ PCO2 (suggests hypoxemia) → right shift (Bohr effect)
-↑ temperature → right shift
-↑ [2,3-DPG] in RBC → right shift
[image] |
|
|
Term
| some factors that cause the Hb-O2 curve to shift to the left |
|
Definition
| -↑ pH (alkalosis) → left shift
-↓ PCO2 (suggests hypoxemia) → left shift (Bohr effect)
-↓ temperature → left shift
-↓ [2,3-DPG] in RBC → left shift
[image] |
|
|
Term
| 2,3-diphosphoglycerate or 2,3 bisphosphoglycerate (2,3-BPG) |
|
Definition
-Metabolic by-product of glycolysis in RBCs.
-O2 inhibits its production.
-2,3-DPG binds Hb -> decrease in affinity for O2 -> right shift where more O2 is released in tissues.
-2,3-DPG production ↑ with hypoxemic conditions
+Anemia
+High altitudes
+Some forms of chronic lung disease
[image] |
|
|
Term
| how 2,3-DPG causes right shift in the Hb-O2 curve |
|
Definition
| 2,3-DPG binds Hb -> decrease in affinity for O2 -> right shift where more O2 is released in tissues
[image] |
|
|
Term
| some hypoxemic conditions that cause ↑ 2,3-DPG production |
|
Definition
-Anemia
-High altitudes
-Some forms of chronic lung disease |
|
|
Term
|
Definition
| -Red pigment found exclusively in striated muscle (skeletal and cardiac muscle fibers).
-*Has a higher affinity for O2 than Hb.
[image] |
|
|
Term
| what myoglobin does in muscles |
|
Definition
| -Ferrying effect – acts as a “go-between” in the transfer of O2 from blood to the mitochondria within muscle cells.
-O2 storage function – in cardiac muscles. |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
| 2 major classes of acids in body |
|
Definition
-volatile acid
-non-volatile acid |
|
|
Term
|
Definition
| can be converted to a gas
-CO2 in bicarbonate buffer system can be breathed out (lungs). |
|
|
Term
|
Definition
cannot leave blood
-lactic acid, fatty acids, ketone bodies
-Need to bind to buffer molecules |
|
|
Term
| examples of volatile acids in the blood |
|
Definition
| CO2 in bicarbonate buffer system can be breathed out (lungs). |
|
|
Term
| examples of non-volatile acids in the blood |
|
Definition
-lactic acid
-fatty acids
-ketone bodies
-Need to bind to buffer molecules |
|
|
Term
| Buffers in the body for non-volatile acids include... |
|
Definition
| -HCO3–
-PO42–
-proteins including Hb |
|
|
Term
| how kidneys help regulate blood pH |
|
Definition
| -excrete H+ into urine
-reabsorb HCO3- from urine |
|
|
Term
| the formula for the bicarbonate buffer system |
|
Definition
| CO2 + H2O ⇌ H2CO3 ⇌ H+ + HCO3-
[image] |
|
|
Term
| the bicarbonate buffer system the blood uses |
|
Definition
|
|
Term
| carbonic anhydrase enzyme (CA) |
|
Definition
-Catalyzes reaction both directions.
-Higher expression in RBCs, gastric mucosa, pancreatic exocrine cells, renal tubules.
[image] |
|
|
Term
| Henderson-Hasselbalch equation relating to blood |
|
Definition
| pH = 6.1 + log ( [HCO3-] / [CO2] ) |
|
|
Term
| [CO2] is adjusted by ______, [HCO3-] by kidneys |
|
Definition
|
|
Term
| Free H+ in ______ concentrations, free HCO3- in mmol/L concentrations. |
|
Definition
|
|
Term
| What effect does adding HCO3- have on plasma [H+]? |
|
Definition
|
|
Term
| What does increased [HCO3-] do to pH? |
|
Definition
|
|
Term
| What does decreased [HCO3-] do to pH? |
|
Definition
|
|
Term
| What effect does adding CO2 have on plasma [H+]? |
|
Definition
|
|
Term
| What does increased [CO2] do to pH? |
|
Definition
|
|
Term
| What does decreased [CO2] do to pH? |
|
Definition
|
|
Term
| what ventilation adjusts itself to and why |
|
Definition
| Ventilation usually adjusted to metabolic rate to maintain normal CO2 levels. |
|
|
Term
| So how would the lungs (controlled by the brain) respond to ↑ plasma [CO2], ↑ plasma [H+], and ↓ plasma pH? |
|
Definition
| increase breathing rate to release CO2 and bring the pH back into balance
[image] |
|
|
Term
| And how would the lungs (controlled by the brain) respond to ↓ plasma [CO2], ↓ plasma [H+], and ↑ plasma pH? |
|
Definition
| decrease breathing rate to retain CO2 and bring the pH back into balance
[image] |
|
|
Term
|
Definition
| -Caused by hypoventilation, which can be caused by CNS depression, neuromuscular disorders, chest wall restriction, pulmonary tissue disease, airway obstruction.
-Accumulation of CO2 in the tissues --> ↑ PCO2 in blood --> ↓ pH in blood |
|
|
Term
|
Definition
| -Caused by hyperventilation, which can be caused by CNS disease, acute asthma, hypoxemia.
-Excessive loss of CO2 --> ↓ PCO2 --> ↑ pH in blood |
|
|
Term
| 3 forms of CO2 that are transported in the blood |
|
Definition
| -Dissolved CO2 (10%) – accounts for PCO2
-HCO3- (70%)
-Carbaminohemoglobin (20%)
+Unloading of O2 --> Hb-CO2 formed
+CO2 does NOT bind heme in Hb. |
|
|
Term
| does CO2 bind the heme in hemoglobin? |
|
Definition
|
|
Term
| how Carbaminohemoglobin is formed |
|
Definition
| Unloading of O2 --> Hb-CO2 formed
[image] |
|
|
Term
| Carbonic anhydrase is located in... |
|
Definition
|
|
Term
| how bicarbonate (HCO3-) gets transported across the plasma membrane of red blood cells |
|
Definition
| Antiporter exchanges chloride (Cl-) for bicarbonate (HCO3-).
[image] |
|
|
Term
|
Definition
| hemoglobin with CO2 bound to one of the amino acids |
|
|
Term
| how Cl-/HCO3- exchange differs systemic capillaries and pulmonary capillaries |
|
Definition
| Cl- goes into the red blood cell in the systemic capillaries and out of the red blood cell in pulmonary capillaries |
|
|
Term
| how regulation of breathing helps maintain homeostasis |
|
Definition
| For metabolic homeostasis, the frequency and amplitude of breathing must respond to metabolic changes. |
|
|
Term
| some sensors involved in regulation of breathing |
|
Definition
-Chemoreceptors for chemical changes
-mechanoreceptors for mechanical changes
[image] |
|
|
Term
| the integrator involved in regulation of breathing |
|
Definition
|
|
Term
| the effectors involved in regulation of breathing |
|
Definition
respiratory muscles
[image] |
|
|
Term
| the respiratory centers of the brain stem |
|
Definition
-Rhythmicity center (medulla)
-Apneustic center (pons)
-Pneumotaxic center (pons)
[image] |
|
|
Term
| how the brain acts as an integrator in regulation of breathing |
|
Definition
| -Continuous display of voluntary and involuntary actions.
-Voluntary action is done by cerebrum, hypothalamus, limbic system (anger).
-Involuntary action is done by the brain stem respiratory centers (medulla oblongata and pons).
-Brain stem respiratory centers
+Rhythmicity center (medulla)
+Apneustic center (pons)
+Pneumotaxic center (pons)
[image][image] |
|
|
Term
| the 2 groups of chemoreceptors that help regulate breathing by monitoring changes in blood PCO2, PO2, and pH. |
|
Definition
-Central chemoreceptors
-Peripheral chemoreceptors |
|
|
Term
|
Definition
| -Located in medulla, different from the rhythmicity center.
-More sensitive to blood PCO2 than blood pH (due to the blood-brain barrier (BBB)). |
|
|
Term
| Peripheral chemoreceptors |
|
Definition
| -Carotid and aortic bodies
-Directly detect changes in PO2
-Indirectly detect changes in PCO2 through pH
+H2O + CO2 <--> H2CO3 <--> H+ + HCO3-
-More sensitive to changes in blood pH than PO2
[image] |
|
|
Term
| the types of peripheral chemoreceptors |
|
Definition
-Carotid bodies
-aortic bodies |
|
|
Term
| depiction of chemoreceptor cells and baroreceptor cells |
|
Definition
[image]
-Baroreceptors: Carotid sinuses and aortic arch
-Chemoreceptors: Carotid bodies and aortic bodies |
|
|
Term
| Pulmonary Mechanoreceptors |
|
Definition
| -Detect mechanical changes of breathing (volume and frequency).
-Influence the brain stem respiratory control centers via sensory fibers in vagus nerves.
-Pulmonary stretch receptors (PSR)
+detect volume changes
+present in the smooth muscle of the airways
+slowly adapting
+activated during inspiration to force expiration |
|
|
Term
| Pulmonary stretch receptors (PSR) |
|
Definition
the main type of pulmonary mechanoreceptors
-detect volume changes
-present in the smooth muscle of the airways
-slowly adapting
-activated during inspiration to force expiration |
|
|
Term
| Hering-Breuer inflation reflex |
|
Definition
Triggered to prevent over-inflation of the lungs
[image] |
|
|
Term
| some types of pulmonary mechanoreceptors |
|
Definition
-Pulmonary stretch receptors (PSR)
-Pulmonary irritant receptors (PIR)
-Unmyelinated C fibers |
|
|
Term
| Pulmonary irritant receptors (PIR) |
|
Definition
-A.k.a. – rapidly adaptive receptors on Aδ fibers
-Detect frequency of breathing
-Respond to smoke, smog, and particulates -> cause coughing
[image] |
|
|
Term
|
Definition
-Sensory neurons located in lungs
-Stimulated by noxious substances such as capsaicin
-Produces initial apnea -> rapid, shallow breathing
[image] |
|
|
Term
|
Definition
| Located in medulla oblongata
-generate automatic basic rhythm of breathing
-Basic rhythm is irregular, erratic, and unstable. It is NOT the normal rhythm
-Consists of interacting neurons that fire either during inspiration (I neurons) or expiration (E neurons)
-Quiet expiration is a passive process that occurs when the I neurons are inhibited
[image] |
|
|
Term
|
Definition
| interacting neurons in the rhythmicity center that fore during inspiration |
|
|
Term
|
Definition
| interacting neurons in the rhythmicity center that fore during expiration |
|
|
Term
| divisions of the rhythmicity center |
|
Definition
-dorsal respiratory group (DRG)
-ventral respiratory group (VRG) |
|
|
Term
| Dorsal respiratory group (DRG) |
|
Definition
division of the rhythmicity center that triggers inspiration
[image] |
|
|
Term
| Ventral respiratory group (VRG) |
|
Definition
division of the rhythmicity center that triggers expiration when a more forceful expiration is needed
[image] |
|
|
Term
| how the pons regulates breathing |
|
Definition
| Basic rhythm generated by the medullary rhythmicity center must be adjusted by pons. |
|
|
Term
| the pontine centers involved in regulation of breathing |
|
Definition
-Apneustic center
-Pneumotaxic center
[image] |
|
|
Term
|
Definition
Promotes long inspiration and sharp expiration (apneustic breathing).
[image] |
|
|
Term
|
Definition
-Needs to work together with apneustic center.
-Antagonizes the apneustic center’s effects.
-Inhibits inspiration, thus the normal rhythm.
[image] |
|
|
Term
| how the Apneustic center, Pneumotaxic center, Dorsal respiratory group (DRG), and Ventral respiratory group (VRG) interact with each other to regulate breathing |
|
Definition
|
|
Term
| general overview of how everything interacts with each other to regulate breathing |
|
Definition
|
|
Term
| some functions of the kidneys |
|
Definition
| -regulate volume and components of ECF (plasma and interstitial fluid) through filtering of blood plasma into urine
-Regulate BP through volume of blood plasma
-Regulate [waste products] in blood
-Regulate concentration of electrolytes (Na+, K+, H+, HCO3- & other ions)
-Regulate pH of body fluids
-Secrete erythropoietin
+Hypoxia → ↑ erythropoietin → ↑RBC production |
|
|
Term
| the primary function of the kidneys |
|
Definition
| regulate volume and components of ECF (plasma and interstitial fluid) through filtering of blood plasma into urine |
|
|
Term
| how kidneys are stimulated to secrete erythropoietin |
|
Definition
| Hypoxia → ↑ erythropoietin → ↑RBC production |
|
|
Term
| depiction of the kidneys in the context of the urinary system |
|
Definition
|
|
Term
| the structure of the kidney |
|
Definition
|
|
Term
| some structural components of the kidney |
|
Definition
-outer cortex
-inner medulla
-Collecting ducts of nephrons (ahead) |
|
|
Term
| outer cortex of the kidney |
|
Definition
-outer component
-contains many capillaries |
|
|
Term
| inner medulla of the kidneys |
|
Definition
-inner component of the kidneys
-has 7-18 renal pyramids separated by renal columns |
|
|
Term
| Collecting ducts of nephron |
|
Definition
| ahead of the kidneys, they empty into minor calyces which unite to form a major calyx |
|
|
Term
| path by which urine goes from kidneys to urination |
|
Definition
Path of urine = nephrons -> minor calyces -> major calyces -> renal pelvis -> ureters -> urinary bladder -> urethra -> exits
[image] |
|
|
Term
|
Definition
the functional unit of the kidney
[image] |
|
|
Term
| 3 muscles to focus on concerning the bladder |
|
Definition
-Detrusor – smooth muscle – bladder wall
-Internal urethral sphincter – smooth muscle
-External urethral sphincter – skeletal muscle
[image] |
|
|
Term
|
Definition
part of the pons involved in urination
-not doing anything during the filling phase |
|
|
Term
| depiction of the sympathetic process of filling the bladder |
|
Definition
|
|
Term
| some things that happen during the process of filling the bladder |
|
Definition
-Filling of bladder – sympathetic relaxation of detrusor and constriction of internal urethral sphincter.
-Somatic motor fibers stimulate external (lower) urethral sphincter (voluntary).
-Afferent fibers along pelvic nerve detect stretch -> stimulate sympathetic outflow from hypogastric nerve, and constant somatic firing from pudendal nerve.
[image] |
|
|
Term
| why the filling of the bladder is a sympathetic process |
|
Definition
| because a nerve is actively mediating the the detrusor muscle of the bladder wall and the internal and external sphincters are being constricted |
|
|
Term
| the neurotransmitter(s) involved in the sympathetic process of filling the bladder |
|
Definition
| norepinephrine for the involuntary and acetylcholine for the voluntary |
|
|
Term
| depiction of the parasympathetic process of emptying the bladder |
|
Definition
|
|
Term
| some things that happen during the parasympathetic process of emptying the bladder |
|
Definition
-As bladder fills, afferent firing along pelvic nerve ↑↑ -> [periaqueductal grey integrates signals from spinal cord and central regions] -> triggers micturition center in pons ->…
--> Full bladder – pons signals inhibition of sympathetic and activation of parasympathetic neurons → contraction of detrusor & relaxation of internal (upper) urethral sphincter.
-Somatic motor fibers control external (lower) urethral sphincter (voluntary) – relax.
[image] |
|
|
Term
| the neurotransmitter(s) involved in the parasympathetic process of emptying the bladder |
|
Definition
|
|
Term
| depiction of the blood vessels in the kidneys |
|
Definition
|
|
Term
| Renal plasma (blood) flow |
|
Definition
| Renal plasma (blood) flow = volume of plasma (blood) delivered to kidneys over time (mL/min). *RPF is 22% of cardiac output. |
|
|
Term
| the path blood takes through the vessels in the kidneys |
|
Definition
| Renal artery → interlobar artery → arcuate a. → interlobular a. → afferent arteriole → glomerulus (1st capillary) → efferent arteriole → peritubular capillaries (2nd capillary) with vasa recta surrounding loop of Henle → venous blood
[image] |
|
|
Term
| function of the glomerulus |
|
Definition
|
|
Term
| how many nephrons are in a kidney? |
|
Definition
|
|
Term
| the 2 main components of the nephron |
|
Definition
1. Vascular component
2. Tubular components
[image] |
|
|
Term
| vascular component of the nephron |
|
Definition
glomerulus – all of RPF passes through the glomeruli
[image] |
|
|
Term
| the tubular components of the nephron and the path taken |
|
Definition
Nephron tubule: glomerular (Bowman’s) capsule → proximal convoluted tubule (PCT) → loop of Henle (LOH) (descending limb -> thin ascending limb -> thick ascending limb) → distal convoluted tubule (DCT) → collecting duct (CD) cortical then medullary → empties into calyx
[image] |
|
|
Term
|
Definition
1. Cortical nephron
2. Juxtamedullary nephron
[image] |
|
|
Term
|
Definition
| originates in outer 2/3 of cortex
-about 85% of nephrons are cortical nephrons
*More involved in solute reabsorption and waste secretion.
[image] |
|
|
Term
|
Definition
| originates in inner 1/3 cortex
*Important for producing concentrated urine.
-Has longer LOH & well-developed vasa recta.
[image] |
|
|
Term
|
Definition
| Renal plasma (blood) flow |
|
|
Term
|
Definition
| Glomerular filtration rate |
|
|
Term
| depiction of the structure of the glomerular structure |
|
Definition
|
|
Term
| some components of the glomerular structure |
|
Definition
-Glomerulus
-Glomerular (Bowman’s) capsule
[image]
[image] |
|
|
Term
|
Definition
tangle of capillaries within the glomerular structure
-Recall glomerulus is tuft of blood vessels
+Afferent arteriole in
+Efferent arteriole out
-Glomerular capsule + glomerulus = renal corpuscle
[image] |
|
|
Term
|
Definition
Glomerular capsule + glomerulus = renal corpuscle
[image] |
|
|
Term
|
Definition
| fluid that enters glomerular space -> proximal convoluted tubule |
|
|
Term
| Glomerular (Bowman’s) capsule |
|
Definition
Surrounds glomerulus – 2 layers
-Inner layer (podocytes) lines blood vessels
-Outer layer – rounded and encompasses entire glomerulus
-Glomerular (Bowman’s) space in-between
[image] |
|
|
Term
| An ultrafiltrate in glomerulus must pass through, in order |
|
Definition
`(1) Fenestrated capillary – large pores in the endothelium.
(2) Basement membrane
(3) Slits in the processes of podocytes, which comprise the inner layer of the glomerular capsule.
-Slit diaphragms span the slits.
[image] |
|
|
Term
| the part of the glomerular structure the ultrafiltrate passes through |
|
Definition
|
|
Term
|
Definition
| having perforations, apertures, or transparent areas |
|
|
Term
| how fenestrated capillaries help form filtrate |
|
Definition
| -100-400 times more permeable to plasma H2O, and solutes (electrolytes, glucose, etc.).
-Small enough to prevent RBCs, platelets, WBCs, and large proteins from passing through pores. |
|
|
Term
| Plasma proteins are mostly excluded from the filtrate due to... |
|
Definition
large size and negative charge.
-The basement membranes and slit diaphragms of podocytes are lined with negative charges which repel negatively-charged proteins. |
|
|
Term
| why glomerular filtrate has low protein concentration |
|
Definition
*Filtered proteins reabsorbed by renal epithelial cells -> no proteins in urine.
[image] |
|
|
Term
| What are two general causes of proteinuria? |
|
Definition
1: proteins get through the glomerulus
2: proximal tubular cells not reabsorbing the protein
[image] |
|
|
Term
| glomerular filtration formed under... |
|
Definition
(1) hydrostatic P of blood (major, due to BP) [and colloid osmotic P of glomerular filtrate (very minor)]
[image] |
|
|
Term
| glomerular filtration countered by... |
|
Definition
(2) Hydrostatic P of glomerular filtrate
(3) Colloid osmotic P of plasma
[image] |
|
|
Term
| Net filtration pressure of glomerular filtration |
|
Definition
|
|
Term
| Glomerular filtration rate (GFR) |
|
Definition
-Volume of filtrate produced by both kidneys each minute; this is the rate at which urine forms
-~115 mL/min in women, 125 mL/min in men -> 7.5 L/hour -> 180 L/day
-Correlates with renal function. |
|
|
Term
| the stages of chronic kidney disease and their associated glomerular filtration rates (GFRs) |
|
Definition
|
|
Term
|
Definition
*Volume of urine is ~ 1-2 L/day (1%) --> 99% of filtrate is reabsorbed.
[image] |
|
|
Term
| why we pee out only 1-2 L of the 180 L produced by glomerular filtration rate (GFR) |
|
Definition
because volume of urine is ~ 1-2 L/day (1%) --> 99% of filtrate is reabsorbed
[image] |
|
|
Term
|
Definition
minimal urine volume required to excrete metabolic waste (400 - 600 mL)
[image] |
|
|
Term
| Filtration (in the context of the nephron) |
|
Definition
from the glomerulus to form the filtrate.
[image] |
|
|
Term
| Reabsorption (in the context of the nephron) |
|
Definition
brings water and solutes out of the filtrate back into the plasma along the rest of the nephron.
[image] |
|
|
Term
| Secretion (in the context of the nephron) |
|
Definition
secreting solutes into the filtrate for excretion or elimination.
[image] |
|
|
Term
| Quantity of a solute excreted |
|
Definition
Quantity of a solute excreted = (quantity filtered + quantity secreted) - quantity reabsorbed
[image] |
|
|
Term
|
Definition
Quantity of a solute excreted per min (mg/min)
Renal Excretion Rate = V (rate of urine formation, mL/min) x U (concentration of solute x in urine, mg/mL)
[image] |
|
|
Term
| Renal excretion or elimination rate |
|
Definition
Amount of substance removed per unit time = mg/min.
[image]
-Recall renal plasma flow (A) = mL/min.
-Recall GFR (B) = mL/min. |
|
|
Term
| Renal plasma clearance rate |
|
Definition
-Ability of kidneys to remove a specific solute (x) from plasma and excrete those molecules in the urine.
-*The volume of plasma from which a solute is completely removed by kidney per unit time = mL/min.
[image]
-Recall renal plasma flow (A) = mL/min.
-Recall GFR (B) = mL/min. |
|
|
Term
| how and why inulin is used to measure glomerular filtration rate (GFR) |
|
Definition
-If a substance is neither reabsorbed nor secreted, then the amount excreted = amount filtered
-Renal excretion of inulin – filtered but neither reabsorbed nor secreted.
-Have to administer inulin and then collect urine and blood samples.
-Its clearance rate is equal to GFR. Example, 120 mL/min.
[image] |
|
|
Term
|
Definition
| a metabolite of muscle creatine formed at a constant rate |
|
|
Term
| how and why creatinine is used to measure glomerular filtration rate (GFR) |
|
Definition
-Creatinine – a metabolite of muscle creatine formed at a constant rate.
-The creatinine excretion is the function of muscle mass, less affected by diet, age, and sex.
-Measure of the plasma creatinine is a good indicator of GFR.
-Creatinine freely filters through the glomeruli and is only slightly secreted by PCT clearance close to GFR, a little above that of inulin (~127 mL/min).
-Just measuring plasma creatinine gives a rough idea of renal function (GFR).
+(There are other non-renal reasons such as dehydration and urinary obstruction which will also affect plasma creatine.)
[image] |
|
|
Term
| How does determining creatinine clearance differ from determining inulin clearance? |
|
Definition
| you make your own creatinine; you don't have to introduce creatinine |
|
|
Term
| What happens to plasma creatinine if glomerular filtration rate (GFR) decreases? |
|
Definition
|
|
Term
| What happens to urine creatinine if glomerular filtration rate (GFR) decreases? |
|
Definition
|
|
Term
| depiction of the entire pathway of renal absorption |
|
Definition
|
|
Term
| the 2 routes by which renal reabsorption can occur |
|
Definition
-transcellular
-paracellular |
|
|
Term
| transcellular route of renal reabsorption |
|
Definition
through tubular cells
Filtrate -> Apical membrane tubular cell -> Basal membrane tubular cell -> Interstitial fluid -> Capillary
[image] |
|
|
Term
| paracellular route of renal reabsorption |
|
Definition
between tubular cells
Filtrate -> interstitial fluid -> capillary
[image] |
|
|
Term
| Which fluid compartment does transcelluar route involve that paracellular does not? |
|
Definition
the intracellular route
[image] |
|
|
Term
|
Definition
| proximal convoluted tubule |
|
|
Term
|
Definition
|
|
Term
| solute concentration in different parts of the PCT and LOH |
|
Definition
|
|
Term
| some hormones that regulate salt and water transport in the distal nephron |
|
Definition
-Vasopressin (ADH)
-Aldosterone |
|
|
Term
| constituative reabsorption |
|
Definition
reabsorption that does not change and is not hormonally regulated
-Approximately 65% of the filtered salt & water is reabsorbed across PCT, 20% is reabsorbed across loop of Henle (LOH).
-Salt transport in the above regions (PCT & LOH) are NOT under hormonal regulation. |
|
|
Term
| the parts of the nephron where the kidneys can tweak the amount of salt and water that get reabsorbed |
|
Definition
the distal convoluted tubule (DCT) and the collecting duct (CD)
-Only 15% of the initial filtrate gets there. This 15% is reabsorbed variably, depending on level of hydration and the concentration of electrolytes in the body. |
|
|
Term
| the remaining 15% of initial filtrate that gets to the DCT and CD is reabsorbed variably, depending on... |
|
Definition
| level of hydration and the concentration of electrolytes in the body. |
|
|
Term
| how Na+ is transported across the apical membrane in the PCT |
|
Definition
| by facilitated diffusion (2° active transport) using Na+-glucose cotransporter, no energy spent
[image] |
|
|
Term
| how Na+ is transported across the basolateral membrane in the PCT |
|
Definition
| by (1°) active transport using Na+-K+ pump, energy required
[image] |
|
|
Term
| how Na+ gets into systemic capillaries |
|
Definition
Diffuses across interstitial space into systemic capillaries.
[image] |
|
|
Term
| energy requirements of reabsorption in the PCT |
|
Definition
| uses 6% of total energy expenditure of the body to reabsorb 65% of the filtrate |
|
|
Term
| what Cl- does in the reabsorption process in the PCT |
|
Definition
| -follows Na+ (electrical attraction)
–paracellular
[image] |
|
|
Term
| what water does in the reabsorption process in the PCT |
|
Definition
| *Water (~115 L/day) follows the osmotic pressure of salt out of PCT into interstitium then to blood (peritubular capillaries) -> no change in osmolarity.
-PCT highly permeable to H2O
-Aquaporin channels
[image] |
|
|
Term
| water usually follows the Na+ ions, except in... |
|
Definition
|
|
Term
| the mOsm right after the reabsorption in the PCT |
|
Definition
| total [solute] remains at 300 mOsm (isotonic) |
|
|
Term
| Glucose and amino acids in blood are easily filtered by... |
|
Definition
|
|
Term
| Normally all of the filtered glucose and amino acids are reabsorbed by... |
|
Definition
facilitated diffusion (2° secondary active transport) in the PCT.
-Carrier-mediated transport displays saturation. |
|
|
Term
| Renal transport threshold |
|
Definition
| minimal plasma [substance] that results in excretion of that substance in the urine |
|
|
Term
| Renal plasma threshold for glucose |
|
Definition
|
|
Term
|
Definition
| occurs when the transport carriers for glucose become saturated due to hyperglycemia |
|
|
Term
| Diabetes mellitus (DM) – When hyperglycemia results in glycosuria, a large volume of urine will be formed. Why? |
|
Definition
| because glucose in the urine is osmotically active, holding lots of water in the filtrate that becomes urine |
|
|
Term
| an instrument that can be used to detect glycosuria |
|
Definition
|
|
Term
| Primarily ______ nephrons responsible for water and salt reabsorption in the loop of Henle. |
|
Definition
|
|
Term
| depiction of the loop of Henle |
|
Definition
|
|
Term
| Concentration gradient in renal medulla in and around the loop of Henle. |
|
Definition
| -In order for H2O to be reabsorbed, medullary interstitial fluid must be hypertonic relative to tubular fluid.
-Osmotic pressure of interstitial fluid can reach 1,200-1,400 mOsm.
-Osmotic pressure of tubular fluid in descending LOH always lags a little behind until the bottom of the LOH deep in the medulla.
+Starts at 300 mOsm entering LOH and reaches ~1200 mOsm at bottom.
[image] |
|
|
Term
| the requirement for H2O to be reabsorbed in the context of the loop of Henle |
|
Definition
| In order for H2O to be reabsorbed, medullary interstitial fluid must be hypertonic relative to tubular fluid.
[image] |
|
|
Term
| some membranes at the thick ascending limb of the loop of Henle |
|
Definition
-apical membrane
-basolateral membrane
[image] |
|
|
Term
| what happens at the apical membrane of the loop of Henle? |
|
Definition
| Na+ diffuses from the filtrate into the cells, accompanied by the facilitated transport of K+ and Cl- (ratio 1 Na+ : 1 K+ : 2 Cl-)
[image] |
|
|
Term
| what happens at the basolateral membrane of the loop of Henle? |
|
Definition
| Na+ actively transported to interstitium by Na+/K+ pump, Cl- follows Na+ passively
[image] |
|
|
Term
| the part of the loop of Henle that's impermeable to water |
|
Definition
the ascending limb
[image] |
|
|
Term
| what happens as a result of the Na+ being removed from the ascending limb of the loop of Henle? |
|
Definition
| As Na+ removed from ascending LOH, H2O remains -> tubular fluid (filtrate) becomes increasingly dilute (hypotonic) while the interstitial fluid in the medulla becomes relatively hypertonic.
[image] |
|
|
Term
| Filtrate going out of ascending limb LOH to DCT is hypertonic or hypotonic? |
|
Definition
hypotonic
Went from 1200 at the bottom to 100 mOsm.
[image] |
|
|
Term
| the part of the loop of Henle that's permeable to water, but not to salts; doesn't even do active transport of salts |
|
Definition
the descending limb of the loop of Henle
[image] |
|
|
Term
| the direction the water moves in the context of the descending limb of the loop of Henle |
|
Definition
| -surrounding hypertonic interstitial fluid draws H2O out of descending limb into capillaries.
-As osmolarity of surrounding fluid ↑ -> more H2O exits -> fluid volume ↓ in tubule -> higher [Na+] and osmolarity of tubular fluid -> enters ascending limb.
[image] |
|
|
Term
| depiction of the countercurrent multiplier system involving the loop of Henle |
|
Definition
|
|
Term
| importance of countercurrent flow in the loop of Henle |
|
Definition
Countercurrent flow in opposite directions in ascending and descending limbs LOH and close proximity of loop’s limbs allow interactions.
[image] |
|
|
Term
| how the positive feedback (multiplier system) works in the loop of Henle |
|
Definition
The more salt the ascending limb extrudes -> the more concentrated the interstitial fluid -> the more water diffuses out of descending limb -> gradual increasing concentration of renal interstitial fluid, followed by LOH tubular fluid, from the cortex to inner medulla.
[image] |
|
|
Term
| osmolarity gradient in the interstitium around the loop of Henle |
|
Definition
Osmolarity ↑ as go from cortex to deep medulla
[image] |
|
|
Term
| the NaCl, H2O, and osmolarity in the thin descending limb |
|
Definition
| -Amount of NaCl remains the same.
-Amount of H2O ↓
-Osmolarity ↑
[image] |
|
|
Term
| the NaCl, H2O, and osmolarity in the thick ascending limb |
|
Definition
-Amount of H2O remains the same.
-Amount of NaCl ↓
-Osmolarity ↓
[image] |
|
|
Term
| the result of the medullary hypertonicity created by the countercurrent multiplier system |
|
Definition
| H2O and NaCl conservation |
|
|
Term
|
Definition
Net of capillaries around LOH
[image] |
|
|
Term
| properties of the vasa recta that enable it to do countercurrent exchange |
|
Definition
| -Walls are permeable to H2O, NaCl, & urea – passive transport.
-Slow, low pressure blood flow in medulla = low hydrostatic P.
-Colloid osmotic P inside vasa recta >>> surrounding interstitium.
-As descend into hypertonic medulla
+H2O exits the capillaries
+NaCl enters the capillaries
-As ascend to decreasing tonicity of cortex
+H2O enters the capillaries
+NaCl exits the capillaries
[image] |
|
|
Term
| The countercurrent exchange of vasa recta |
|
Definition
| -Hypertonic salts in interstitial fluid diffuse into blood of the descending capillary loop then passively diffuse out of the ascending capillary loop.
+No net movement of salts.
+*Hypertonicity of renal medullary interstitium maintained.
-H2O moves out of descending limbs, but enters ascending limbs to a greater extent.
+*Water returned to systemic circulation.
[image] |
|
|
Term
| the ultimate result of the entire countercurrent mechanism |
|
Definition
| -Ultimately, H2O and NaCl are reclaimed from filtrate.
-Enough of each remains in plasma of vasa recta to maintain homeostatic levels.
[image] |
|
|
Term
| the flow of water and NaCl in the vasa recta |
|
Definition
| -H2O leaves descending vasa recta
-H2O enters ascending vasa recta
-NaCl enters descending vasa recta
-NaCl leaves ascending vasa recta
[image][image] |
|
|
Term
| the flow of water and NaCl in the loop of Henle |
|
Definition
| -H2O leaves descending LOH
-NaCl leaves ascending LOH
[image][image] |
|
|
Term
| the role of the countercurrent multiplier in the entire countercurrent mechanism |
|
Definition
Countercurrent multiplier creates medullary hypertonicity.
[image] |
|
|
Term
| the role of the countercurrent exchange in the entire countercurrent mechanism |
|
Definition
Countercurrent exchange maintains medullary hypertonicity (salt remains in medulla) and conserves water in the body (water returns to circulation).
[image] |
|
|
Term
|
Definition
| Nitrogenous end product of protein metabolism -> renal elimination important |
|
|
Term
|
Definition
|
|
Term
| Some urea is recycled. What is its function? |
|
Definition
| contributes to total osmolarity of medullary interstitial fluid; helps maintain hypertonicity of interstitial fluid |
|
|
Term
|
Definition
| facilitated diffusion by urea transporters |
|
|
Term
| path of urea from medullary CD to ascending limb of loop of Henle |
|
Definition
| Urea diffuses out of medullary CD -> interstitial fluid -> into ascending limb LOH |
|
|
Term
| DCT and cortical CD [permeable or impermeable] to urea. |
|
Definition
|
|
Term
| the amounts of Na+ and K+ that get reabsorbed before going into the distal convoluted tubule and make it to the distal convoluted tubule, respectively |
|
Definition
| Approximately 85% of filtered Na+ & K+ is reabsorbed before the filtrate reaches the distal convoluted tubule (DCT), i.e. remaining 15% filtrate goes to DCT.
[image] |
|
|
Term
| among the filtrate that makes it to the distal convoluted tubule, what happens to the Na+ in the absence of aldosterone? |
|
Definition
| 80% of the Na+ is reabsorbed in the distal convoluted tubule
[image] |
|
|
Term
| how aldosterone regulates salt reabsorption |
|
Definition
it regulates remaining 20% (2-3% of the total filtrate, or ~30 g of Na+/day) of the 15% of filtrate that makes it to the distal convoluted tubule, thus affecting 2-3% of salt re-absorption.
-Aldosterone targets DCT (minor) and collecting ducts (major).
[image] |
|
|
Term
|
Definition
-DCT (minor)
-collecting ducts (major)
[image] |
|
|
Term
| depiction of how Na+ and K+ are handled in the renal tubules |
|
Definition
|
|
Term
| the effect of aldosterone |
|
Definition
| Aldosterone acts on late DCT (minor) and cortical CD (major) to reabsorb Na+ and secrete K+, thus promoting further Na+ retention and K+ loss from blood.
[image] |
|
|
Term
| how Na+ and K+ move at the apical membrane of the DCT/CD |
|
Definition
they follow their diffusion gradients; this leads to saving sodium and peeing potassium
[image] |
|
|
Term
| how Na+ and K+ move at the basal membrane of the DCT/CD |
|
Definition
| active transport (Na+ / K+ pump)
[image] |
|
|
Term
| how aldosterone causes Na+ retention and K+ loss |
|
Definition
| by going into the collecting tubule cells, binding to the intracellular receptor, and causing increased expression of the Na+ channels and the Na+ / K+ ATPases
[image] |
|
|
Term
| the cause and effect of aldosterone secretion |
|
Definition
| -*Stimulated directly by a rise in blood K+ and indirectly by a fall in blood Na+.
-Aldosterone stimulates K+ (and H+) secretion in exchange for Na+ reabsorption.
-*Aldosterone-induced Na+ reabsorption allows fine-tuning of plasma [Na+].
-*Aldosterone-induced K+ secretion is the main means by which K+ can be eliminated in the urine.
+There is aldosterone-independent K+ secretion into the filtrate (minor).
[image] |
|
|
Term
| some characteristics of the medullary CD |
|
Definition
| -important in water reabsorption/conservation due to hypertonic interstitial fluid.
-The medullary CD is permeable to water but impermeable to salts --> the high [NaCl] in the medullary interstitial fluid cannot enter the medullary CD.
[image] |
|
|
Term
| how Antidiuretic hormone (ADH, vasopressin) stimulates H2O reabsorption |
|
Definition
| Antidiuretic hormone (ADH, vasopressin) from the posterior pituitary stimulates incorporation of aquaporins into apical epithelial cell membranes of medullary CD --> ↑ H2O re-absorption from tubules along concentration gradient.
[image] |
|
|
Term
| What effect does aldosterone have on blood volume? |
|
Definition
|
|
Term
| What effect does ADH have on blood volume? |
|
Definition
|
|
Term
| 2 hormones that are involved in water conservation |
|
Definition
|
|
Term
| What happens when excess water needs to be excreted? ADH secretion? |
|
Definition
we don't have release of that because we want the water to stay in the collecting ducts
[image] |
|
|
Term
| What happens when excess water needs to be excreted? Osmolarity of filtrate in collecting duct? |
|
Definition
gets fairly dilute
[image] |
|
|
Term
| What happens when excess water needs to be excreted? Blood volume? |
|
Definition
|
|
Term
| What happens when water needs to be conserved? ADH secretion? |
|
Definition
|
|
Term
| What happens when water needs to be conserved? Osmolarity of filtrate in collecting duct? |
|
Definition
|
|
Term
| What happens when water needs to be conserved? Blood volume? |
|
Definition
|
|
Term
|
Definition
a disease associated with inadequate secretion of ADH or defects in renal ADH receptors.
[image] |
|
|
Term
| result of Diabetes insipidus (DI) |
|
Definition
Medullary CD become less permeable to water --> ↓ water re-absorption into the plasma --> high volume and very dilute urine.
[image] |
|
|
Term
| general diagram of the pathophysiology of ADH |
|
Definition
|
|
Term
| What are the derivations of the names of diabetes mellitus and diabetes insipidus? |
|
Definition
-diabetes basically means siphoning off water (it was understood that this condition caused excess urination)
-mellitus means sweet (physicians would taste the urine, sweet in this case)
-insipidus means not having a strong taste (physicians would taste the urine; nearly tasteless in this case) |
|
|
Term
| some ions the kidneys regulate |
|
Definition
| -Na+
-K+
-H+
-Cl-
-HCO3-
-PO4-3
[image] |
|
|
Term
| effect of the kidneys regulating Na+ |
|
Definition
| Regulation of plasma [Na+] --> volume of blood plasma --> regulation of BP. |
|
|
Term
| effect of the kidneys regulating K+ |
|
Definition
| Control of plasma of [K+] for proper function of cardiac & skeletal muscles. |
|
|
Term
| the goal of the kidneys regulating ions |
|
Definition
| to match ingestion with urinary excretion |
|
|
Term
| Role of juxtaglomerular (JG) apparatus |
|
Definition
| Involved in renin -> -> aldosterone secretion |
|
|
Term
| Atrial natriuretic peptide (ANP) |
|
Definition
| acts as an endogenous diuretic by stimulating excretion of Na+, Cl- and H2O; opposite to aldosterone.
-Inhibits effects of aldosterone and ADH. |
|
|
Term
| What does natriuretic mean? |
|
Definition
|
|
Term
| Juxtaglomerular Apparatus |
|
Definition
| Region in each nephron where the afferent arteriole contacts the thick ascending limb LOH (about to enter DCT)
[image] |
|
|
Term
| types of cells in the juxtaglomerular apparatus |
|
Definition
-granular cells
-macula densa cells
-mesangial cells
[image] |
|
|
Term
|
Definition
| detect [Na+] and flow
-part of juxtaglomerular apparatus
[image] |
|
|
Term
|
Definition
secrete renin
-part of juxtaglomerular apparatus
[image] |
|
|
Term
|
Definition
| type of smooth muscle cells in the juxtaglomerular apparatus |
|
|
Term
| overall function of juxtaglomerular apparatus |
|
Definition
Renal autoregulation
[image] |
|
|
Term
|
Definition
(intrinsic mechanisms) maintains steady renal blood flow and GFR
[image] |
|
|
Term
| the overall local effects of macula densa cell signaling |
|
Definition
-When ↓ systemic arterial P --> chemicals released locally (NO, PGs) --> the afferent arterioles dilate --> maintains GFR in a constant range.
-Tubuloglomerular feedback – macula densa in ascending limb senses an increased flow of filtrate --> secretes ATP as a signal to afferent arterioles to constrict.
[image] |
|
|
Term
| why is renal autoregulation of renal blood flow and GFR important? |
|
Definition
| if you had constantly widely fluctuating GFR and blood flow, that would really disrupt the cincentration gradient in the medulla and impair your ability to reabsorb sodium, reabsorb water, lose potassium, things like that |
|
|
Term
| Tubuloglomerular feedback |
|
Definition
macula densa in ascending limb senses an increased flow of filtrate --> secretes ATP as a signal to afferent arterioles to constrict. This lowers it back to the homeostatic level of filtrate being formed.
[image] |
|
|
Term
| Granular cells (juxtaglomerular cells) |
|
Definition
-Modified smooth muscle cells in the wall of afferent arterioles.
-Receive local (paracrine) signals from macula densa.
-Secrete renin causing systemic effects:
1) ↓ systemic arterial P --> --> ↑ renin secretion.
2) ↑ systemic arterial P --> --> ↓ renin secretion.
[image] |
|
|
Term
| how Granular cells (juxtaglomerular cells) regulate blood pressure |
|
Definition
The renin-angiotensin-aldosterone (RAA) system – (“negative” feedback response)
-↓ in BP → detected by granular cells → ↑ renin secretion → renin converts angiotensinogen (produced by the liver → angiotensin (AT) I
-Angiotensin-converting enzyme (ACE) converts AT I → AT II (bioactive)
-*AT II effects:
(1) → vasoconstriction → ↑ BP
(2) → ↑ aldosterone secretion (a steroid H from adrenal cortex) → ↑ in renal Na+ re-absorption → ↑ in water re-absorption → ↑ blood vol → ↑ BP
[image] |
|
|
Term
| the pathway showing how the renin secreted by granular cells regulates blood pressure |
|
Definition
|
|
Term
| how sympathetic innervation helps to regulate GFR |
|
Definition
-Sympathetic innervation -> constriction of the afferent arterioles -> reduces GFR -> thus preserves blood volume to muscles and heart.
-Only with severe sympathetic input, e.g., shock, hemorrhage.
[image] |
|
|
Term
|
Definition
| Glomerular filtration rate (mL/min) |
|
|
Term
| Summary of Local and Systemic Effects of Juxtaglomerular Apparatus and Renal Autoregulation |
|
Definition
|
|
Term
| overview of how the renal-angiotensin-aldosterone system (RAAS) increases blood volume and pressure |
|
Definition
|
|
Term
| depiction of how CO2, acids, buffers, and blood cells interact with each other |
|
Definition
|
|
Term
| Blood pH is maintained within narrow pH range (7.40) by... |
|
Definition
|
|
Term
|
Definition
|
|
Term
| Kidneys help regulate blood pH by... |
|
Definition
| excreting H+ and/or reabsorbing HCO3-
[image]
-CA: catalyzed by carbonic anhydrase.
-Henderson-Hasselbalch equation
-pH = 6.1 + log ( [HCO3-] / [CO2] )
-[CO2] is adjusted by lungs, [HCO3-] by kidneys |
|
|
Term
|
Definition
| -When blood pH < 7.35
-↑ H+ ions |
|
|
Term
|
Definition
| -When blood pH > 7.45
-↓ H+ ions |
|
|
Term
| the most important buffer in blood and what it does |
|
Definition
| -HCO3-
-Excess H+ is buffered by HCO3- |
|
|
Term
| the role of the proximal convoluted tubule in the handling of HCO3- and H+ |
|
Definition
| -Main site of HCO3-- reabsorption.
-Na+/H+ antiporter – another source of Na+ reabsorption.
-Role of carbonic anhydrase – HCO3- can not cross membranes.
-H+ keeps cycling – small amounts of extra H+ secreted for excretion.
[image] |
|
|
Term
| how bicarbonate (HCO3-) goes through the membrane of the proximal tubule |
|
Definition
| by way of a Na+ / HCO3- cotransporter along Na+'s concentration gradient |
|
|
Term
| the role of the distal convoluted tubule / collecting ducts in the handling of HCO3- and H+ |
|
Definition
| -Active transport of H+ across apical membrane -> filtrate.
+H+ ATPase uniporter
+H+/K+ ATPase antiporter
-Combines with phosphate and ammonia buffers in filtrate -> excreted.
-Other mechanisms exist to ↑ HCO3- entering plasma and ↓ H+ entering filtrate.
[image] |
|
|
Term
| depiction of the relationship between Na+, K+, and H+ |
|
Definition
|
|
Term
|
Definition
|
|
Term
| how Na+ reabsorption in DCT and CD influences K+ |
|
Definition
| Na+ re-absorption in DCT and CD creates electrical gradient for K+ secretion (see aldosterone).
[image] |
|
|
Term
| how plasma [K+] indirectly affects [H+] |
|
Definition
| -↓ in ECF [K+] (hypokalemia) --> ↑ H+ secretion in distal tubule & cortical CD --> metabolic alkalosis.
-Hyperkalemia --> metabolic acidosis.
-Severe acidosis --> H+ is secreted at the expense of K+ --> ↑ ECF [K+] --> hyperkalemia.
[image] |
|
|
Term
| the ions that get secreted into the filtrate and when |
|
Definition
| Often H+ or K+ is being secreted into filtrate at the expense of the other in acute situations.
[image] |
|
|
Term
| the ions that get moved into the plasma and cells and when |
|
Definition
| Similar situation occurs in plasma with movement of excess H+ or K+ into cells while the other moves into plasma.
[image] |
|
|
Term
| what hyperkalemia leads to |
|
Definition
|
|
Term
| why urine tends to be slightly acidic (pH 5-7) |
|
Definition
| because kidneys reabsorb almost all HCO3- and excrete H+ |
|
|
Term
| Nephron cannot produce urine with pH < 4.5 because... |
|
Definition
|
|
Term
| H+ are prevented from contributing to the acidity of the urine by... |
|
Definition
| being combined with HPO4-2 or NH3.
-*Buffering reactions
+HPO4 + H+ --> H2PO4-
+NH3 + H+ --> NH4+ (ammonium ion) |
|
|
Term
| some buffering reactions that occur in the nephron to affect the pH of the urine |
|
Definition
| HPO4 + H+ --> H2PO4-
NH3 + H+ --> NH4+ (ammonium ion) |
|
|
Term
| how hypoventilation leads to respiratory acidosis |
|
Definition
| Hypoventilation --> accumulation of CO2 in the tissues --> ↑ PCO2 --> [HCO3-] / [CO2] --> ↓ pH |
|
|
Term
| the compensatory response for respiratory acidosis caused by hypoventilation |
|
Definition
| ↑ renal secretion of H+ (as NH4+ and monophosphate) and ↑ re-absorption of HCO3- --> ↑ [HCO3-] / [CO2] --> ↑ pH --> blood pH close to normal |
|
|
Term
| how hyperventilation leads to respiratory alkalosis |
|
Definition
| Hyperventilation --> too little CO2 --> [HCO3-] / [CO2] --> ↑ pH |
|
|
Term
| the compensatory response for respiratory alkalosis caused by hyperventilation |
|
Definition
| ↓ re-absorption of HCO3- --> ↓ [HCO3-] / [CO2] --> ↓ pH ↓ blood pH close to normal |
|
|
Term
| the equation that regulation of blood pH boils down to |
|
Definition
| CO2 + H2O <--> H2CO3 <--> H+ + HCO3- |
|
|
Term
|
Definition
| excess of nonvolatile acids |
|
|
Term
| some things that can cause metabolic acidosis |
|
Definition
| -↑ acid intake or production
-↓ renal excretion of H+
-Ketoacidosis in diabetes
-lactic acidosis
-loss of HCO3- (for buffering) in diarrhea
-renal tubular disorders or renal failure
-toxicants |
|
|
Term
| the pathway that leads to metabolic acidosis |
|
Definition
| ↑ acid intake, production, or ↓ renal excretion of H+ --> ↓ ratio of [HCO3-] / [CO2] --> ↓ pH --> metabolic acidosis |
|
|
Term
| Compensatory response for metabolic acidosis |
|
Definition
| hyperventilation by lungs --> ↓ CO2 --> ↑ ratio of [HCO3-] / [CO2] |
|
|
Term
|
Definition
| too much HCO3- or too little nonvolatile acids (e.g. from vomiting stomach acid) |
|
|
Term
| the cause and effect leading to metabolic acidosis |
|
Definition
| ↑ HCO3- or acid loss --> ↑ ratio of [HCO3-] / [CO2] --> ↑ pH --> metabolic alkalosis |
|
|
Term
| compensatory response for metabolic alkalosis |
|
Definition
| hypoventilation by lungs --> ↑ CO2 --> ↓ ratio of [HCO3-] / [CO2] |
|
|
Term
| depiction of the pulmonary and renal responses to acidosis |
|
Definition
|
|
Term
| depiction of the pulmonary and renal responses to alkalosis |
|
Definition
|
|
Term
| why we need body defense (immune system) |
|
Definition
Defense mechanism
-Protect against disease-causing agents (pathogens)
-Make up the immune system |
|
|
Term
|
Definition
|
|
Term
|
Definition
inherited; nonspecific
-Serves as a first line of defense |
|
|
Term
|
Definition
specific
-A function of lymphocytes & changes with exposure |
|
|
Term
| some types of external defenses in innate defense |
|
Definition
-skin
-saliva
-tears
-mucus
-"good" gut bacteris to outcompete the bad
-stomach acid
-epithelial barriers |
|
|
Term
| some epithelial barriers that function in innate defense |
|
Definition
-Digestive tract (gastric acid, enzymes)
-Respiratory tract (mucus, cilia, enzymes)
-Genitourinary tract (acidity, pH ~4) |
|
|
Term
| some types of internal defense mechanisms |
|
Definition
-fever
-interferons
-phagocytes |
|
|
Term
| why the integrity of the skin is important for defense |
|
Definition
| because if there's a cut, bacteria can infect and inflammation can result |
|
|
Term
| how stomach acid functions in external defense |
|
Definition
|
|
Term
| how mucus, cilia, and enzymes in the respiratory tract function in external defense |
|
Definition
-mucus entraps unwanted particle
-cilia move it upward
-enzymes digest it |
|
|
Term
| how the acidity of the genitourinary tract (pH ~4) |
|
Definition
| reduces growth of bacteria |
|
|
Term
|
Definition
molecules that elicit adaptive immunity specifically bind to Ag; they mediate specific immunity
-Usually large molecules that are foreign to the body
-this is how the immune system distinguishes self from non-self |
|
|
Term
|
Definition
| mediated by antigens (Ag) |
|
|
Term
| types of specific immunity |
|
Definition
-Humoral immunity
-Cell-mediated immunity |
|
|
Term
|
Definition
uses antibodies (Ab) produced by B cells
[image] |
|
|
Term
|
Definition
uses T cells to destroy host cells infected by pathogens
[image] |
|
|
Term
| innate immunity triggered by... |
|
Definition
| pathogen-associated molecular patterns (PAMPs) |
|
|
Term
| the difference between Gram-negative and Gram-positive bacteria |
|
Definition
| whether or not there's an envelope outside the cell wall |
|
|
Term
| immune cells recognize PAMPs by... |
|
Definition
| Toll-like receptors (TLR’) |
|
|
Term
| the surface molecule on Gram-negative bacteria |
|
Definition
| Lipopolysaccharide (LPS) from Gram “–” bacteria cell membrane |
|
|
Term
| the surface molecule on Gram-positive bacteria |
|
Definition
| Peptidoglycan from Gram “+” bacteria cell wall |
|
|
Term
| the result of PAMPs binding to TLR' to form the PAMPs-TLR’ complex |
|
Definition
| PAMPs-TLR’ complex → ↑ cytokines secretion from immune cells → activate more immune cells for further body defense → inflammation most likely to occur |
|
|
Term
|
Definition
| it's to stimulate cells to work on something. We call that cytokine. The cytokines secreted by immune cells will activate other immune cells to be more active for a general body defense, and include an induction of inflammation |
|
|
Term
| difference between Gram-positive and Gram-negative based on Gram-staining |
|
Definition
Gram staining
-Detect the presence of peptidoglycan (Gram “+”) on cell wall of bacteria
-Gram “+” bac – stained as purple/blue due to retaining crystal violet dye
-Gram “–” bac – stained as pink/red due to the existence of an outer membrane
+More resistant against antibodies, because of their impenetrable wall |
|
|
Term
|
Definition
a part of the healing process when tissues are injured by pathogens, trauma etc.
-Inflammation initiates nonspecific phagocytosis by blood phagocytes (WBCs)
-Characteristics of inflammation
+Redness, swelling and pus, warmth, pain |
|
|
Term
| inflammation is initially caused by... |
|
Definition
| induction by PAMPs binding to TL receptor, and then initiate the inflammation |
|
|
Term
| what causes the redness, swelling, and warmth in inflammation? |
|
Definition
|
|
Term
| Inflammation initiates... |
|
Definition
| nonspecific phagocytosis by blood phagocytes (WBCs) |
|
|
Term
| Characteristics of inflammation |
|
Definition
-Redness
-swelling
-pus (not always; depending on the nature of the bacterial infection)
-warmth
-pain |
|
|
Term
| how inflammation is initiated |
|
Definition
Injured (infected) tissues release cytokines
→ Activate mast cells near the damaged area
→ Mast cells secrete cytokines (histamine, TNF-α, prostaglandins & leukotrienes) → dilation of blood vessels → ↑ membrane permeability → allows white blood cells to leave the blood vessel
[image] |
|
|
Term
|
Definition
| tumor necrosis factor alpha |
|
|
Term
| Effects of Cytokines from Mast Cells |
|
Definition
|
|
Term
| vasodilation in the inflammatory pathway leads to... |
|
Definition
diapedesis (extravasation)
[image][image] |
|
|
Term
| diapedesis (extravasation) |
|
Definition
blood phagocytes exit capillaries by pseudopod movement attracts WBCs
-a kind of activity that WBC inside the blood vessel going out to the infected area
[image][image] |
|
|
Term
|
Definition
recruit blood monocytes to the injured tissues or infected cell → macrophages → phagocytosis
[image][image] |
|
|
Term
|
Definition
constriction of bronchi & bronchioles for protection of further entry of pathogen into respiratory tract
-If too severe → asthma |
|
|
Term
| meaning of the word vasation |
|
Definition
|
|
Term
| meaning of the word extravasation |
|
Definition
| go out of the blood vessel |
|
|
Term
| the only time RBC goes out of the blood vessel |
|
Definition
| when there's a hematoma, in which the inflammatory area or the swelling area is accompanied by the presence of RBC |
|
|
Term
| why WBC can exit the blood vessel while RBC can't, even though WBC is about twice as big as RBC |
|
Definition
because WBC can do psudopod movement while RBC can't
[image][image] |
|
|
Term
| why the WBC can do pseudopod movement while the RBC can't |
|
Definition
| chemotaxis (a type of biochemical signaling) |
|
|
Term
| phagocytosis in the inflammation process |
|
Definition
Degradation of bacteria or injured cells by macrophages
[image] |
|
|
Term
| the pathway by which phagocytosis occurs in the inflammation process |
|
Definition
-Tissue damage --> cell necrosis --> expressed danger-associated molecular patterns (DAMPs) --> ↑ innate immunity & inflammation
-Pseudopod movement by macrophages --> vacuole formation --> fuse with lysosomes --> phagolysosomes
[image] |
|
|
Term
|
Definition
danger associated molecule patterns
-expressed by the damaged tissue of our own cells
-can initiate in innate immunity and inflammation
[image] |
|
|
Term
| depiction of how phagocytosis occurs in the infected area |
|
Definition
|
|
Term
| Cells die by apoptosis (do or do not) express DAMPs |
|
Definition
|
|
Term
| the types of phagocytes that arrive to the infected area and the order in which they arrive |
|
Definition
1: neutrophils (pus formation)
2: blood monocytes (become macrophages and may serve as antigen presenting cells)
3: T lymphocytes, for specific immunity
[image][image] |
|
|
Term
|
Definition
-first phagocyte to arrive to the infected area
-fights against pathogen, resulting in pus formation |
|
|
Term
|
Definition
| the dead body of the neutrophil together with a dead body of the bacteria |
|
|
Term
|
Definition
-second phagocyte to arrive to the infected area
-in response to chemotaxis, monocytes send information from the damaged area
-engulfs bacteria
-present antigen from pathogen to other WBCs, including lymphocytes, to perform body defense |
|
|
Term
|
Definition
-3rd phagocyte to arrive
-last resort
-responds to antigen presented by monocyte to produce specific immunity |
|
|
Term
| Body temperature is regulated by... |
|
Definition
| hypothalamus (thermostat) |
|
|
Term
| fever can be induced by... |
|
Definition
-Exogenous pyrogens (LPS)
-Endogenous pyrogens such as interleukins (IL), or
-Endotoxin from gram “–” bac (LPS) |
|
|
Term
| how Endotoxin from gram “–” bac (LPS) causes fever |
|
Definition
| Endotoxin from gram “–” bac (LPS) --> stimulates WBCs --> release endogenous pyrogens (IL1-β & other cytokines) --> alter set point in hypothalamus of the brain |
|
|
Term
|
Definition
-Nonspecifically ↓ bac
-↑ neutrophil activities
-↑ interferon production |
|
|
Term
|
Definition
| substance that can induce fever |
|
|
Term
|
Definition
-chemicals released by WBC, leukocyte, for the communication between leukocyte. We call that interleukin
-interleukins rely on these chemicals between WBC and then induce fever. |
|
|
Term
|
Definition
-Are polypeptides produced by cells infected with virus
-Provide short-acting, non-specific resistance to viral infection in nearby cells
-they alert nearby cells to be more active against virus |
|
|
Term
|
Definition
-α interferons
-β interferons
-γ interferons |
|
|
Term
|
Definition
-↑ Overall immune activities by ↑ phagocytosis, ↑ killer T cell activities, ↑ natural killer cell activities, ↑ Ab production by plasma cells
-↓ tumor growth, ↓ cell division, ↓ maturation of adipocytes, RBC |
|
|
Term
| adaptive immunity relies on... |
|
Definition
|
|
Term
|
Definition
-B cells (B lymphocytes)
-T cells (T lymphocytes) |
|
|
Term
| origin of B cells (B lymphocytes) |
|
Definition
evidently bursa of Fabricius
-Named after lymphocytes processed from chicken bursa of Fabricius |
|
|
Term
| origin of T cells (T lymphocytes) |
|
Definition
|
|
Term
| types of B cells (B lymphocytes) |
|
Definition
-Memory cells
-plasma cells |
|
|
Term
|
Definition
| a kind of lymphoid tissue that present during gestation in fetus, or early childhood |
|
|
Term
| what happens to the thymus as the person gets older? |
|
Definition
-gets replaced more and more by fat tissue, or adipose tissue
-when this happens, the T cells go into circulation |
|
|
Term
| most lymphocyte cells in the blood are... |
|
Definition
| T cells (T lymphocytes) (65-85% of blood lymphocytes) |
|
|
Term
| where most B cells (B lymphocytes) are found |
|
Definition
| lymphoid tissue, such as spleen, such as local lymph nodes |
|
|
Term
| types of T cells (T lymphocytes) |
|
Definition
-Killer (cytotoxic) T Cells
-helper T cells
-suppressor T cells |
|
|
Term
| HIV virus specifically attacks... |
|
Definition
|
|
Term
| the "humoral" in humoral immunity means... |
|
Definition
|
|
Term
| B-cell (humoral) immunity based on... |
|
Definition
| production of antibodies, which are soluble in fluid |
|
|
Term
| why B-cell-mediated immunity is called humoral immunity |
|
Definition
| because the word humoral means "fluid," and it's based on production of antibodies, which are soluble in fluid |
|
|
Term
| B cells expand into clones, which are... |
|
Definition
-memory cells
-plasma cells
[image] |
|
|
Term
|
Definition
-long lifespan
-have the memory of this structure of a specific antigen for a long time
-waiting for the second infection by that antigen, and to expand the clone |
|
|
Term
|
Definition
-factory (2K Ab/sec)
-short-lived |
|
|
Term
| Combined work of memory cells and plasma cells |
|
Definition
| Combined work of memory cells and plasma cells --> Ab production |
|
|
Term
|
Definition
| type of globulin protein with immune function (immunoglobulin (Ig)) |
|
|
Term
| structure of antibodies (Ab) |
|
Definition
| shape of “Y”
-2 long heavy (H) chains + 2 light (L) chains
-Each chain contains constant (Fc) and variable fragments (Fab)
[image] |
|
|
Term
| variable (Fab) fragment of antibody |
|
Definition
confers antibody (Ab) specificity
[image] |
|
|
Term
| the diversity of antibodies we have |
|
Definition
|
|
Term
| why are so many antibodies possible if we have a limited number of genes? |
|
Definition
because we use recombination of different genetic segment, and to produce antibody that adapt to different kind of antigen and specificity
-Recombination of genes code for Hs and Ls in developing lymphocytes --> Ag-independent diversity
-Diversity further increases via somatic hypermutation --> B cells undergo Ag-dependent proliferation |
|
|
Term
| some categories of antibodies |
|
Definition
|
|
Term
| most common type of antibodies |
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
main Ab in external secretions in mucosal area, such as respiratory mucosa, digestive mucosa, reproductive mucosa
-they are secreted from the mucosa into the lumen of the tract, becoming secretory IgG |
|
|
Term
|
Definition
| responsible for allergic symptoms |
|
|
Term
|
Definition
| as Ag R (I think antigen receptors) on lymphocytes |
|
|
Term
|
Definition
| IgA antibodies that are secreted from the mucosal area into the lumen |
|
|
Term
| Killer (cytotoxic) T cells |
|
Definition
have CD8 surface marker
-Kill pathogens by cell-mediated destruction – in contact with victim cell
-Secrete perforins --> create a pore in victim's membrane --> lysis
-Secrete granzymes --> destroy victim's DNA
[image] |
|
|
Term
|
Definition
have CD4 surface marker
-↑ Responses of both killer T cells and B cells
-HIV infects helper T cells and macrophages
[image] |
|
|
Term
| Suppressor (regulatory) T cells |
|
Definition
have CD25 & CD4 surface markers
-↓ Responses of killer Ts and B cells; help protect against autoimmune responses
[image] |
|
|
Term
|
Definition
secreted by lymphocytes
-Usually called interleukin (IL)- 1, 2, 3
-they help mediate the activity of the T-cell |
|
|
Term
| depiction of stem cells turning into B and T lymphocytes and what they do |
|
Definition
|
|
Term
| why immunity mediated by T cells is called cell-mediated immunity |
|
Definition
| because those T cells make contact with the pathogen |
|
|
Term
| how Killer (cytotoxic) T cells kill pathogens |
|
Definition
-Secrete perforins --> create a pore in victim's membrane --> lysis
-Secrete granzymes --> destroy victim's DNA |
|
|
Term
|
Definition
| enzymes for destroying the pathogen's DNA |
|
|
Term
|
Definition
| create pores in pathogen's membrane |
|
|
Term
| Suppressor (regulatory) T cells help protect against... |
|
Definition
|
|
Term
|
Definition
Require prior exposure to the specific Ag (vaccines)
-Eg. Jenner’s cowpox inoculation against smallpox |
|
|
Term
|
Definition
(1) live attenuated virus
(2) killed virus
(3) recombinant viral proteins |
|
|
Term
|
Definition
Donor was given active immunity, Ab --> recipients
-the recipient of the antibodies and the antivenom doesn't have time to develop active immunity |
|
|
Term
| comparison of active and passive immunity |
|
Definition
|
|
Term
| why being exposed to the antibodies a second time may cause an allergic response |
|
Definition
| because it already induced an antigenic effect that the active immunity will react to |
|
|
Term
|
Definition
|
|
Term
| some components of the digestive tract |
|
Definition
-oral cavity
–pharynx
-upper pharyngoesophageal sphincter
-esophagus
-lower gastroesophageal sphincter
-stomach
-pyloric sphincter
-small intestine
-ileocecal valve
-large intestine (cecum, colon, rectum)
-anus
-internal anal sphincter
-external anal sphincter
[image] |
|
|
Term
| divisions of the small intestine |
|
Definition
|
|
Term
| lenth of the GI tract in adults |
|
Definition
|
|
Term
| some accessory organs for the digestive system |
|
Definition
-teeth
-tongue
-salivary glands
-liver
-gall bladder
-pancreas |
|
|
Term
| the 4 general layers of the GI tract |
|
Definition
-mucosa
-submucosa
-muscularis
-serosa
[image][image] |
|
|
Term
|
Definition
-the layer closest to the lumen, where the food is
-lined with epithelial cells
-lamina propria below the epithelium
-muscularis mucosa below the lamina propria
[image][image] |
|
|
Term
|
Definition
muscular tissue that helps with folding of the gut in the small intestine and the stomach
[image][image] |
|
|
Term
|
Definition
-layer of connective tissue below the mucosa
-blood vessels and main lymphatics run thru it
-contains the submucosal plexus
[image][image] |
|
|
Term
|
Definition
within the submucosa
[image][image] |
|
|
Term
|
Definition
-in the muscularis layer
-between 2 muscular layers
-communicates with neurons
[image][image] |
|
|
Term
| the smooth muscle layers of the muscularis |
|
Definition
-inner circular layer
-outer longitudinal layer
they're governed by the autonomic and enteric nervous systems
[image][image] |
|
|
Term
|
Definition
An outer epithelial membrane that covers the surface of a visceral organ
-thinner outside layer
-adjacent to it is the abdominal cavity
[image][image] |
|
|
Term
|
Definition
| tissue that kinda lines the gut and is where the vessels, lymphatics, and most of the nerves run into the gut |
|
|
Term
| the most diverse layer of the GI tract |
|
Definition
| mucosa, especially the epithelial layer |
|
|
Term
|
Definition
| protrusions of the mucosa into the lumen |
|
|
Term
|
Definition
inpouchings down into the laminar propria
-their main job is to absorb nutrients |
|
|
Term
|
Definition
-characterized by squamous epithelium
-found in the oral cavity, pharynx, esophagus, and anal canal |
|
|
Term
|
Definition
-contains cells that are responsible for the secretion of digestive enzymes
-found only in the stomach |
|
|
Term
|
Definition
-contains crypts and villi
-responsible primarily for absorbing digested nutrients
-found along the entirety of the small intestine |
|
|
Term
| absorptive and protective mucosa |
|
Definition
-specializes in water absorption and mucous secretion
-found in the large intestine |
|
|
Term
| some general digestive activities in the GI tract |
|
Definition
-Motility
-Secretion
-Digestion
-Absorption
-Storage
-Elimination
-Regulation
[image] |
|
|
Term
| how the GI tract does Motility |
|
Definition
-mastication (chewing)
-deglutition (swallowing)
-peristalsis
-segmentation
-haustration
-defecation |
|
|
Term
| how the GI tract does Secretion |
|
Definition
-endocrine (hormones)
-paracrine
-exocrine (enzymes, electrolytes, HCl & water) |
|
|
Term
| how the GI tract does Digestion |
|
Definition
|
|
Term
| how the GI tract does Absorption |
|
Definition
| digested food enters blood or lymph |
|
|
Term
| how the GI tract does Storage |
|
Definition
|
|
Term
| how the GI tract does Elimination |
|
Definition
bile and indigestible food
-some substances are put into the bile to be eliminated |
|
|
Term
| how the GI tract does Regulation |
|
Definition
| neural (enteric nervous system ENS and ANS) and hormonal |
|
|
Term
|
Definition
| Waves of smooth muscle contraction in smooth muscles of the tubular digestive tract. It involves circular and longitudinal muscle fibers at successive locations along the tract and serves to propel the contents of the tract in one direction. |
|
|
Term
|
Definition
| segments of the gut constricting on food |
|
|
Term
|
Definition
|
|
Term
|
Definition
| kinda like peristalsis and segmentation in the colon |
|
|
Term
| endocrine functions in the GI tract |
|
Definition
|
|
Term
| paracrine and exocrine functions in the GI tract |
|
Definition
| enzymes, electrolytes, HCl & water |
|
|
Term
|
Definition
breaks down non-absorbable polymers (carbohydrates, fats, and proteins) into absorbable monomer (mostly) building blocks
-obtains basic organic molecules to make ATP, build tissues, and serve as cofactors and coenzymes.
[image] |
|
|
Term
| how digestion degrades non-absorbable molecules into smaller, absorbable molecules |
|
Definition
Hydrolysis into monomers, aided by specific enzymes
[image] |
|
|
Term
| what the basic molecules obtained by digestion are used for |
|
Definition
| to make ATP, build tissues, and serve as cofactors and coenzymes |
|
|
Term
| function of the oral cavity |
|
Definition
-chewing
-Mixes food with saliva which contains salivary amylase, mucus, growth factors.
-1st stage of deglutition (oral stage, which is voluntary)
[image] |
|
|
Term
| the function of the pharynx |
|
Definition
| -2nd stage of deglutition (Pharyngeal stage, which is involuntary) |
|
|
Term
| function of the esophagus |
|
Definition
-Deglutition (swallowing)
-3rd stage of Deglutition (esophageal stage, which is involuntary) |
|
|
Term
| the stages of Deglutition (swallowing) |
|
Definition
1: Oral stage (voluntary) – bolus moved to pharynx
2: Pharyngeal stage (involuntary) – soft palate covers nasopharynx, vocal folds close and epiglottis covers them (larynx), upper esophageal sphincter relaxes.
3: Esophageal stage (involuntary) – peristalsis moves food down esophagus to stomach.
[image] |
|
|
Term
| the salivary glands in the oral cavity |
|
Definition
-parotid
-submandibular
-sublingual
[image] |
|
|
Term
| what the soft pallate does during swallowing |
|
Definition
covers the nasopharynx to keep food and liquid from going into your nasal passages
-the vocal folds close to cover the epiglottis
[image][image] |
|
|
Term
|
Definition
-voluntary
–bolus moved to pharynx
[image] |
|
|
Term
| Pharyngeal stage of swallowing |
|
Definition
involuntary – soft palate covers nasopharynx, vocal folds close and epiglottis covers them (larynx), upper esophageal sphincter relaxes
Bolus is moved out of pharynx --> through upper esophageal sphincter --> into esophagus.
[image] |
|
|
Term
| Esophageal stage of swallowing |
|
Definition
-involuntary
–peristalsis moves food down esophagus to stomach
[image][image] |
|
|
Term
| the movement of bolus through esophagus before it gets to the lower esophageal sphincter |
|
Definition
-*Upper third contains skeletal muscle, transitions to smooth m.
-Passes through diaphragm via hiatus.
[image] |
|
|
Term
| the movement of bolus through esophagus when it gets to the lower esophageal sphincter |
|
Definition
Lower esophageal sphincter
-Relaxes to allow bolus to pass.
-Closed to prevent regurgitation; heart burn – gastroesophageal reflux disease (GERD)
[image] |
|
|
Term
| heart burn (gastroesophageal reflux disease (GERD)) |
|
Definition
when stomach acid goes into the esophagus due to the failure of the lower esophageal sphincter to close properly
-it causes erosions
[image] |
|
|
Term
|
Definition
Series of localized reflexes in response to distention of wall by bolus.
-uses a peristaltic wave
[image] |
|
|
Term
|
Definition
coordinated, wave-like muscular contractions
[image] |
|
|
Term
| how the peristaltic wave occurs in the esophagus |
|
Definition
| -Circular smooth muscle contracts on the proximal side and relaxes on the distal side of the bolus --> followed by longitudinal contraction (shortening) of smooth muscle.
-After food passes into stomach, lower esophageal sphincter constricts.
-*These principles apply throughout the GI tract.
-this is a lot faster in the esophagus than in the small intestine
[image] |
|
|
Term
|
Definition
|
|
Term
|
Definition
|
|
Term
|
Definition
| The state of being distended, enlarged, swollen from internal pressure |
|
|
Term
| depiction of how deglutition (swallowing) is neurologically controlled |
|
Definition
|
|
Term
|
Definition
-Cardia
-fundus
-body
-antrum
-pylorus
-pyloric sphincter
-Gastric glands (deeper in the mucosa)
[image]
[image] |
|
|
Term
|
Definition
-Stores food
-Churns food to mix with gastric secretions
-Initiates digestion of proteins via secretions
-Kills bacteria
-Moves food (chyme) into the small intestine |
|
|
Term
|
Definition
where the food enters the stomach
[image]
[image] |
|
|
Term
|
Definition
-in the stomach
-allow the stomach to expand
[image]
[image] |
|
|
Term
| chyme (pronounced "kyme") |
|
Definition
digested food in the stomach and intestines
-stops being chyme when it gets turned into feces |
|
|
Term
| the 3 muscle layers in the stomach |
|
Definition
1: inner Oblique
2: Circular
3: outer Longitudinal
[image] |
|
|
Term
| what the stomach does in terms of motility |
|
Definition
|
|
Term
| how the stomach does mixing during motility |
|
Definition
weak peristaltic constricting waves fundus to antrum
-Food + gastric secretions --> chyme
-Pyloric sphincter “closed”
[image] |
|
|
Term
| how the stomach does emptying during motility |
|
Definition
strong peristaltic waves starting in antrum to pylorus
-Pyloric sphincter “relaxed” --> chyme enters duodenum.
-Full duodenum --> pressure closes pyloric sphincter
[image] |
|
|
Term
| where gastric glands are found |
|
Definition
| gastric pits; the mucosa contains numerous gastric pits |
|
|
Term
|
Definition
line the pits and secrete exocrine molecules and water (gastric juice) into lumen, and endocrine and paracrine signaling molecules into interstitial space of mucosa.
[image] |
|
|
Term
| some types of cells within the gastric glands |
|
Definition
(1) Goblet cells (mucous neck cells)
(2) Parietal cells
(3) Chief cells
(4) Enterochromaffin-like cells (ECL)
(5) G cells
(6) D cells
(7) Ghrelin cells
[image] |
|
|
Term
| Goblet cells (mucous neck cells) |
|
Definition
cells inside the gastric glands that secrete mucus & bicarbonate as protection against stomach acid
[image] |
|
|
Term
|
Definition
| cells inside the gastric glands that secrete gastric acid (HCl), which breaks down food, and intrinsic factor (IF), which helps absorb vitamin B12, which is used for making heme
[image] |
|
|
Term
|
Definition
cells inside the gastric glands that secrete pepsinogen, which is important for protein digestion
[image] |
|
|
Term
| Enterochromaffin-like cells (ECL) |
|
Definition
cells inside the gastric glands that secrete the paracrine molecules histamine and serotonin to trigger function of neighboring cells
[image] |
|
|
Term
|
Definition
cells inside the gastric glands that secrete gastrin endocrine hormone
[image] |
|
|
Term
|
Definition
cells inside the gastric glands that secrete somatostatin – paracrine and endocrine – inhibits secretion of multiple GI hormones
[image] |
|
|
Term
|
Definition
cells inside the gastric glands that secrete ghrelin – ↑ during fasting --> stimulate hunger
[image] |
|
|
Term
|
Definition
| the only essential function in stomach – polypeptide that promotes absorption of vitamin B12 in the ileum --> helps prevent pernicious anemia |
|
|
Term
| the reaction that produces H+ in the cytosol of the goblet cells in the stomach |
|
Definition
| CO2 + H2O --> H+ + HCO3- by carbonic anhydrase
[image] |
|
|
Term
| transport of ions at the apical membrane in the process of making gastric acid (HCl) |
|
Definition
| H+ is secreted into gastric lumen by primary active transport, through H+/ K+ ATPase (proton pump), Cl- is secreted through facilitated diffusion.
[image] |
|
|
Term
| concentration of H+ in lumen vs. that in parietal cells |
|
Definition
| 3 x 106 times more H+ in lumen than inside parietal cells
[image] |
|
|
Term
| transport of ions at the basolateral membrane in the process of making gastric acid (HCl) |
|
Definition
| HCO3- exits cells against its electrochemical gradient, by coupling its transport with Cl- following gradient – secondary active transport
[image] |
|
|
Term
| how gastric acid (HCl) secretion is regulated neurologically |
|
Definition
enteric and parasympathetic nervous systems (ACh) stimulates parietal & ECL cells.
-Binds muscarinic Rs.
[image] |
|
|
Term
| how gastric acid (HCl) secretion is regulated by endocrine means |
|
Definition
gastrin from G cells, carried to parietal & ECL cells by blood circulation
[image] |
|
|
Term
| how gastric acid (HCl) secretion is regulated by paracrine means |
|
Definition
| ECL cells secrete histamine --> binds H2 Rs on parietal cells
[image] |
|
|
Term
| Enterochromaffin-like (ECL) cells |
|
Definition
| Enterochromaffin-like cells
-secrete histamine --> binds H2 Rs on parietal cells
[image] |
|
|
Term
| the role of acetylcholine in the regulation of gastric acid (HCl) secretion |
|
Definition
| -binds muscarinic receptors
-ultimately triggers intracellular signaling, leading to activity of the H+ / K+ ATPase pump
[image] |
|
|
Term
| the 3 phases of regulation of stomach activities |
|
Definition
-Cephalic phase
-Gastric phase
-Intestinal phase |
|
|
Term
| Cephalic phase of regulation of stomach activities |
|
Definition
sight, smell, & taste of food --> ↑ vagal tone, gastrin and histamine activation --> ↑ secretion.
-increases tone to the vagus nerve
-"anticipating food" |
|
|
Term
| Gastric phase of regulation of stomach activities |
|
Definition
food in stomach --> physical distension and chemical nature of chyme (amino acids etc. ) --> ↑ secretion.
-Positive feedback– ↑ secretion of HCl and pepsinogen --> ↑ gastric secretion. |
|
|
Term
| Intestinal phase of regulation of stomach activities |
|
Definition
| gastric activity inhibited when chyme enters the small intestine. |
|
|
Term
|
Definition
| digestion and small amount of absorption |
|
|
Term
| function of HCl in the stomach |
|
Definition
HCl functions to provide an acidic gastric environment
-Denatures ingested proteins
-Activates pepsinogen to pepsin (pH = 2).
-Kills bacteria |
|
|
Term
| how digestion occurs in the stomach |
|
Definition
-Proteins denatured and partially digested by pepsin more digestible.
-Carbohydrate digestion by salivary amylase is soon inactivated by acidity. |
|
|
Term
| why carbohydrate digestion by salivary amylase stops in the stomach |
|
Definition
| because it gets inactivated by acidity |
|
|
Term
| some molecules that can get absorbed through the stomach lining |
|
Definition
-Alcohol (ethanol) – main absorption site is the small intestine.
-Aspirin and salicylates – unionized at gastric pH. |
|
|
Term
| why aspirin and salicylates can get absorbed through the stomach lining |
|
Definition
| because they're unionized at gastric pH |
|
|
Term
| how alkaline mucus functions as a chemical protective mechanism in the stomach |
|
Definition
| it contains HCO3- and forms a barrier against actions of pepsin & acid.
[image] |
|
|
Term
| some physical protective mechanisms in the stomach |
|
Definition
-Tight junctions
-Rapid rate of cell division
[image] |
|
|
Term
| how tight junctions function as a physical protective mechanism in the stomach |
|
Definition
between adjacent cells; keeps acid from getting between cells
[image] |
|
|
Term
| how rapid rate of cell division functions as a physical protective mechanism in the stomach |
|
Definition
entire epithelium replaced in 3 days
-they wear out fast
-the new cells work their way up from the gastric pits
[image] |
|
|
Term
| where the new cells for the stomach epithelium come from |
|
Definition
|
|
Term
| how prostaglandins help to protect the stomach epithelium |
|
Definition
| *Prostaglandins E2 (PGE2) and I2 (PGI2) --> ↓ gastric acid & ↑ mucus secretions, ↑ mucosal blood flow.
-they're "housekeeping" prostaglandins
[image] |
|
|
Term
| how Prostaglandins E2 and I2 |
|
Definition
-helps decrease gastric acid and increase mucus secretions
-nutritive
-helps remove metabolic waste products |
|
|
Term
|
Definition
Erosions of mucosa of stomach or duodenum
[image] |
|
|
Term
| chemicals that can damage lining to produce an ulcer |
|
Definition
|
|
Term
| some causes of peptic ulcers |
|
Definition
| -gastrin-secreting tumor
-Helicobacter pylori
-NSAIDs (aspirin, ibuprofen, etc.) |
|
|
Term
| how NSAIDs (aspirin, ibuprofen, etc.) cause peptic ulcers |
|
Definition
| by inhibiting paracrine secretion of PGE2 & PGI2 |
|
|
Term
| some treatments for ulcers |
|
Definition
| -Proton pump inhibitors such as omeprazole (Prilosec)
-Histamine receptor (H2) blockers such as famotidine (Pepcid) and ranitidine (Zantac)
-Antibiotics |
|
|
Term
| the 3 sections of the small intestine |
|
Definition
-Duodenum
-Jejunum
-Ileum
[image] |
|
|
Term
|
Definition
–short
-Bile and pancreatic duct empty here
[image][image] |
|
|
Term
|
Definition
2/5 length of small intestine
[image] |
|
|
Term
|
Definition
3/5 length of small intestine
-Ileocecal valve into colon
[image][image] |
|
|
Term
|
Definition
the valve through which the chyme goes from the ileum into the colon
[image] |
|
|
Term
| some structural components of the small intestine |
|
Definition
-Folds (plicae circulares)
-villi
-microvilli (aka the brush border)
-Epithelial cells (enterocytes)
-goblet cells
-intestinal crypts
-Lamina propria
+lymphocytes
+capillaries
+central lacteal
[image] |
|
|
Term
| the structures in the small intestine that increase surface area to let it do its job more efficiently |
|
Definition
| Folds (plicae circulares) --> villi --> microvilli (also known as the brush border)
[image] |
|
|
Term
| Epithelial cells (enterocytes) interspersed with... |
|
Definition
|
|
Term
|
Definition
| epithelial cells of the small intestine |
|
|
Term
| how the epithelial cells at the tips of villi are maintained |
|
Definition
-exfoliated
-replaced by mitosis in intestinal crypts |
|
|
Term
| where the new enterocytes (epithelial cells of the small intestine) come from |
|
Definition
|
|
Term
| Lamina propria contains... |
|
Definition
-lymphocytes
-capillaries
-central lacteal |
|
|
Term
| functions of the small intestine |
|
Definition
| complete digestion and absorption of carbohydrates, proteins, and fats |
|
|
Term
| enzymes needed for digestion in the small intestine |
|
Definition
-pancreatic enzymes
-brush border enzymes |
|
|
Term
| why absorption in the small intestine is very rapid |
|
Definition
|
|
Term
|
Definition
| attached to surface of microvilli – not secreted |
|
|
Term
| advantage of the brush-border enzymes being attached to the surface of the microvilli instead of floating around |
|
Definition
makes them last longer due to negating the need to continue synthesizing them
[image] |
|
|
Term
| what the duodenum and jejunum absorb |
|
Definition
| -carbohydrates
-amino acids
-lipids
-iron
-Ca2+
-H2O |
|
|
Term
|
Definition
| -bile salts
-vitamin B12
-electrolytes
-H2O |
|
|
Term
| some ways water gets into the GI tract |
|
Definition
-Diet
-saliva
-gastric secretions
-bile
-pancreatic juice
-SI secretions
-colonic secretions
[image] |
|
|
Term
| some ways water gets out of the GI tract |
|
Definition
-SI reabsorption
-colonic reabsorption
[image] |
|
|
Term
| water that enters the GI tract, but does not get reabsorbed, is lost in... |
|
Definition
|
|
Term
| where water gets absorbed in the GI tract |
|
Definition
| -mostly small intestine (all but ~2L) |
|
|
Term
| how water absorption occurs in the small intestine |
|
Definition
| absorbs all but ~ 2 L of ingested H2O, and H2O from GI secretions
-Absorbs Na+ and Cl- via facilitated diffusion.
-Na+ cotransported with glucose.
-Na+, K+ ATPase pump moves Na+ out of enterocytes into interstitial fluid.
-Water follows Na+ by osmosis.
[image] |
|
|
Term
| how water absorption occurs in the large intestine |
|
Definition
| -absorbs Na+ via facilitated diffusion
-H2O follows by osmosis
+Roughly 100+ mL H2O remains in feces daily. |
|
|
Term
| the 2 major types of motility patterns derived from contractions in the small intestine |
|
Definition
-Peristalsis
-Segmentation |
|
|
Term
|
Definition
-Movement of chyme through the small intestine.
-Slow and weak movement – avg. 1 cm/min.
[image] |
|
|
Term
|
Definition
-Major contractile activity of the small intestine 2-3x/min.
-Strong contraction of circular smooth muscle to mix chyme.
-this is to mix the contents; these muscles can squish forward, backwards, up, and down
[image] |
|
|
Term
| some ways by which humoral regulation of intestinal activity is done |
|
Definition
-Endocrine regulation
-Paracrine regulation |
|
|
Term
| some things secreted by the enterocytes for endocrine regulation of intestinal activities |
|
Definition
-Secretin
-Cholecystokinin (CCK), a.k.a. pancreazymin
-Gastric inhibitory peptide or glucose-dependent insulinotropic peptide (GIP)
-Motilin |
|
|
Term
| how paracrine regulation of the intestinal activities is done |
|
Definition
| filling --> ↑ intestinal pressure --> ↑ secretion of serotonin (ECL cells) in intestinal mucosa --> ↑ muscle contractions |
|
|
Term
|
Definition
| stimulus: drop in pH.
-Stimulates HCO3- and H2O secretion in pancreatic juice.
-Inhibits gastrin secretion. |
|
|
Term
| Cholecystokinin (CCK), a.k.a. pancreazymin |
|
Definition
| stimulus: presence of partially digested fats and proteins.
-Stimulates contraction of gallbladder, thus secretion of bile.
-Stimulates enzymatic and HCO3- secretion in pancreatic juice. |
|
|
Term
| Gastric inhibitory peptide or glucose-dependent insulinotropic peptide (GIP) |
|
Definition
stimulus: proteins, fats, CHOs.
-Stimulates insulin secretion from endocrine pancreas.
-Inhibits gastric motility & HCl secretion --> slows emptying. |
|
|
Term
|
Definition
| released from M cells during fasting --> stimulates motility |
|
|
Term
| the parts of the small intestine in order |
|
Definition
cecum --> ascending colon --> transverse colon --> descending colon --> sigmoid colon --> rectum --> anal canal --> anus
[image] |
|
|
Term
| how motility occurs in the large intestine |
|
Definition
Outer surface bulges outward to form haustra (bag-like structure).
1) Haustrations
2) Mass propulsive movements.
[image] |
|
|
Term
|
Definition
part of the outer surface of the large intestine that bulges outward to form a bag-like structure
[image] |
|
|
Term
|
Definition
| mixing movements in the large intestine triggered by chyme |
|
|
Term
| the histological makeup of the large intestine |
|
Definition
-No plicated folds or villi.
-Thin brush border on epithelial cells.
-Many goblet cells.
[image] |
|
|
Term
|
Definition
| roughly the 1st half of the colon
-H2O (most of remaining 10-15%) and electrolytes (Na+, Cl-).
-HCO3- secreted to neutralize acidic products of bacterial metabolism.
-Production of vitamin B complexes and vitamin K via microbes. |
|
|
Term
|
Definition
| roughly the 1st half of the colon
-Feces with residual H2O |
|
|
Term
| what the microbes in the absorbing colon do |
|
Definition
| -make vitamin K and some B vitamins (riboflavin, thiamin, biotin, pantothenic acid, folic acid)
-make short-chain fatty acids (FAs) from cellulose
+FAs help absorb Na+, Ca2+, HCO3-, Mg2+, Fe2+ (much less absn. in colon vs. SI).
-Beneficial (mutualism) vs. harmful species of bacteria |
|
|
Term
| diversity of microbes in the large intestine |
|
Definition
| > 400 different species of microbes |
|
|
Term
| Disruption of normal microflora leads to... |
|
Definition
|
|
Term
| what causes the defecation reflex? |
|
Definition
| Waste material passes to the rectum |
|
|
Term
| the amount of your feces that's composed of bacteria |
|
Definition
|
|
Term
| the pathway of the defecation reflex |
|
Definition
Distension of rectum by fecal material --> signals sent to the sacral region of the spinal cord --> induction of defecation reflex --> relaxation of internal anal sphincter (involuntary) and external anal sphincter (voluntary), aided by contractions of abdominal and pelvic muscles which push feces from rectum --> defecation
[image] |
|
|
Term
| why the defecation reflex is called a reflex |
|
Definition
because part of it goes through the spinal cord and back without going to the brain
[image] |
|
|
Term
| some functions of the liver |
|
Definition
|
|
Term
|
Definition
|
|
Term
| why the liver is so good at regenerating |
|
Definition
| Active hepatocytes undergo mitosis --> amazing regenerative abilities |
|
|
Term
| some groups of blood vessels in the liver |
|
Definition
-hepatic artery
-hepatic portal system
-hepatic veins
[image][image] |
|
|
Term
|
Definition
-brings oxygenated blood to liver
-Branches off aorta
[image][image] |
|
|
Term
|
Definition
-brings nutrients and deoxygenated blood from abdominal organs to liver
-Venous return for the abdominal organs
[image][image][image] |
|
|
Term
|
Definition
multiple hepatic veins take deoxygenated blood from liver to inferior vena cava
[image][image] |
|
|
Term
| depiction of how the hepatic portal system works |
|
Definition
|
|
Term
| why the liver is organized the way it is |
|
Definition
| Organized to filter the blood. Blood percolates through endothelium-lined sinusoids between cords or plates of hepatocytes into the central vein, which then drains into the hepatic vein. |
|
|
Term
| how the liver is organized |
|
Definition
Lobes --> lobules --> hepatic cords or plates --> hepatocytes
[image] |
|
|
Term
| the histology of the lobule |
|
Definition
|
|
Term
| portal triad in the liver |
|
Definition
corners at the liver's lobules where the branches of hepatic artery, portal vein, and bile ductules run together
[image] |
|
|
Term
| after the portal triad, the fluid empties into the... |
|
Definition
central vein, which leads to the bile duct
[image] |
|
|
Term
| Perimeter of each lobule is defined by... |
|
Definition
| portal triads at the corners |
|
|
Term
| the direction everything flows in the portal triad |
|
Definition
|
|
Term
| the flow of oxygen-rich and nutrient-rich blood in the portal triad |
|
Definition
Oxygen-rich blood from hepatic artery and nutrient-rich blood from hepatic portal vein mix and flow through sinusoids toward central vein in center of each lobule.
[image] |
|
|
Term
| one advantage of the liver's endothelium being fenestrated |
|
Definition
hepatocytes directly exposed to blood
-this makes it easier for hepatocytes to secrete albumin into the blood stream |
|
|
Term
| the flow of bile through the bile canaliculi in the portal triad |
|
Definition
collect waste products --> flow in opposite direction (away from central vein) to bile ductules in portal triads --> gall bladder
[image] |
|
|
Term
|
Definition
part of the portal triad
-collect waste products --> flow in opposite direction (away from central vein) to bile ductules in portal triads --> gall bladder
[image] |
|
|
Term
| how bile secretion is triggered, and then occurs |
|
Definition
Bile stored in gall bladder until signaled to release:
-Cholecystokinin – primary signal
-Parasympathetic and enteric nervous system (ACh)
[image] |
|
|
Term
|
Definition
primary signal for bile secretion
[image] |
|
|
Term
| Enterohepatic (re)circulation |
|
Definition
95% of bile from ileum reabsorbed --> portal vein --> reused
-whatever doesn't get recirculated winds up in the stool
[image] |
|
|
Term
|
Definition
| a collective term, it contains
-bile acids
-bile salts
-Bile pigment – bilirubin (heme without Fe)
-Electrolytes
-cholesterol
-HCO3-
-water
[image] |
|
|
Term
| Bile acids and bile salts |
|
Definition
-Precursor – cholesterol.
-Aids digestion of fat.
[image] |
|
|
Term
| Bile pigment aka bilirubin |
|
Definition
heme without Fe
-Aged RBC --> engulfed by phagocytes mainly in spleen and bone marrow --> … --> liver --> conjugated bilirubin.
[image] |
|
|
Term
| Jaundice or icterus caused by... |
|
Definition
↑ in blood bilirubin levels
[image] |
|
|
Term
| endocrine functions of the pancreas |
|
Definition
Islets of Langerhans secrete...
-insulin
-glucagon
-somatostatin |
|
|
Term
| exocrine and digestive function of pancreas |
|
Definition
| pancreatic juice secreted from acinar cells in acini --> pancreatic ducts.
-*Contains H2O, HCO3- and digestive enzymes.
-Complete digestion of food requires action of both pancreatic and brush border enzyme. |
|
|
Term
| some things that signal for pancreatic juice to be released |
|
Definition
-Secretin
-Cholecystokinin
-Parasympathetic and enteric nervous systems (ACh) |
|
|
Term
| Most pancreatic enzymes are produced as... |
|
Definition
| inactive precursors called zymogens |
|
|
Term
|
Definition
(when activated by enterokinase in the small intestine)
-triggers the activation of other pancreatic enzymes
-breaks peptide bonds within the aino acid chain |
|
|
Term
| Pancreatic trypsin inhibitor |
|
Definition
| inhibits activation of trypsin in the pancreas |
|
|
Term
| the 3 main enzymes that the pancreas secretes |
|
Definition
|
|
Term
| depiction of the duct of the pancreas that releases enzymes |
|
Definition
|
|
Term
|
Definition
the enzyme that activates trypsinogen into trypsin
[image] |
|
|
Term
| what would happen if the pancreas did not use trypsin inhibitor? |
|
Definition
| trypsinogen could possible turn into trypsin while still in the pancreas |
|
|
Term
|
Definition
| removes FAs from glycerol |
|
|
Term
|
Definition
|
|
Term
| the role of bicarbonate in the small intestine |
|
Definition
| helps neutralize gastric acid to prevent gastric acid reflux back into the pancreatic ducts |
|
|
Term
| some types of regulation that regulate the digestive system |
|
Definition
-neural regulation
-hormonal regulation |
|
|
Term
| differences between neural and hormonal regulation of the digestive system |
|
Definition
-neuronal occurs faster and lasts shorter
-hormonal occurs slower and lasts longer |
|
|
Term
| extrinsic component of the neuronal regulation of the GI activity |
|
Definition
|
|
Term
| how the extrinsic parasympathetic component of the nervous system regulates GI activity |
|
Definition
–generally stimulatory
–vagus nnerves and sacral nerves |
|
|
Term
| how the extrinsic sympathetic component of the nervous system regulates GI activity |
|
Definition
| generally inhibitory (inhibits peristalsis and secretion, stimulates contraction of sphincters) |
|
|
Term
| intrinsic division of the neuronal regulation of the GI system |
|
Definition
| domain of the enteric nervous system (enteric or visceral brain) |
|
|
Term
| Submucosal & myenteric plexi |
|
Definition
where extrinsic and intrinsic divisions of neuronal regulation of the GI system meet
[image] |
|
|
Term
| depiction of the enteric nervous system (ENS), showing the sympathetic and parasympathetic divisions |
|
Definition
|
|
Term
|
Definition
input to ENS, ANS, brain
[image] |
|
|
Term
| Myenteric or Auerbach’s plexus |
|
Definition
between longitudinal and circular smooth m. – controls GI movements.
-innervates smooth m. of muscular layer from esophagus thru entire GI tract.
(1) ↑ tone (tonic)
(2) ↑ intensity of contractions (phasic)
(3) ↑ rate of contractions (phasic)
(4) ↑ conduction rate of excitatory waves.
[image] |
|
|
Term
| Submucosal or Meissner’s plexus |
|
Definition
within submucosa – controls GI secretions and local blood flow.
-in SI and LI.
-Innervates mucosal layer.
-Controls local secretion, local absorption, and local contraction of muscularis mucosa.
[image] |
|
|
Term
| Autonomic nervous system (ANS) |
|
Definition
mainly works through influencing ENS neurons.
[image] |
|
|
Term
|
Definition
| maintaining tone over time |
|
|
Term
|
Definition
| briefer, short-term changes in firing of neurons |
|
|
Term
| types of smooth muscle electrical activity in the GI system |
|
Definition
(1) Slow Waves
(2) Spike Potentials |
|
|
Term
|
Definition
not action potentials
-Interstitial cells of Cajal pacemakers.
-Slow, rhythmic, low intensity gradually bring smooth muscle to threshold.
[image][image] |
|
|
Term
|
Definition
action potentials
-Slow waves that reach approx. – 40 mV.
-Last longer than neuronal APs.
-Stretch and parasympathetic NS trigger depolarization.
-Sympathetic NS triggers hyperpolarization.
[image][image] |
|
|
Term
| some details about how neural regulation of peristalsis occurs |
|
Definition
-Presence of food bolus induces contraction and relaxation simultaneously in the same muscle bundles.
-Stretch triggers mechanoreceptors.
-Potential role for chemoreceptors.
[image][image] |
|
|
Term
| the pathway by which neural regulation of peristalsis occurs |
|
Definition
Stretch triggers mechanoreceptors. Potential role for chemoreceptors. Afferent sensory neurons --> Cholinergic interneurons in ENS --> ACh triggers release of ACh and substance P proximal to bolus --> smooth muscle contraction behind bolus.
-ACh triggers release of NO, VIP, and ATP distal to bolus --> smooth muscle relaxation in front of the bolus.
[image][image] |
|
|
Term
| some short reflexes within the GI tract mediated by ENS |
|
Definition
-Gastroileal reflex
-Ileogastric reflex
-Intestino-intestinal reflex
[image] |
|
|
Term
|
Definition
↑ gastric activity --> ↑ motility of ileum --> ↑ movement of chyme through ileocecal sphincter.
[image] |
|
|
Term
|
Definition
↑ distension of ileum --> ↓ gastric motility.
[image] |
|
|
Term
| Intestino-intestinal reflex |
|
Definition
↑ distension in one GI segment --> relaxation throughout the rest of intestine.
[image] |
|
|
Term
| Long reflexes in the GI system |
|
Definition
involve communication through CNS to mediate ENS function.
[image] |
|
|
Term
| table summarizing the GI hormones |
|
Definition
|
|
Term
| some GI hormones you should not forget |
|
Definition
|
|
Term
| endocrine mediators target... |
|
Definition
-epithelial cells
-smooth muscle |
|
|
Term
| Paracrine mediators target... |
|
Definition
-epithelial cells
-neurons |
|
|
Term
| some paracrine mediators involved in the GI system |
|
Definition
|
|
Term
| sequence of how carbohydrates get digested |
|
Definition
-Salivary amylase – begins starch digestion.
-Pancreatic amylase – digests starch to oligosaccharides.
-Brush border enzymes – hydrolyzes oligosaccharides into monosaccharides.
[image] |
|
|
Term
|
Definition
begins starch digestion.
[image] |
|
|
Term
|
Definition
digests starch to oligosaccharides.
[image] |
|
|
Term
|
Definition
hydrolyzes oligosaccharides into monosaccharides.
[image] |
|
|
Term
| the carbohydrates that get absorbed |
|
Definition
only monosaccharides, such as...
-Glucose
-galactose
-fructose
[image] |
|
|
Term
|
Definition
| -by secondary active transport
-co-transporting glucose with Na+.
[image] |
|
|
Term
| Absorbed monosaccharides goes to... |
|
Definition
blood (via portal vessel to the liver).
[image] |
|
|
Term
|
Definition
the transporter through which glucose exits enterocytes to interstitial fluid
-this is facilitated transport
[image] |
|
|
Term
| lactose intolerance caused by... |
|
Definition
|
|
Term
| Digestion of proteins begins in the stomach when... |
|
Definition
| pepsin digests proteins to form polypeptides. |
|
|
Term
| how digestion of polypeptides occurs in the duodenum and jejunum |
|
Definition
-Endopeptidases cleave peptide bonds in the interior of the polypeptide
-Exopeptidases cleave peptide bonds from the ends of the polypeptide
[image] |
|
|
Term
| how digestion of polypeptides occurs in the enterocytes |
|
Definition
Di- and tripeptides --> amino acids.
[image] |
|
|
Term
|
Definition
-in the duodenum and jejunum
-cleave peptide bonds in the interior of the polypeptide
+Trypsin
+chymotrypsin
[image] |
|
|
Term
|
Definition
-in the duodenum and jejunum
-cleave peptide bonds from the ends of the polypeptide
+Carboxypeptidases
+aminopeptidases
[image] |
|
|
Term
| the endopeptidases in the duodenum and jejunum |
|
Definition
-Trypsin (pancreatic)
-chymotrypsin (pancreatic)
[image] |
|
|
Term
| the exopeptidases in the duodenum and jejunum |
|
Definition
-Carboxypeptidases (pancreatic)
-aminopeptidases (brush-border)
[image] |
|
|
Term
|
Definition
-cleaves proteins at the amino end
-brush border enzyme in the duodenum and jejunum that helps digest polypeptides.
-The other 3, trypsin, chymotrypsin, and carboxypeptidase, are pancreatic.
[image] |
|
|
Term
|
Definition
-pancreatic enzyme in the duodenum and jejunum
-cleaves proteins at the carboxy end
[image] |
|
|
Term
| how proteins are absorbed |
|
Definition
| 1: free amino acids absorbed by co-transport with Na+ (secondary active transport)
2: Di-peptides and tri-peptides transported by secondary active transport using a H+ gradient to transport them into the cytoplasm
3: Facilitated transport of amino acids into interstitial fluid --> portal system --> liver.
[image] |
|
|
Term
| the result of lipids entering the duodenum |
|
Definition
Arrival of lipids in duodenum --> ↑ secretion of bile
[image][image] |
|
|
Term
| Functions of bile acids/salts |
|
Definition
-Emulsification
-Micelle formation
[image][image] |
|
|
Term
|
Definition
forms smaller fat molecules from big fat droplets --> ↑ surface areas for lipid-lipase contact.
[image][image] |
|
|
Term
|
Definition
transports digested fat in micelles --> move to brush border for absorption.
[image][image] |
|
|
Term
| how digestion of lipids occurs in the small intestine |
|
Definition
-Pancreatic lipase + colipase --> triglycerides --> fatty acids + monoglycerides.
-Pancreatic phospholipase digests phospholipids into fatty acids.
[image][image] |
|
|
Term
|
Definition
Pancreatic lipase + colipase --> triglycerides --> fatty acids + monoglycerides.
[image][image] |
|
|
Term
|
Definition
digests phospholipids into fatty acids.
[image][image] |
|
|
Term
| how lipids are transported in the gut |
|
Definition
|
|
Term
|
Definition
-bile salts
-free fatty acids
-monoglycerides
-phospholipids
-cholesterol
[image] |
|
|
Term
| the role of micelles in absorption of fat |
|
Definition
Micelles allow diffusion of constituents through unstirred water layer on enterocytes -> absorption through apical membranes of epithelium.
[image] |
|
|
Term
| what happens to micelles after they enter the cell? |
|
Definition
Resynthesize triglycerides and phospholipids within cell --> combine with apolipoprotein to form chylomicrons.
[image] |
|
|
Term
| what happens to chylomicrons after they get secreted out of the cell? |
|
Definition
chylomicrons --> secrete into central lacteals --> larger lymphatic vessels --> thoracic duct --> mix with venous blood at vena cava --> blood circulation
-indirect trip to the liver
[image][image] |
|
|
Term
| general depiction of what happens with micelles and lipids in lipid absorption |
|
Definition
indirect trip to the liver
[image] |
|
|
Term
|
Definition
| In blood, lipids + apolipoproteins = lipoproteins |
|
|
Term
|
Definition
| hydrolyzes triglycerides --> free fatty acids + glycerol supplied to tissues |
|
|
Term
| what happens to chylomicrons in the bloodstream? |
|
Definition
| In capillary endothelium of adipose tissue, LPL hydrolyzes triglycerides in chylomicrons --> free fatty acids and glycerol to store in the fat cells |
|
|
Term
| what happens to what's left of the chylomicrons after hydrolysis? |
|
Definition
| After hydrolysis, chylomicron remnants containing cholesterol are taken to the liver. Liver synthesizes and adds cholesterol and triglycerides. |
|
|
Term
| Very low-density lipoprotein (VLDL) |
|
Definition
| triglycerides and cholesterol + apolipoproteins leave liver to deliver triglycerides to organs. |
|
|
Term
| how VLDL gets converted to LDL |
|
Definition
| As triglycerides are removed, VLDLs --> intermediate-density lipoprotein (IDL) --> low-density lipoprotein (LDL). ↓ in triglyceride and ↑ in cholesterol and apolipoproteins content. |
|
|
Term
| low-density lipoprotein (LDL) |
|
Definition
transport cholesterol to organs. “Bad cholesterol.”
[image] |
|
|
Term
| what happens to excess cholesterol? |
|
Definition
| returned to liver on HDL to prevent atherosclerosis |
|
|
Term
| high-density lipoprotein (HDL) |
|
Definition
Excess cholesterol is returned to the liver on high-density lipoproteins (HDL), thus preventing atherosclerosis. “Good cholesterol.”
[image] |
|
|
Term
| the types of lipoproteins that can be in chylomicrons |
|
Definition
|
|
Term
| the lipoproteins with the most triglycerides |
|
Definition
|
|
Term
| table summarizing the lipoproteins involved in transport of lipids |
|
Definition
|
|
Term
| the structure of a lipoprotein |
|
Definition
|
|
Term
| depiction of the major pathways of lipid metabolism |
|
Definition
|
|
Term
|
Definition
hardening of arteries
-the most common form is atherosclerosis
[image] |
|
|
Term
|
Definition
the most common form of arteriosclerosis (hardening of the arteries)
[image] |
|
|
Term
| the pathway that leads to atherosclerosis |
|
Definition
| Arterial endothelial cells contain LDL Receptors --> LDL-LDL R’ --> endocytosis --> oxidized LDL --> oxidative damage and inflammatory response --> formation of atheroma --> atherosclerosis
[image] |
|
|
Term
|
Definition
localized plaques of fat that protrude into lumen of arteries
[image] |
|
|
Term
| how atheromas clog arteries |
|
Definition
Atheromas (localized plaques of fat) protrude into lumen of arteries --> ↓ blood flow --> … --> ↑ clot formation
[image] |
|
|
Term
| substances that can reduce the oxidation of LDL |
|
Definition
| Antioxidants, such as vit C, E, and beta-carotene |
|
|
Term
| do arterial endothelial cells contain HDL or LDL receptors? |
|
Definition
|
|
Term
| the pathway explaining what HDL does with cholesterol |
|
Definition
| HDL carries cholesterol to liver --> formation of bile in liver that contains bile salts and cholesterol --> eliminates excessive cholesterol from the body |
|
|
