The respiratory zone is where gas exchange occurs and this area is made up of respiratory bronchioles, alveolar ducts, and alveoli

The conduction zone is the path air travels and is made up of the nose, nasal cavity, pharynx, larynx, trachea, bronchi, terminal bronchioles

Aorta --> renal artery --> segmental artery --> interlobar artery --> arcuate artery --> cortical radiate artery --> afferent arterioles --> glommy --> efferent arterioles --> peritubular capillaries --> cortical radiate veins --> arcuate veins --> interlobar veins --> renal vein --> IVC

PG- the changing of the pressures from the outside and inside of the lungs is what facilitates airflow. When the lung pressure decreases below atm, air flows down the pressure gradient into the lungs. If gradient increases, airflow increases

R- decreases in elasticity = increase resistance. Bronchoconstriction increases R. You need less resistance to increase airflow

A- released in response to hyponatremia, hyperkalemia or RAAS (low bp or bv) and works to increase sodium reabsorption in the DCT. Promotes secretion of K+ to help maintain balance. 

ADH- released in response to increased blood osmolarity or low BV or BP it acts to increase permeability of collecting ducts by adding more aqua ducts. This will concentrate the urine

Atelectasis (or RDS)

a. holds the visceral and parietal
pleural membranes together

Podocytes

ATM- pressure in the air, usually 760 mmHg

Alveolar (intrapulmonary)- pressure in the alveoli. During inhalation becomes negative in relation to atm to allow air in. Inhalation is active using external intercostals and diaphragm

Intrapleural- pressure within pleural cavities and it is always negative in relation to atm to keep lungs open. Doesn't really change with breathing

The negative intrapleural pressure creates a suction effect that keeps the lungs inflated against the thoracic wall. During inhalation, as the thoracic cavity expands, intrapleural pressure becomes more negative, enhancing the transpulmonary pressure and promoting lung expansion. 

Equalization = collapse

a. the end of the proximal tubule

4, 3, 1, 2

The alveoli and capillaries form the respiratory membrane. This is a very thin membrane which is good because it allows for fast and efficient gas exchange. There are so many alveoli that the surface area available for gas exchange is so high.

T1- make up a majority of alveolar surface and do the gas exchange

T2- mixed around T1 and produce surfactant which reduces surface tension to prevent alveoli from collapsing

RC- covering that protects the kidney and works to maintain shape and fight infection

C- outer region and contains nephrons and help to filter blood and form urine

M- inner region of kidney containing renal pyramids. concentrates urine

S- where pelvis, calyces, and blood vessels are

P- collects urine from calyces and transports it to ureter

H- blood vessels, nerves, and ureter enter and exit

P- tips of the pyramids that go into minor calyces and where urine drains into calyces

Calyces- drain urine. Minor feeds into major which feeds into pelvis

Central chemoreceptors- in the medulla and monitor pH of CSF

Peripheral chemoreceptors- in aorta and carotid arteries and stimulated by changes in H+

Ex: ventilation increases when PC detect increase H+ or PCO2

Glomerular hydrostatic (HPg)- BP in glommy it pushes water and solutes out into capsular space. Higher BP than in other capillaries

Blood colloid osmotic (OPg)- exerted by dissolved solutes and they oppose filtration to draw fluid back into glommy

Capsular hydrostatic (HPc)- pressure in glommy capsule due to filtrate and it impedes additional fluid movement

a. hemoglobin