Cfrn Review

Front 1

10 mmHg change in PaCO2 will cause what change in pH

Back 1

Inverse change in pH of 0.08

Front 2

A 0.1 change in pH will cause what change in Potassium (K+)

Back 2

Inverse change in Potassium (K+) of 0.6

Front 3

A 10 mmHg in PaCO2 will cause what change in Potassium

Back 3

A correlating change in Potassium (K+) of 0.5

Front 4

Diastolic Heart Failure

Back 4

Ventricles fail to adequately fill prior to systole

Front 5

Systolic Heart Failure

Back 5

Ventricles fail to clear

Front 6

Graham's Law

Back 6

The rate of diffusion of a gas through a liquid medium is directy proportional to the solubility of the gas and inversely proportional to the square root of its density.

Front 7

Dalton's Law

Back 7

The total pressure of a gas mixture is the sum of the partial pressures of the gases in the mixture.

Front 8

Charles' Law

Back 8

At a constant pressure, the volume of gas is directly proportional to the absolute temperature of the gas.

Front 9

Gay-Lussac's Law

Back 9

The pressure of a fixed volume of gas is directly proportional to its temperature in kelvins.

Front 10

Henry's Law

Back 10

The quantity of gas dissolved in 1 ml of liquid is proportional to the partial pressure of the gas in contact with the liquid.

Front 11

Borh Effect

Back 11

In the presence of CO2, the oxygen affinity of hemoglobin decreases.

Causing a right shift in the oxyhemoglobin dissociation curve.

Front 12

Haldane Effect

Back 12

Deoxygenation of the blood increases its ability to carry carbon dioxide

Conversely, oxygentated blood has a reduced capacity for carbon dioxide.

Front 13

Oxygen Adjustment Calculation

Back 13

(%IO2 x P1) = % IO2 needed
____________
P2

Front 14

Pediatric Maintenance Fluids

Back 14

4ml/kg for the first 10 kg
2ml/kg for the second 10 kg
1ml/kg for every kg after 20

Front 15

10 mmHg change in PaCO2 will cause what change in pH

Back 15

Inverse change in pH of 0.08

Front 16

A 0.1 change in pH will cause what change in Potassium (K+)

Back 16

Inverse change in Potassium (K+) of 0.6

Front 17

A 10 mmHg in PaCO2 will cause what change in Potassium

Back 17

A correlating change in Potassium (K+) of 0.5

Front 18

Diastolic Heart Failure

Back 18

Ventricles fail to adequately fill prior to systole

Front 19

Systolic Heart Failure

Back 19

Ventricles fail to clear

Front 20

Graham's Law

Back 20

The rate of diffusion of a gas through a liquid medium is directy proportional to the solubility of the gas and inversely proportional to the square root of its density.

Front 21

Dalton's Law

Back 21

The total pressure of a gas mixture is the sum of the partial pressures of the gases in the mixture.

Front 22

Charles' Law

Back 22

At a constant pressure, the volume of gas is directly proportional to the absolute temperature of the gas.

Front 23

Gay-Lussac's Law

Back 23

The pressure of a fixed volume of gas is directly proportional to its temperature in kelvins.

Front 24

Henry's Law

Back 24

The quantity of gas dissolved in 1 ml of liquid is proportional to the partial pressure of the gas in contact with the liquid.

Front 25

Borh Effect

Back 25

In the presence of CO2, the oxygen affinity of hemoglobin decreases.

Causing a right shift in the oxyhemoglobin dissociation curve.

Front 26

Haldane Effect

Back 26

Deoxygenation of the blood increases its ability to carry carbon dioxide

Conversely, oxygentated blood has a reduced capacity for carbon dioxide.

Front 27

Oxygen Adjustment Calculation

Back 27

(%IO2 x P1) = % IO2 needed
____________
P2

Front 28

Pediatric Maintenance Fluids

Back 28

4ml/kg for the first 10 kg
2ml/kg for the second 10 kg
1ml/kg for every kg after 20

Front 29

Chloride

Back 29

99 - 111 meq/l

Front 30

Magnesium

Back 30

1.8 - 2.4

Front 31

Creatnine

Back 31

0.6 - 1.3

Front 32

Serum Sodium

Back 32

137 - 150

Front 33

Hematocrit

Back 33

Male: 42 - 52

Female: 37 - 47

Front 34

Hemoglobin

Back 34

Male: 14 - 18

Female: 12 - 16

Front 35

RBC

Back 35

Male: 4.7 - 6.1

Female: 4.2 - 5.4

Front 36

Platelets

Back 36

150 - 450

Front 37

Ionized Calcium

Back 37

4.7 - 5.1

Front 38

Serum Calcium

Back 38

8.5 - 10.2

Front 39

Potassium

Back 39

3.5 - 5.0

Front 40

BUN

Back 40

10 - 23

Front 41

Brown-Sequard Syndrome

Back 41

Hemisection of the cord

Ipsilateral loss of pain, motor, + vibratory sense.

Contralateral loss of pain + temperature perception.

Front 42

Central Cord Syndrome

Back 42

Greater motor weakness in upper extremities than in lower extremities with varying degrees of sensory loss.

Front 43

Anterior Cord Syndrome

Back 43

Complete motor, pain, + temporary loss below the lesion with sparing of proprioception, vibration, + touch.

Front 44

Variable FHR Decelartions

Back 44

Cord Compression

Front 45

Late FHR Decelartions

Back 45

Uteroplacental insufficiency - inadequate oxygenation exchange within the placenta during contraction.

Front 46

Sinusoidal FHR

Back 46

Fetal hypovolemia or anemia

Immediate delivery

Front 47

FHR Bradycardia

Back 47

FHR < 120 for 5 - 10 minutes

Front 48

Pulmonary Cappillary Wedge Pressure

Back 48

5 - 12 mmHg

Front 49

PA Cath Pressures

Back 49

Systolic = 20 - 30 mmHg

Diastolic = 5 - 10 mmHg

Front 50

CFRN Review

Back 50

Certified Flight Registered Nurse