Exploring Flow & Time Constants in the mode of Pressure Control

preview_player
Показать описание
Demonstration & explanation of the effects of altering mechanical ventilator controls and patient factors in the mode of pressure control.
  1. Allan Prost
  2. Mechanical Ventilation
  3. Pressure Control Ventilation
  4. Time Constants
  5. Respiratory Therapy
Рекомендации по теме
Exploring Flow & 0:20:08

Exploring Flow & Time Constants in the mode of Pressure Control

ICU Training: Lung 0:02:19

ICU Training: Lung Mechanics - The Expiratory Time Constant

Time constant on 0:01:33

Time constant on ventilator || Calculation of TC

Respiratory Therapy - 0:08:21

Respiratory Therapy - Time Constant

7 Compliance, Resistance 0:23:14

7 Compliance, Resistance & Time Constant

Respiratory physiology lecture 0:22:26

Respiratory physiology lecture 4 - Time constants, elastic properties of lung and closing capacity

Resistance and time 0:00:32

Resistance and time constant

Respiratory Time Constant 0:16:36

Respiratory Time Constant (Tau)

Time Is an 0:07:56

Time Is an Illusion: Scientists Claim Time Isn’t What We Perceive

2.17 The Time 0:09:52

2.17 The Time Constant Tau

Time constant | 0:00:42

Time constant | meaning of Time constant

Compliance and time 0:00:41

Compliance and time constant

Path exploration in 0:12:39

Path exploration in Google Analytics 4 | Behavior Flow in GA4

COPD Ventilation Physiology 0:16:04

COPD Ventilation Physiology ~ Time Constant & Pride's Waterfall concept

Respiratory time constant 0:19:06

Respiratory time constant

What is Rise 0:01:05

What is Rise time on ventilator?

Basics of Mechanical 0:42:27

Basics of Mechanical Ventilation Part 3: Flow

How Time Works: 0:02:02

How Time Works: the Secrets of Time's Flow

Circuit Theory in 0:07:22

Circuit Theory in the Lab: Time Constants in Discharging RC Circuits

⚡Current Affairs: Exploring 0:00:43

⚡Current Affairs: Exploring the Flow of Electricity!⚡

Inspiratory time is 0:01:32

Inspiratory time is too long

Time Is an 0:11:23

Time Is an Illusion: Scientists Say Time Doesn’t Exist in the Way We Think

Case 68 how 0:09:21

Case 68 how to calculate time constant( CXR ) compliance x resistance, (RDS short TC) MAS (LONG TC

Understanding I time, 0:20:49

Understanding I time, E time, TCT, and I:E ratio

Комментарии
Автор

Mr. Prost, I enjoyed this very much! Nicely done!

dougchism
Автор

Nice presentation..Very simplified, thankyou

rajasekharthottadi
Автор

With a size 6.0 ETT, you obviously have higher resistance and, consequently, more turbulent flow through the ETT tube. Therefore, P(lung) of the lungs would reach P(mouth) much later, with a size 6.0 ETT. P(lung ) would reach P(mouth) faster with a 8.0 ETT. You can see the inspiratory pause for a size 6.0 ETT is shorter than the inspiratory pause for a size 8.0 ETT. The lungs spend more time at P(mouth pressure) with an 8.0 ETT than that of a 6.0 ETT: therefore, a smaller tidal volume for a 6.0 ETT and a larger tidal volume for a 8.0 ETT.

christams
Автор

i dont understand how you're getting the resitance to calculate flow. To calculate flow we got the change in pressure by subtracting Pmouth and Plung but what value are we using to calculate the resistance to divide.

marcopolo
Автор

Please, make video about forced oscillation technique in ventilation

ДенисЮденков-ьж
Автор

Hi dear, in Simv mode if set RR is 12 and patients takes 14 breathes of his own... than how many breathes will receive the set vt?

paediatriciandoctorzahidhu