Showing posts with label Vascular pathology. Show all posts
Showing posts with label Vascular pathology. Show all posts

Monday, January 3, 2022

Clinical pearl: Retroperitoneal hematoma


Vascular access during cardiac catheterization (in cases of myocardial infarction, for example) obtained through femoral artery above the level of inguinal ligament may lead to retroperitoneal hematoma due to arterial puncture.

Tuesday, May 19, 2020

High-yield : Risk of stroke with cardioversion


Electrical/chemical cardioversion performed in a case of atrial fibrillation may carry a high-risk of stroke, especially if >48 hours of time has passed (thrombus formation takes about 48 hours).

Monday, March 30, 2020

Rickettsia mnemonic


Do you want to learn about Rickettsia today?

Rickettsia mnemonic (Rickettsia typhi, flea vector)

Friday, November 8, 2019

Thursday, March 21, 2019

Catheter Removal Timing

Removal — Following diagnosis of catheter-related infection, catheter removal is warranted in the following circumstances :

●Severe sepsis

●Hemodynamic instability

●Endocarditis or evidence of metastatic infection

●Erythema or exudate due to suppurative thrombophlebitis

●Persistent bacteremia after 72 hours of antimicrobial therapy to which the organism is susceptible

Source :Uptodate

Bhopalwala. H

Monday, March 18, 2019

Right to left shunt causing Hypoxemia

A right-to-left shunt exists when blood passes from the right to the left side of the heart without being oxygenated. There are two types of right-to-left shunts:

●Anatomic shunts exist when the alveoli are bypassed. Examples include intracardiac shunts, pulmonary arteriovenous malformations (AVMs), and hepatopulmonary syndrome.

●Physiologic shunts exist when non-ventilated alveoli are perfused. Examples include atelectasis and diseases with alveolar filling (eg, pneumonia, acute respiratory distress syndrome).

Right-to-left shunts cause extreme V/Q mismatch, with a V/Q ratio of zero in some lung regions. The net effect is hypoxemia, which is difficult to correct with supplemental oxygen.

The degree of shunt can be quantified from the shunt equation:

Qs/Qt  =  (CcO2  -  CaO2)  ÷  (CcO2  -  CvO2)

where Qs/Qt is the shunt fraction, CcO2 is the end-capillary oxygen content, CaO2 is the arterial oxygen content, and CvO2 is the mixed venous oxygen content. CaO2 and CvO2 are calculated from arterial and mixed venous blood gas measurements, respectively. CcO2 is estimated from the PAO2.

Source: UpToDate

Bhopalwala. H