26.5.16

HIGHEST Yield Pearls for MRCP 1 2 & PACES

HIGHEST Yield Pearls for MRCP 1 2 & PACES

1) Hepatitis "D" Virus has HIGHEST mortality in ALL people EXCEPT#Pregnancy.
In Pregnant women: MOST LETHAL is Hepatitis E virus.
2) "While calculating Serum Osmolality the serum Na is multiplied by 2 to account for the accompanying ANIONS (mostly Cl- & HCO3-)."
3) Most Common cause of Metastasis to LIVER is primary cancers of Lung.
LLLLLungs send metastasis to LLLLLLiver.
4) Ketamine is the ONLY induction agent that causes Bronchodilation.
Again:
Ketamine is the ONLY induction agent that causes Bronchodilation.
5) AANNencephaly: failure of AANNterior neuropore to close.(at day 25)
SSSpinda bifida: failure of poSSSterior neuropore to close.(at day 27)
6) Muscle Spindles: Innervated by 1a fibers - cause skeletal muscle to CONTRACT.
GTOs: innervated by 1b - cause contracting muscle to RELAX
7) In SSSpontaneous pneumothorax: trachea shifts to ipSSSilateral side.
In TTTension pneumothorax: trachea deviates to conTTTralateral side.
8) Antibiotics SAFE in pregnancy:
All Penicillins.
All Cephalosporins.
All Carbapenems.
Aztreonam.
Azithromycin.
Nitrofurantoin (Avoid in last trimester bcoz can cause hemolysis in G6PD deficient fetus).
Metronidazole (SAFE in ALL trimesters).

23.5.16

Free Exam Resources for doctors

Following are free resources for exam Practice
Specefically MRCP, PLAB, MRCGP and clinical revision

MRCPass

• Notes on topics covered in MRCP Part 1
• 130 MCQ questions
• Bookmark questions
• Choose questions by topic
• Track statistics
• Look back over wrong answers

Revise MRCP

• Covers MRCP Parts 1 and 2
• Over 5,000 MCQs arranged by topic
• Free to sign up
• Past papers going back to September 2010

Medexam.net 

• Over 1,800 MCQs with detailed answers

14.5.16

The Only MRCP Notes you will ever need 5th Edition: 2015 Edition

The Only MRCP Notes you will ever need 5th Edition


This is a solid book for consolidating your knowledge before the exam, Most of the data is updated than the 4th edition, But still few topics you should see through Passmedicine.com like ACS, STROKE, ARRHYTHMIA management. 

Also latest Treatment for diabetes according to NICE December 2015 guidelines 

Terminology of Acid-Base Disorders

Definitions

The definitions of the terms used here to describe acid-base disorders are those suggested by the Ad-Hoc Committee of the New York Academy of Sciences in 1965. Though this is over 35 years ago, the definitions and discussion remain valid today.


Basic Definitions

  • Acidosis - an abnormal process or condition which would lower arterial pH if there were no secondary changes in response to the primary aetiological factor.
  • Alkalosis - an abnormal process or condition which would raise arterial pH if there were no secondary changes in response to the primary aetiological factor.
  • Simple (Acid-Base) Disorders 1 are those in which there is a single primary aetiological acid-base disorder.
  • Mixed (acid-Base) Disorders 2,3 are those in which two or more primary aetiological disorders are present simultaneously.
  • Acidaemia - Arterial pH < 7.36 (ie [H+] > 44 nM )
  • Alkalaemia - Arterial pH > 7.44 (ie [H+] < 36 nM )

Regulation of Intracellular Hydrogen Ion Concentration

Importance of Intracellular [H+]

The most important [H+] for the body is the intracellular [H+]

Why? Because of its profound effects on metabolism and other cell processes which occur due to the effects of [H+] on the degree of ionisation of intracellular compounds. Specifically:
  • Small molecule effect: Intracellular trapping function -due to the ionisation of metabolic intermediates.
  • Large molecule effect: Effects on protein function: The function of many intracellular proteins (esp the activities of enzymes) is altered by effects on the ionisation of amino acid residues (esp histidine residues)

Renal Regulation of Acid-Base Balance

Renal Regulation of Acid-Base Balance

The organs involved in regulation of external acid-base balance are the lungs are the kidneys.
The lungs are important for excretion of carbon dioxide (the respiratory acid) and there is a huge amount of this to be excreted: at least 12,000 to 13,000 mmols/day.
In contrast the kidneys are responsible for excretion of the fixed acids and this is also a critical role even though the amounts involved (70-100 mmols/day) are much smaller. The main reason for this renal importance is because there is no other way to excrete these acids and it should be appreciated that the amounts involved are still very large when compared to the plasma [H+] of only 40 nanomoles/litre.
There is a second extremely important role that the kidneys play in acid-base balance, namely the reabsorption of the filtered bicarbonate. Bicarbonate is the predominant extracellular buffer against the fixed acids and it important that its plasma concentration should be defended against renal loss.
In acid-base balance, the kidney is responsible for 2 major activities:
  • Reabsorption of filtered bicarbonate: 4,000 to 5,000 mmol/day
  • Excretion of the fixed acids (acid anion and associated H+): about 1 mmol/kg/day.
Both these processes involve secretion of H+ into the lumen by the renal tubule cells but only the second leads to excretion of H+ from the body.
The renal mechanisms involved in acid-base balance can be difficult to understand so as a simplification we will consider the processes occurring in the kidney as involving 2 aspects:
  • Proximal tubular mechanism
  • Distal tubular mechanism

Respiratory Regulation of Acid-Base Balance: Acid Base Learner Series

How is the Respiratory System Linked to Acid-base Changes?

‘Respiratory regulation’ refers to changes in pH due to pCO2 changes from alterations in ventilation. This change in ventilation can occur rapidly with significant effects on pH. Carbon dioxide is lipid soluble and crosses cell membranes rapidly, so changes in pCO2 result in rapid changes in [H+] in all body fluid compartments.
A quantitative appreciation of respiratory regulation requires knowledge of two relationships which provide the connection between alveolar ventilation and pH via pCO2. These 2 relationships are:
  • First equation - relates alveolar ventilation (VA) and pCO2
  • Second equation - relates pCO2 and pH.

Acid Base Learner Series: Buffers

Definition of a Buffer

A buffer is a solution containing substances which have the ability to minimise changes in pH when an acid or base is added to it 1.
A buffer typically consists of a solution which contains a weak acid HA mixed with the salt of that acid & a strong base eg NaA. The principle is that the salt provides a reservoir of A- to replenish [A-] when A- is removed by reaction with H+.

Buffers in the Body

The body has a very large buffer capacity.

This can be illustrated by considering an old experiment (see below) where dilute hydrochloric acid was infused into a dog.

Acid Base Physiology: Acid Base Learner Series

Acid Base Physiology
Each day there is always a production of acid by the body’s metabolic processes and to maintain balance, these acids need to be excreted or metabolised. The various acids produced by the body are classified as respiratory (or volatile) acids and as metabolic (or fixed) acids. The body normally can respond very effectively to perturbations in acid or base production.

Respiratory Acid

The acid is more correctly carbonic acid (H2CO3) but the term 'respiratory acid' is usually used to mean carbon dioxide. But CO2 itself is not an acid in the Bronsted-Lowry system as it does not contain a hydrogen so cannot be a proton donor. However CO2 can instead be thought of as representing a potential to create an equivalent amount of carbonic acid. Carbon dioxide is the end-product of complete oxidation of carbohydrates and fatty acids. It is called a volatile acid meaning in this context it can be excreted via the lungs. Of necessity, considering the amounts involved there must be an efficient system to rapidly excrete CO2.
The amount of CO2 produced each day is huge compared to the amount of production of fixed acids. Basal CO2production is typically quoted at 12,000 to 13,000 mmols/day.
Basal Carbon Dioxide Production
Consider a resting adult with an oxygen consumption of 250 mls/min and a CO2 production of 200 mls/min (Respiratory quotient 0.8):

Daily CO2 production
= 0.2 x 60 x 24 litres/day divided by 22.4 litres/mole
= 12,857 mmoles/day.

Increased levels of activity will increase oxygen consumption

Manchester Metropolitan Postgraduate Courses Fairs


Postgraduate Courses for 2016 entry
At the event you will be able to attend subjects sessions, meet staff, pick up a prospectus and find out about postgraduate loans.
The Faculty of Humanities, Languages and Social Science is also pleased to announce we will be offering sixteen scholarships to assist students with financing their Masters studies. Students applying for full or part-time study on any taught Masters Programmes in the Faculty are eligible for these scholarships which will pay 50% of the fees
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