Capnography Simplified


by rjjaramillo
This is a repost from Jeremy Jaramillo’s Blog . Its a nice resource. Do visit it at

Capnography (end-tidal CO2 monitoring) is a non-invasive measurement of carbon dioxide in exhaled air to assess a patients’ ventilatory status. It may also be referred to as partial pressure end tidal carbon dioxide monitoring (PETCO2). The end-tidal CO2 (EtCO2) level is a reflection of global CO2 production in the body. Cardiac function, pulmonary function, and metabolic rate all influence the amounts of CO2 produced. The end-tidal CO2 provides information on systemic CO2 production (from exhaled alveolar gas), pathologic dead space, pulmonary blood flow, and confirmation of endotracheal tube placement. Capnography allows trending of CO2 levels using fewer arterial blood gas analyses, but does not completely replace arterial blood gas analysis. Age, smoking, general anesthesia, and systemic diseases can increase the difference between the CO2 value obtained from non-invasive monitoring and arterial blood gas monitoring. Note that capnography measures ventilation, not oxygenation.

Comparison of Capnography and Pulse Oximetry
Capnography Pulse Oximetry
Measures CO2 Measures oxygen saturation
Reflects ventilation Reflects oxygenation
Hypoventilation / apnea detected immediately Changes lag with hypoventilation / apnea
Should be used with pulse oximeter Should be used with capnography

Maintenance of a patient’s airway is always a primary patient care objective. If the airway
patency is lost, no other treatment modalities can prevent death.


  1. Alveolar Dead Space: When gas exchange doesn’t occur because air is present, but no blood is available to exchange gas. Or there is blood but no air. It could also be because the exchange surface is compromised by pulmonary edema, pulmonary effusion, or swollen membranes
  2. Alveolar volume (Va) – Air that is available for gas exchange, which is typically about 350 cc (Vt – Vd = Va); Anything that affects the tidal volume only affects the alveolar volume.
  3. Anatomical Dead Space (Vd) – Air not available for gas Exchange, which is typically about 150 cc
  4. Bradypnea – slower than normal rate (<10 breaths/min), with normal depth and regular rhythm. Associated with ICP, brain injury, and drug overdose.
  5. Capnogram – the wave form.
  6. Capnography – the measurement of carbon dioxide (CO2) in exhaled breath.
  7. Capnometer – the numeric measurement of CO2.
  8. Dyspnea – air hunger, difficult or labored breathing, shortness of breath
  9. End Tidal CO2 (ETCO2 or PetCO2) – the level of (partial pressure of) carbon dioxide released at end of expiration. Normal values range between 35 and 45 mmHg
  10. Hyperventilation – Increased rate and depth of breathing that results in decreased PaCO2 level. Fast breathing (tachypnea) doesn’t necessarily increase tidal volume, which can be caused by anxiety, head injuries, diabetic emergencies, PE, AMI, and others
  11. Hypoventilation – Shallow, irregular breathing. Slow breathing (bradypnea) does not necessarily decrease tidal volume. Causes include CNS disorders, narcotic use and others.
  12. PACO2 – Partial pressure of CO2 in the alveoli.
  13. PaCO2 – Partial pressure of CO2 in arterial blood.
  14. PCO2 – Partial pressure of CO2 in the blood
  15. PETCO2 – Partial pressure of CO2 at the end of expiration. ~ 38 mm Hg (usually 1 – 6 mm Hg less than PaCO2)
  16. (a-ET)PCO2 – Arterial to end-tidal CO2 tension/pressure difference or gradient.
  17. PvCO2 – Partial pressure of CO2 in mixed venous blood.
  18. Physiologic Dead Space – is the alveolar gas that does not equilibrate fully with capillary blood. In normal subjects, dead space ventilation (VD) accounts for 20 to 30% of the total ventilation (VT), so VD/VT = 0.2 to 0.3
  19. Respiration (or diffusion) is measured by the amount of oxygen in the blood.
  20. Tachypnea – rapid, shallow breathing (>24 breaths/min). Associated with pneumonia, pulmonary edema, metabolic acidosis, septicemia, severe pain, or rib fracture.
  21. Tidal Volume (Vt) – The amount of air moved in one breath, which is typically around 500 cc in an adult at rest
  22. Ventilation is measured by the amount of carbon dioxide in the blood.


Upper and Lower Airways


The Lungs

The lungs are cone-shaped organs that hold between 4 – 8 liters of volume. The top portion is known as the apex, and the bottom is known as the base. The apex of each lung rises above the clavicles a few centimeters and the base rests against the diaphragm. The right lung has 3 lobes: upper, middle, and lower. The left has two lobes: upper and lower.



Aspiration pneumonias are often located in the right middle lobe due to the shorter, straighter right mainstem bronchus.

The Diaphragm

The diaphragm is the major muscle of ventilation. It is a dome-shaped musculofibrous partition located between the thoracic and abdominal cavities. It is composed of two muscles: the right and left hemidiaphragms. The diaphragm allows the esophagus, the aorta, several nerves, and the inferior vena cava to exit through it. The phrenic nerve exits the central nervous system between cervical vertebrae 3 – 5 and extends down to innervate the diaphragm assisting in controlling ventilation.



Patients with cervical spine injuries of C3, C4 and C5 are often dependent on mechanical ventilation. This is due to interruption of nerve transmission to the diaphragm and other ventilatory muscles.

Accessory muscles of ventilation

During vigorous exercise and the advanced stages of pulmonary disease processes (e.g. COPD) the accessory muscles of inspiration and expiration are activated to assist the diaphragm.

Muscles of Inspiration (I) Muscles of Expiration (E)
Scalene muscles Rectus abdominis muscles
Sternocleidomastoid muscles External abdominal obliquus muscles
Pectoralis major muscles Internal abdominis obliquus muscles
Trapezius muscles Transversus abdominis muscles
External intercostal muscles Internal intercostal muscles

PaCO2 Equation – PaCO2 reflects ratio of metabolic CO2 production to alveolar ventilation

The PCO2 equation puts into physiologic perspective one of the most common of all clinical observations: a patient’s respiratory rate and breathing effort. The equation states that alveolar PCO2 (PACO2) is directly proportional to the amount of CO2 produced by metabolism and delivered to the lungs (VCO2) and inversely proportional to the alveolar ventilation (VA). While the derivation of the equation is for alveolar PCO2, its great clinical utility stems from the fact that alveolar and arterial PCO2 can be assumed to be equal. Thus,


PaCO2 Condition in Blood State of Alveolar Ventilation
> 45 mm Hg Hypercapnia Hypoventilation
35 – 45 mm Hg Eucapnia Normal ventilation
< 35 mm Hg Hypocapnia Hyperventilation

The constant 0.863 is necessary to equate dissimilar units for VCO2 (ml/min) and VA (L/min) to PACO2 pressure units (mm Hg). Alveolar ventilation is the total amount of air breathed per minute (VE; minute ventilation) minus that air which goes to dead space per minute (VD). Dead space includes all airways larger than alveoli plus air entering alveoli in excess of that which can take part in gas exchange.


In the clinical setting we don’t need to know the actual amount of CO2 production or alveolar ventilation. We just need to know if VA is adequate for VCO2; if it is, then PaCO2 will be in the normal range (35-45 mm Hg). Conversely, a normal PaCO2 means only that alveolar ventilation is adequate for the patient’s level of CO2 production at the moment PaCO2 was measured.  From the PCO2 equation it is evident that a level of alveolar ventilation inadequate for CO2 production will result in an elevated PaCO2 (> 45 mm Hg; hypercapnia). Thus patients with hypercapnia are hypoventilating (the term hypoalveolar ventilating would be more appropriate but hypoventilating is the conventional term). Conversely, alveolar ventilation in excess of that needed for CO2 production will result in a low PaCO2 (< 35 mm Hg; hypocapnia) and the patient will be hyperventilating. (Confusion sometimes arises because the prefix (hyper-, hypo-) differs for the same condition depending on whether one is describing a blood value or the state of alveolar ventilation.) For reasons that will be discussed below, the terms hypo- and hyper- ventilation refer only to high or low PaCO2, respectively, and should not be used to characterize any patient’s respiratory rate, depth, or breathing effort.

From the PCO2 equation it follows that the only physiologic reason for elevated PaCO2 is a level of alveolar ventilation inadequate for the amount of CO2 produced and delivered to the lungs. Thus arterial hypercapnia can always be explained by:

  1. Not enough total ventilation (as may occur from central nervous system depression or respiratory muscle weakness); or
  2. Too much of the total ventilation ending up as dead space ventilation (as may occur in severe chronic obstructive pulmonary disease, or from rapid, shallow breathing); or
  3. Some combination of 1) and 2).

Excess CO2 production is omitted as a specific cause of hypercapnia because it is never a problem for the normal respiratory system unimpeded by a resistive load. During submaximal exercise, for example, where CO2 production is increased, PaCO2 stays in the normal range because VA rises proportional to the rise in VCO2. With extremes of exercise (beyond anaerobic threshold) PaCO2 falls as compensation for the developing lactic acidosis. In a healthy patient PaCO2 may be reduced but is never elevated.

An important clinical corollary of the PaCO2 equation is that we cannot reliably assess the adequacy of alveolar ventilation – and hence PaCO2 – at the bedside. Although VE can be easily measured with a handheld spirometer (as tidal volume times respiratory rate), there is no way to know the amount of VE going to dead space or the patient’s rate of CO2 production. Other clinical factors include respiratory effort, mental status, body habitus, temperature, etc.

A common mistake is to assume that because a patient is breathing fast, hard and/or deep he or she must be “hyperventilating.” Not so, of course.









PCO2 vs. Alveolar Ventilation

The relationship is shown for metabolic carbon dioxide production rates of 200 ml/min and 300 ml/min (curved lines). A fixed decrease in alveolar ventilation (x-axis) in the hypercapnic patient will result in a greater rise in PaCO2 (y-axis) than the same VA change when PaCO2 is low or normal.
This graph also shows that if alveolar ventilation is fixed, an increase in carbon dioxide production will result in an increase in PaCO2.


Effect of Increasing Arterial PCO2 or Reducing pH on Ventilation

Guyton & Hall, Textbook of Medical Physiology, 10th ed., 2000, Saunders p. 477.


The effect of PCO2 on ventilation is primarily due to a region of the ventral medulla referred to as the chemosensitive area. In this area, there are sensor neurons that are excited by hydrogen ions. As arterial PCO2 rises, CO2 easily and rapidly diffuses through the blood brain barrier where it combines with water to form carbonic acid which releases a hydrogen ion. So, the net effect of increased arterial PCO2 is increased cerebrospinal fluid (CSF) and brain interstitial acidity. This strongly stimulates these sensor neurons which stimulate the respiratory centers to increase ventilation (this will tend to reduce the arterial PCO2 back to baseline).

Hydrogen ions themselves do not diffuse as easily across the blood brain barrier making the direct effect of pH less. The effect of PCO2 on ventilation is strongest in the acute phase. If the person has a high PCO2 for a prolonged period (days or longer, perhaps due to a lung or neurological problem), the pH of the CSF tends to return toward normal because of adaptive effects related to bicarbonate. The person becomes accustomed to the higher PCO2 and it causes less stimulus to hyperventilate.

Ventilation Increases as PaO2 Decreases at Constant PaCO2

Guyton & Hall, Textbook of Medical Physiology, 10th ed., 2000, Saunders p. 479.


Integrated Effects of PCO2, PO2 & pH on Alveolar Ventilation

Guyton & Hall, Textbook of Medical Physiology, 10th ed., 2000, Saunders p. 479.



Currently, there are 2 basic types of CO2 detectors: quantitative and qualitative.

  1. Qualitative CO2 detectors are colorimetric detectors that contain material that reversibly reacts with CO2. This reaction causes the color to change, most commonly, from purple to yellow. Qualitative capnography units can be broken down into mainstream and sidestream configurations.
    1. Mainstream units, or in-line units, are used for ventilated patients who are intubated endotracheally. The sensor is placed directly on an adapter attached to the endotracheal tube. From there, EtCO2 can be directly measured.
    2. Sidestream units have a sensor that is located on the main unit itself. These systems aspirate the gas sample from the patient’s airway, which then measures the EtCO2. In turn, sidestream units can be used in awake or intubated patients.
  2. Quantitative CO2 detectors give a measured value of EtCO2. This numeric value is referred to as capnometry. Quantitative detectors can also be displayed as a waveform called a capnogram. This waveform of inspiratory/expiratory CO2 can be displayed over time or volume and is referred to as a capnograph.

How medical equipment works – Capnography

Levels or Phases

Information from Capnography can be broken down into levels, each with increasing degrees of information

1. Level 1

  1. Breathing or not, i.e. apnoea monitor
  2. Respiratory rate

2. Level 2

  1. Expired CO2 levels (4.5% or 35mmHg)
  2. Inspired CO2 levels (0%)
  3. From these parameters we can now begin to deduce the state of the patient with regard to respiration i.e. normocapnic, hypocapnic or hypercapnic

3. Level 3

  1. Waveform profile
  2. There are 4 recognised parts to a typical capnogram, each one having characteristics that impart specific information
  3. A typical capnogram obtained during controlled mechanical ventilation showing:
    1. i. Inspiratory baseline (A to B)
    2. ii. Expiratory upstroke (B to C)
    3. iii. Expiratory plateau (C to D)
    4. iv. Inspiratory down stroke (D to E)


Advanced Emergency Nursing Journal Vol. 28, No. 4, pp. 301–313



  1. “α” (Alpha) angle – Used to assess the Ventilation/ Perfusion (V/Q) status of lung. During mismatches, the alpha angle is > ~ 90 degrees. The more damaged and less uniform the alveoli, the larger the angle. Bronchospasm (sharkfin), COPD, etc.
  2. “β” (Beta) angle – Used to assess rebreathing. During rebreathing, the beta angle is > 90 degrees. May see in infants who are breathing faster than capnograph can account for.

A normal capnogram look like the following.


Its analysis should include the following:

  1. Verify presence of exhaled CO2
    1. Is a waveform present?
  2. Inspiratory baseline
    1. Is there rebreathing?
  3. Expiratory upstroke
    1. Is it steep, sloping, or prolonged?
  4. Expiratory plateau
    1. Is it flat, prolonged, notched, or sloping?
  5. Inspiratory down stroke
    1. Is it steep, sloping, or prolonged?
  6. Check PICO2 min and PECO2max
  7. Estimate or measure PaCO2 – PECO2 max
  8. Search for causes of hypercapnia or hypocapnia, if either is present

Clinical Application Examples of Capnography

Slap the Cap – The Role of Capnography in EMS

  1. One of two sure signs of endotracheal intubation.
    1. This is probably the most common use of capnography, yet limiting oneself to this use only is a huge waste. In the beginning, color change devices would detect CO2 levels. This is widely believed to be able to accurately predict when the endotracheal tube is misplaced in the esophagus. Theoretically, there should be no CO2 exhaled from the esophagus, on the trachea. However, in low perfusion states, this is not a very accurate reading and the manufacturer even suggests using another confirming device besides this one. Therefore, waveform capnography is the gold standard for endotracheal tube confirmation. Tube confirmation is confirmed with a SQUARE waveform. With a square waveform, the tube cannot be in the esophagus, or the hypopharynx. It must be in the trachea, regardless of the value of the return of CO2.image
    2. Right mainstem intubation. A square waveform can occur with a right mainstem intubation because the tube is still in the main airway.Therefore, auscultation in the fifth intercostal space midaxillary, bilaterally, is necessary to rule out right mainstem intubation.
  2. Detection of untoward events e.g… Disconnections or inadvertent extubation.
  3. Maintenance of normocapnia
  4. Cardiopulmonary resuscitation
    1. As an assessment tool during CPR, capnography is a direct measurement of ventilation in the lungs, and it also indirectly measures metabolism and circulation. For example, a decrease in perfusion (cardiac output) will lower the delivery of carbon dioxide to the lungs. This will cause a decrease in the ETCO2 (end-tidal CO2), and this will be observable on the waveform as well as with the numerical measurement.
    2. Two very practical uses of waveform capnography in CPR are: 1.) evaluating the effectiveness of chest compressions; and 2.) identification of ROSC. Evaluating effectiveness of chest compressions is accomplished in the following manner: Measurement of a low ETCO2 value (< 10 mmHg) during CPR in an intubated patient would indicate that the quality of chest compressions needs improvement.
    3. An abrupt increase in PETCO2 may indicate return of spontaneous circulation (ROSC), Increase in pulmonary circulation brings more CO2 into lungs for elimination.  In most cases that have ROSC the ETCO2 goes into the 70-90’s!
  5. Weaning from mechanical ventilation
  6. Monitoring the seizure patient
    1. Generalized seizure, such as a tonic/clonic, can affects both hemispheres of the brain and the medulla. When the medulla is involved, the patient may not breath during seizure activity. Following the post-ictal state capnography can determine the need for further ventilation.
  7. Metabolic Uses: DKA
    1. Since CO2 is carried in the blood stream and bicarbonate Ion, it has a
      direct clinical relationship to serum bicarb levels. Therefore, if the patient
      has a high Blood glucose, measure their ETCO2. If it is less than 29, then
      the patient has DKA. The blood gas bicarb will show a very low level as
      well, indication metabolic acidosis.
  8. Pulmonary Embolism: This is easy. The combination of ETCO2 and an ABG CO2 can easily call a V/Q mismatch. All you need then is a CT scan to figure out where it is and
    they are on their way. A high blood gas CO2 and a low ETCO2 tells us the
    CO2 is not getting to the lungs to be exhaled.
  9. Trauma?
    1. In Tension Pneumothorax, pressure in the chest collapses a lung and then
      presses on the right side of the heart making it hard to fill with blood. It
      only takes about 7mm/hg pressure to stop the blood flow into the right
      atria. The first and must reliable sign of a TENSION pneumothorax is the
      sudden drop in perfusion that is picked up immediately on a capnogram.
      By the same token, when the chest is successfully decompressed, it is not
      a rush of air but a sudden increase in ETCO2 that confirms decompression
      success. Furthermore, the capnogram can be used to keep watch in case
      it develops again.
    2. The same is true for Pericardial Tamponade and cardiocentesis. In each
      of these obstructive forms of hypoperfusion, the capnogram will remain
      square because it is a perfusion problem, not an airway problem, but you
      knew that, right?
  10. Closed Head Injury. ITLS and the Brain Trauma Foundation have taken the
    lead in recommending capnography as the way titrate CO2 ventilations in
    the patient with a closed head injury. If the patient has a GCS of less than
    9 and they are posturing, have unequal pupils, or dropped two in front of
    you, then they should be selectively ventilated to an ETCO2 between 30-
    35mm/hg. If the patient does not the signs (above) of deterioration, then
    ventilate the patient to levels, 35-45. Never ever bag them to lower than
    25mm/hg. It causes cerebral vasoconstriction and creates an alkalosis not
    allowing O2 to dissociate from hemoglobin, make the brain injury worse.
  11. Monitoring the non-intubated patient
    1. Capnography helps conscious patients too

Specific Waveforms to Know

There are a few specific waveforms that you need to know.





Capnography Outside the Operating Rooms

Kodali, Bhavani Shankar Anesthesiology. 118(1):192-201, January 2013. doi: 10.1097/ALN.0b013e318278c8b6


A, Prolonged phase II, increased α angle, and steeper phase III suggest bronchospasm or airway obstruction.

B, Expiratory valve malfunction resulting in elevation of the baseline, and the angle between the alveolar plateau and the downstroke of inspiration is increased from 90°. This is due to rebreathing of expiratory gases from the expiratory limb during inspiration.

C, Inspiratory valve malfunction resulting in rebreathing of expired gases from inspiratory limb during inspiration (reference 5 for details).

D, Capnogram with normal phase II but with increased slope of phase III. This capnogram is observed in pregnant subjects under general anesthesia (normal physiologic variant and details in reference 9).

E, Curare cleft: Patient is attempting to breathe during partial muscle paralysis. Surgical movements on the chest and abdomen can also result in the curare cleft. (You have maybe 3 minutes to sedate the patient before they begin to waken or start to fight the tube.)

F, Baseline is elevated as a result of carbon dioxide rebreathing.

G, Esophageal intubation resulting in the gastric washout of residual carbon dioxide and subsequent carbon dioxide will be zero.

H, Spontaneously breathing carbon dioxide waveforms where phase III is not well delineated.

I, Dual capnogram in one lung transplantation patient. The first peak in phase III is from the transplanted normal lung, whereas the second peak is from the native disease lung. A variation of dual capnogram (steeple sign capnogram – dotted line) is seen if there is a leak around the sidestream sensor port at the monitor. This is because of the dilution of expired PCO2 with atmospheric air.

J, Malignant hyperpyrexia where carbon dioxide is raising gradually with zero baseline suggesting increased carbon dioxide production with carbon dioxide absorption by the soda lime.

K, Classic ripple effect during the expiratory pause showing cardiogenic oscillations. These occur as a result of to-and-for movement of expired gases at the sensor due to motion of the heartbeat during expiratory pause when respiratory frequency of mechanical ventilation is low. Ripple effect like wave forms also occur when forward flow of fresh gases from a source during expiratory pause intermingles with expiratory gases at the sensor.

L, Sudden raise of baseline and the end-tidal PCO2 (PETCO2) due to contamination of the sensor with secretions or water vapor. Gradual rise of baseline and PETCO2 occurs when soda lime is exhausted.

M, Intermittent mechanical ventilation (IMV) breaths in the midst of spontaneously breathing patient. A comparison of the height of spontaneous breaths compared to the mechanical breaths is useful to assess spontaneous ventilation during weaning process.

N, Cardiopulmonary resuscitation: capnogram showing positive waveforms during each compression suggesting effective cardiac compression generating pulmonary blood.

O, Capnogram showing rebreathing during inspiration. This is normal in rebreathing circuits such as Mapleson D or Bain circuit.

YouTube Preview Image YouTube Preview Image


  1. AHRQ Guideline – Capnography/capnometry during mechanical ventilation: 2011
  2. BCEMS
    1. Capnography Part I
    2. Capnography Part II
  3. Capnography
  4. Capnography Outside the Operating Rooms
  5. Capnography/Capnometry During Mechanical Ventilation: 2011 (pdf)
  6. Cecil medicine – Chapter 104 – Respiratory Monitoring in Critical Care
  7. Council of the Intensive Care Society – Capnography Guidelines
  8. Difficult Airway Society – Capnography the Future
  9. Emergency Nurses Association – Wave Form Capnography The 12 Lead of the Lungs!
  10. Interpreting your capnogram
  11. Life in the Fast Lane
    1. Capnography
    2. Respiratory Monitoring in the ED
  12. NIAA – National Audit Project 4
  13. Noninvasive Monitoring of End-Tidal Carbon Dioxide in the Emergency Department
  14. Phillips – Clinical Measurements – A Quick Guide to Capnography
  15. Physiology of Oxygenation and Ventilation
  16. Slap the Cap – The Role of Capnography in EMS
  17. Rapid Results – Capnography: A Key Patient Assessment Tool
  18. Riding the Waves (pdf)
  19. The Alveolar Gas Equation (pdf)

this is a repost from this website Its a wonderful resource. Do check it.

Topical Anesthetics to support Intubation

Local Anesthesia for Awake Intubation

Topical anesthetic products can play a pivotal role in the comfort and safety of patients in the operating room. When used in conjunction with awake intubation, for example, and delivered with skill and care, these agents can lessen or even eliminate the need for sedation, thereby greatly improving patient cooperation during surgical procedures…..

Continue reading Topical Anesthetics to support Intubation

Anesthesia for Non Obstetric Surgery During Pregnancy

Non obstetric surgery during Pregnancy

Surgery during pregnancy is complicated by the need to balance the requirements of two patients. Under usual circumstances, surgery is only conducted during pregnancy when it is absolutely necessary for the wellbeing of the mother, fetus, or both. Even so, the outcome is generally favourable for both the mother and the fetus. All general anaesthetic drugs cross the placenta and there is no optimal general anaesthetic technique.

Presentation By:

Dr Sarbari Swaika,

Associate Professor 
Department of Anaesthesiology,
Bankura Sammilani Medical College,
West Bengal.

More Stuff on Non Obstetric Surgery during pregnancy

BJA Article on same topic

Guidelines for Diagnosis, Treatment, and Use of Laparoscopy for Surgical Problems during Pregnancy

Other Articles on Obstetric Anesthesia

Ambulatory Anesthesia- Video Lecture By Dr Jayshree Sood

 Anesthesia for Ambulatory Surgeries

Ambulatory Anesthesia:  We are in the midst of a major shift in surgical practice. For a variety of reasons ranging from patient preference to cost,surgery is changing from an inpatient to an outpatient activity. Day surgery is defined as planned investigations or procedures on patients who are admitted and discharged home on the day of their surgery but who require some facilities and time for recovery. In most countries, including ours, this means that the patient spends a few hours in hospital and does not stay overnight.
However, in the USA, day surgery is termed ‘ambulatory surgery’ and includes patients who may spend upto 23 hours in hospital, allowing a greater range of procedures to be performed.

Below is a video of lecture given in ISACON 2012 by Dr Jayshree Sood on the same topic.


 Below are some PDF articles on Ambulatory Anesthesia


 PDF  Article By Dr H Harsoor on Day care surgery-IJA

 PDF Article: Postoperative pain relief for ambulatory surgery– IJA


PDF Article : Day Care Surgery – BJA


PDF Article Day Care Anesthesia in Children- BJA





Practicing Anesthesiology – Dr SSC Chakrarao




Dr SSC ChakraraoMy Dear collegues,
In an endeavor to keep theme of the year going on I have  prepared  a presentation about ISA,  Its functions, Monitoring standards, Safe operating theater , safety check list, Minimum equipment in OT , Emergency drugs to be available, some advises to our anaesthetists regarding preoperative check up and introduction to the patient, patient consent form and remuneration chart.

Remuneration or anaesthetist’s fee has been much discussed about thing for a long time. Its a general feeling that the remuneration should be decided by the anesthesiologist depending upon the case, the risks involved and not as a proportion of surgeon’s fee. We’ve got  some good response from discussion with our people and everyone thinks that we can sort this with the surgeon/ nursing home owner and  achieve it  to certain extent.

However this will be a  continuous process and will take time to implement . A major reason to this is that people are still not aware about who the anesthesiologist is and what does he do.

I sincerely advise you to  talk to the patient and his relatives before surgery, tell them that you are the person who will relieve the pain during surgery and keep him safe, talk to them again after surgery, wait till the patient is shifted to the room, and make sure the remuneration is paid by the patient’s attendant rather than the surgeon.

In the presentation there’s a suggested  pattern of remuneration suited for Kakinada but you have to decide on your own as per the situation and place and the economic condition of the patient.

Impress up on the the Nursing owner about the safety in OT and minimum equipment, tell them that they have to maintain all those for themselves, tell them that by doing this they can stay away from  litigation.

Anesthesia is one of the most stressful branch of medical science. Instead of working long hours in a day, having no time for yourself and eventually burning out

Charge more, take some time to relax, go for a movie with family, go for a holiday if possible.

Give a feedback, Discuss these things  in your city branch meeting.

Dr SSC Chakrarao

Hon President National

Indian society of Anaesthesiologists

Message from the ISA National President Dr SSC Chakrarao

ISA National President Dr SSC Chakrarao
Dr SSC Chakrarao

My dear Colleagues, Fellow members & Anaesthesiologists,

First of all let me express my gratitude for electing me as President Elect in the year 2012 and now giving me the seat of the ISA National President.

This year 2014 we have a Theme “The Practising Anaesthesiologist”, anaesthesiologists who are practicing alone at district and taluq level and their problems. We have to work on improving the working conditions of those anaesthesiologists, the safety in OT for him and the patient. We have to utilize the registration of Hospitals and Nursing homes act and set some safe standards and advise our lone anaesthesiologist not to administer anaesthesia without Oxygen and equipment for ventilation. In this way we need to touch the Government hospitals also where a good number of caesarean sections and millions of tubal ligations are done. Monitoring of patients with SpO2 & NIBP and EtCO2 for laparoscopic procedures is a must. We have to demand for provision of scavenging systems in OT, adequate number of lead protective aprons when using C-arm, enough protective glasses when laser being used in surgery.

Demanding justified and legitimate remuneration not as part of percentage of surgeons’ charges is must. I think every city branch must come with one’s own fee structure, like what is practiced in Kerala. As we have varied socio-economical conditions and different types of hospitals, the local branches should decide.

This year we must try for the inclusion of Anaesthesia as a subject in the undergraduate curriculum of MBBS, where we can catch the doctors when they are young and teach and create awareness among the medical students. This way of imparting knowledge of resuscitation and basic life support will help them to serve better.

Global warming is the problem of the day. Let’s go green. Save nature. Save trees. On adopting this principle, and for other economic reasons, our esteemed journal of ISA, the IJA, indexed with Pubmed, has gone further and turned out to be an e-journal with printing mandatory hard copies.

Let’s update our database further, let’s make a clean data base with everyone having the mobile number, email ID and Pin code for the postal address and erase those with insufficient information to regularise the membership. I call for the attention all the members, as their involvement is necessary in this data base update.

The new generation anesthesiologist is computer friendly and has information at his fingertips on a mobile or a tablet. At ISA Kakinada city branch we have started a website with an idea to provide quality academic material from the specialists in our field in the form of video lectures, PPTs, journal articles and lot more. the site is located at

I request you to have a look at the site and provide suggestions to improve or new ideas to implement for it to be even more useful for the community. You can click here for sending your suggestions.

I wish you all a great time ahead and look forward to see you soon.


Dr.S.S.C.Chakra Rao,

President – Indian Society of Anaesthesiologists (National)

Honorary Secretary, ISA(National) 2009-11,

Ex-Officio Member of GC ISA(National),

Founder Honorary Secretary, FBF- ISA,

Managing Director of Care Emergency Hospital,

Formerly Additional Director of Medical & Health Services, Andhra Pradesh.

Anesthesia For Liver Transplant

A significant progress has been made in the last two decades in the field of orthotopic liver transplantation since it was first performed in 1967. It now stands as a standard therapy for many patients with acute and chronic liver disease. The success in this field is due to the advancements and innovations which evolved – in the form of better pre and post transplant care, improved anaesthesia, innovative surgical strategies, early detection of complications and progress in the field of immunosuppression. Liver transplantation is now a routine procedure in numerous medical centers throughout the world. The issues involved in the conduct of anaesthesia in this novel procedure are highlighted.

Anesthesia for Liver transplant – Dr Palepu B Gopal

Presentation by Dr Sandeep

Post operative ICU management of Liver transplant Patients


IJA Articles

Dr Amar Nandhkumar’s Article

Transfusion support in Liver Transplant Dr Col. TVSP Murthy

Another Article by Dr Col TVSP Murthy


Pregnancy with Mitral Stenosis – PG long Case

Pregnant patients are very commonly posted in PG and DNB exams as long case and are very much dreaded by the students as the viva can lead anywhere from pregnancy, anemia to cardiac surgery….. I have posted some very good online resources in this post. You can like our facebook page and keep getting updates on your facebook timeline about new articles.

Heart disease is a major cause of maternal complications in pregnant women. Up to 20% of the pregnancies in patients with heart disease are complicated by a cardiovascular event such as heart failure, hypertensive disorder or arrythmia. In the presence of heart disease obstetric and neonatal complications are also encountered more frequently compared to women without heart disease 1,2 . Although rheumatic heart disease is decreasing worldwide, it is still an important cause of valvular problems with mitral stenosis being the commonest lesion (90%).

An Excellent presentation by Dr Sandeep kumar kar

Articles on pregnancy with mitral stenosis

IJA Article By Dr Kannan

Emergency Caesarian in Mitral stenosis – IJA

American Heart Association – Circulation article

PDPH – Post Dural Puncture Headache

Post dural puncture headache

Spinal anaesthesia developed in the late 1800s with the work of Wynter, Quincke and Corning. However, it was the German surgeon, Karl August Bier in 1898, who probably gave the first spinal anaesthetic. Bier also gained first‐hand experience of the disabling headache related to dural puncture. He correctly surmised that the headache was related to excessive loss of cerebrospinal fluid (CSF). In the last 50 yr, the development of fine‐gauge spinal needles and needle tip modification, has enabled a significant reduction in the incidence of post‐dural puncture headache. Though it is clear that reducing the size of the dural perforation reduces the loss of CSF, there are many areas regarding the pathogenesis, treatment and prevention of post‐dural puncture headache that remain contentious.1

PDPH Presentation

A Video on PDPH and epidural patch (Dr Barbara M Scavone)

PDF Articles on PDPH

International Journal of pain and palliative medicine

Dr PF Kotur’s Article in IJA

St George’s Hospital London Guidelines for PDPH

Dr James Bates Iowa

BJA Article

A very nice tutorial for PG students