Laparoscopic, Endoscopic Procedures

Question 1

what are advantages of laparoscopic procedures?

Answer 1

• less tissue trauma
• reduced post-op pain
• shorter hospital stays
• more rapid return to normal activities
• significant cost savings
• less potential for post-op complications i.e. ileus
• improved cosmetic results

Question 2

what are indications for laparoscopic procedures?

Answer 2

• cholecystectomy
• appendectomy
• fundoplication
• inguinal hernia repair
• gynecologic
• colon resection
• splenectomy
• nephrectomy
• liver biopsy
• diastasis repair and more

Question 3

what are types of gynecologic procedures indicated for laparoscopic?

Answer 3

• tubal ligation
• myomectomy
• assisted hysterectomy
• oophorectomy
• lysis of adhesions
• fulgartion of endometriosis
• removal of ectopic pregnancies, tubal repair
• diagnostic procedures
• ovarian cystectomy

Question 4

what are contraindications for laparoscopic procedures?

Answer 4

• bowel obstruction
• ileus
• peritonitis
• intraperitoneal hemorrhage
• diaphragmatic hernia
• severe cardiopulmonary disease, CHF

Question 5

what are relative contraindications for laparoscopic procedures?

Answer 5

• extreme of weight (large abdomen; may obstruct view)
• inflammatory bowel disease
• presence of large abdominal masses
• advanced intra-uterine pregnancy (size of uterus)
• increased ICPs
• VP shunts (emptying into abdominal cavity)
• coagulopathy
• previous abdominal surgeries with adhesions

Question 6

what are considerations with laparoscopy in pregnant patients?

Answer 6

• uterus remains in the pelvis during 1st trimester, allowing safe insertion of Veress needle through umbilicus
• after 23rd week, enlarged uterus obstructs view

Question 7

what are AIs for laparoscopy in pregnant patients?

Answer 7

• closely monitor PaCO2 to maintain slightly alkalotic state (increase MV)
• place in 30 degree left-uterine displacement (no compression of IVC or decreased VR)
• limit intraperitoneal pressures to 12 mmHg
• monitor fetal heart rate throughout w/ transvaginal ultrasound

Question 8

what are four potential causes of physiologic changes during laparoscopy?

Answer 8

• initial trendelenburg position
• creation of the pneumoperitoneum
• potential for systemic absorption of CO2
• reverse trendelenburg position

Question 9

what is the pneumoperitoneum?

Answer 9

insufflation of the peritoneal cavity with CO2 (air, nitrous oxide, helium, and O2)

Question 10

what are characteristics of the pneumoperitoneum?

Answer 10

• doesn’t support combustion
• blood solubility enhances tissue diffusion, decreasing risk of gas emboli
• more pain d/t diaphragmatic irritation (shoulder pain)
• can lead to hypercarbia, respiratory acidosis, cardiac dysrhythmias

Question 11

what is an advantage of the pneumoperitoneum?

Answer 11

-separates the abdominal wall from the contents of the peritoneal cavity to optimize visualization and access

Question 12

what are disadvantages of the pneumoperitoneum?

Answer 12

-limits surgeons freedom of movement, choice of instruments
-involves risk of significant complications r/t use of CO2
(once insufflation begins balance off CO2 by increasing MV)

Question 13

how is the pneumoperitoneum created?

Answer 13

• inject local anesthetic into the umbilical area
• insert Veress needle via anesthetized area into peritoneal cavity
• insufflate cavity with CO2 at a pressure less than 19 mmHg (3 L)
• once distended, insufflator placed in automatic mode to maintain pneumoperitoneum at 12 mmHg
• be sure pt. is completely relaxed when surgeon insufflates
• after intubation, be sure to insert suction catheter and suck out any air bubbles in esophagus

Question 14

what are some possible traumatic injuries r/t pneumoperitoneum?

Answer 14

• unintentional injuries to abdominal organs
• insertion of the Veress needle and trocars (aorta, intestinal walls)
• subcutaneous emphysema d/t improper placement of the needle b/w fascial planes in the muscle (if severe, like up to neck and face, don’t extubate since airway can collapse under increased pressure)
• massive hemorrhage d/t penetration of vessels or rupture of the spleen w/ stretching of pre-existing splenic adhesions

Question 15

what are physiologic changes associated w/ pneumoperitoneum dependent upon?

Answer 15

• pressure attained
• volume of CO2 absorbed
• patient’s intravascular volume (lower CVP can cause “vacuum” sucking more CO2 in)
• ventilator technique
• surgical conditions (length of surgery and position)
• anesthetic agents used

Question 16

what are CV changes associated w/ pneumoperitoneum?

Answer 16

• increased SVR
• increased MAP (young, healthy)
• initial decrease in cardiac index (50% baseline-proportional to the pressure achieved)
• increased myocardial filling pressures initially, followed by sustained decrease in preload (decreased VR)
• decreased renal, portal, and splanchnic blood flow (decreased GFR, urinary output, and creatinine clearance)

Question 17

what causes the initial increase in MAP?

Answer 17

liver and spleen are huge blood reserves and when squeezed under the pressure of the pneumoperitoneum, vessel contents are pushed out
-long term, VR is decreased

Question 18

what are cerebral changes associated w/ pneumoperitoneum?

Answer 18

• increased cerebral blood flow
• increased ICP
• hyperventilation does not help, but hypoventilation makes worse*

Question 19

what are pulmonary changes associated w/ pneumoperitoneum?

Answer 19

• decreased pulmonary compliance
• increased peak airway pressure d/t diaphragm shifting upward (make note of PIP when supine, in trendelenburg, then when insufflated so if increased d/t pneumothorax you’ll know difference)
• reduced lung volumes (VC, FRC)
• atelectasis (will happen, need serious alveolar recruitment)
• hypoxemia d/t V/Q mismatch in obese pts. and pre-existing pulmonary disease (not normally in healthy pts.)
• hypercarbia (ETCO2 increases 0-30% from absorption)
• adjust ventilation
• re check breath sounds after insufflation

Question 20

what are physiological changes associated w/ trendelenburg?

Answer 20

• 10-20 degrees allows small bowel and colon to move out of the pelvis and minimize needle or trocar perforation
• increases VR and CO
• reduces lung capacity d/t weight of abdominal contents on diaphragm (decreased FRC)
• inadvertent right main stem bronchial intubation when lung and carina is displaced cephalad
• increased intra abdominal pressure and gravity increase risk of aspiration of gastric contents (intubate!)

Question 21

how does trendelenburg and pneumoperitoneum combined affect ICP?

Answer 21

increases ICP 150% over baseline

Question 22

what is the position of choice if a gas embolism is suspected?

Answer 22

• trendelenburg w/ left lateral tilt
• prevents the bubble from traveling to the right ventricular outflow tract and causing an airlock (if it does can create an obstruction and cause LV infarct)

Question 23

what are physiologic changes associated with reverse trendelenburg position?

Answer 23

• allows optimum exposure and minimizes the possibility of bowel injury for some procedures
• decreased VR
• decreased LVEDV
• maintained ejection fraction in healthy pts.; decreased in others, esp. w/ LV dysfunction
• decreases negative pulmonary effects of peritoneal insufflation

Question 24

what are physiologic changes associated w/ CO2 absorption?

Answer 24

• PaCO2 rises w/ significant amounts of absorption

- hypercarbia can easily occur, resulting in increased catecholamines (caution w/ CAD)

Question 25

what determines the rate of CO2 absorption w/ pneumoperitoneum?

Answer 25

• tissue solubility of the gas
• diffusion pressure gradient across the containing membrane
• blood flow across the cavity
• increased absorption w/ extra peritoneal vs. intraperitoneal d/t lack of containment of CO2 allowing an increased area for gas exchange

Question 26

how does ETCO2 reflect PaCO2?

Answer 26

• ETCO2 accurately predicts changes in PaCO2 in healthy, mechanically ventilated pts.
• *ETCO2 does not increase comparably w/ increases in PaCO2 in pts. w/ cardiopulmonary disease

Question 27

what is the major concern of anesthesia in laparoscopic procedures?

Answer 27

• prevent the effects of hypercarbia
• controlled PPV w/ increased Vt usu. approx. 8 ml/kg to decrease PaCO2 to normocarbia
• maintain MV by increasing rate
• minimize sympathetic stimulation and hypoxia which would add to increased risk of cardiac arrhythmias
• pre medicate w/ anxiolytic and use 100% O2
• at end of case, when deflate, be aware that Vt can increase w/ decreased pressure causing barotrauma
• at end, do alveolar recruitment for atelectasis: close off pop off, give breath and HOLD to recruit alveoli w/ 100% O2

Question 28

describe GA use for laparoscopic procedures

Answer 28

• most widely accepted technique
• controlled ventilation
• give muscle relaxants to minimize pulmonary compromise, esp. at beginning when inserting trochars
• alters ventilatory response, thus SV under GA results in hypercarbia (intubate and MV!)

Question 29

describe regional anesthesia technique for laparoscopic procedures

Answer 29

• epidural or spinal (level would need to be pretty high w/ lap chole)
• no hypercarbia d/t adequate alveolar ventilation under epidural anesthesia
• combined w/ GA, better pain relief, but no better pulmonary function

Question 30

describe LA anesthesia technique for laparoscopic procedures

Answer 30

• not optimal surgical condition
• inability to control respiration if hypercarbia develops
• delay in treating complications
• risk of injury if pt. moves unexpectedly
• anxiety
• N/V

Question 31

is use of N2O ok w/ laparoscopic procedures?

Answer 31

• controversial
• N2O more soluble than nitrogen and can move into air-filled space faster than nitrogen can move out, causing distention
• increase of intestinal luminal size after 4 hrs.
• expansion of air embolism
• increased vomiting, no difference in nausea

Question 32

what are AIs for laparoscopic procedures?

Answer 32

• adequate muscle relaxation to avoid risks of injury to organs or vessels or umbilical hernia (up until fascia closed)
• evacuate any air from stomach to minimize gastric distention and avoid risk of injury during Veress needle insertion (some surgeons want salem sump left in place)
• stop ventilation during insertion of Veress needle to avoid pushing abdominal contents up toward needle
• explain increased risk of PONV and use prophylaxis (3: scopolamine, decadron, Zofran)
• young, female, non smoker, gynecologic procedure increased risk

Question 33

what are AIs r/t analgesia w/ laparoscopic procedures?

Answer 33

• less painful than open, but still painful
• pre-incisional local infiltration
• intraperitoneal instillation of local?
• NSAIDS
• opioids: induce spasm of sphincter of Oddi (antagonize w/ *glucagon, NTG, or Narcan); increased N/V
• *opioid sparing: NSAIDS, IV Tyl, Gabapentoids (Neurontin)
• deferred pain to shoulders r/t irritation of diaphragm (assist surgeon expel as much CO2 as possible by giving deep breaths to pt. as trocar is open at end of case)

Question 34

what are causes for CV depression and/or collapse during laparoscopic procedures?

Answer 34

• bradycardia and asystole can occur during creation of the pneumoperitoneum secondary to reflex vagal stimulation form stretching and distention of the peritoneum (healthy or not)
• ask surgeon to release pressure is the quickest fix
• ventricular arrhythmias can occur d/t hypercarbia
• PEA can occur d/t compression of the IVC, hemorrhage, and gas embolism (no volume returning to heart)

Question 35

what happens with a carbon dioxide embolism?

Answer 35

• CO2 enters the circulation via open venous access (needle in a vessel, portal circulation)
• b/c of solubility of CO2, small amounts may be reabsorbed w/o consequences (69% TEE)
• w/ large amounts, embolus may form gas lock in the right atrium or ventricle to impair VR and right ventricular outflow
• may reach the pulmonary circulation, causing pulmonary HTN and RH failure

Question 36

what are presenting signs of carbon dioxide embolism?

Answer 36

• hypotension
• jugular venous distention
• tachycardia
• “mill-wheel” murmur
• rapid, but short lived increase in ETCO2 followed by decrease
• hypoxemia
• cyanosis

Question 37

what is the treatment for carbon dioxide embolism?

Answer 37

• stop insufflation and release pneumoperitoneum
• place pt. in trendelenburg w/ left side down to prevent bubble from entering right ventricular outflow tract
• hyperventilate to reduce CO2 levels
• insert central line to aspirate bubble from right atrium

Question 38

what are complications of laparoscopic surgery?

Answer 38

• pneumothorax and pneumomediastinum
• pulmonary dysfunction
• deep vein thrombosis

Question 39

describe pneumothorax and pneumomediastinum and treatment

Answer 39

• tracking of insufflated CO2 around the aortic and esophageal hiatuses of the diaphragm into the mediastinum and rupture of the pleural space (pressure collapses lung when CO2 leaks into thoracic cavity)
• rupture of lung bulla or bleb
• unexplained increased airway pressure (know baseline PiPs), hypoxemia, severe CV compromise w/ hypotension, SQ emphysema
• tx: deflation of abdomen and chest tube decompression if hemodynamically unstable; small pneumothorax may be treated conservatively and allowed to be reabsorbed

Question 40

describe pulmonary dysfunction complications

Answer 40

• less than open procedure, but still compromised
• diaphragmatic dysfunction may last up to 24 hrs (but less dysfunction than an open procedure)
• atelectasis will occur (alveolar recruitment)
• if pt. already has pulmonary dysfunction, this shouldn’t be a same day surgery

Question 41

how is deep vein thrombosis prevented?

Answer 41

• compression stockings

- early ambulation

Question 42

describe concerns w/ robotic assisted laparoscopy

Answer 42

• patient positioning extreme: prostatectomy (steep trendelenburg), pelvis (lithotomy w/ steep trendelenburg)
• d/t length of procedure be cautious of pressure points
• corneal abrasions v. ischemic optic neuropathy
• fluid limit: 1-2 liters of crystalloid; consider colloid use (facial edema, airway edema)

Question 43

describe robotic assisted laparoscopic radical prostatectomy

Answer 43

• mean age 60 y/o
• increase incidence of CAD and renal abnormalities r/t prostatic hypertrophy
• airway assessment
• peripheral neuropathies
• COPD- may be difficult to ventilate
• pressure control over volume control

Question 44

describe thoracoscopy

Answer 44

• indicated for diagnostic procedures as well as operative lung biopsies
• pt. positioned in lateral decubitus position
• local, GA, or regional (intercostal nerve block alone or w/ spinal or epidural)
• one-lung ventilation using double-lumen ET tube placed in left mainstem

Question 45

describe video assisted thoracic surgery (VATS)

Answer 45

• indicated for lung nodules and pleural effusions
• wedge resections
• lung resections: formally requiring open thoracotomy
• three small incisions
• one lung ventilation required
• very painful after

Question 46

describe gasless laparoscopy

Answer 46

• no pneumoperitoneum
• technique using abdominal lift using a mechanical retractor; lifts abdominal wall 10-15 cm w/ only 1-4 mmHg IAP
• avoids effects of CO2 insufflation and high intra abdominal pressures
• minimal changes in cardiopulmonary, renal functions and neuroendocrine responses
• may benefit ASA III and IV pts.

Question 47

describe hysteroscopy

Answer 47

• endoscopic exam of the endocervix and endometrial cavity
• cavity of uterus must be distended w/ either CO2 or liquid distending media
• indications: diagnostic for infertility, abnormal uterine bleeding, localization of IUD, resection of septae, adhesions or lesions
• anesthesia: paracervical block, regional or GA (not preferred)
• limit IV fluid intake

Question 48

describe resectoscope (TURP Syndrome)

Answer 48

venous sinuses opened up and absorption of distending fluid occurs

• if large volumes are absorbed, hypo-osmolar hyponatremia can occur w/ hypervolemia, hyponatremia and decrease osmolarity causing cerebral edema
• HTN (sys. and dias.), bradycardia, CNS changes, N/V, H/A, agitation, and lethargy–lead to cardiac arrest
• close attention must be paid to volume in vs. volume out
• Na+ level pre-op and intra-op if increased volume intake and post-op

Question 49

describe distending medias

Answer 49

• CO2: diagnostic only d/t open vessels w/ resection causing embolism
• Hyskon (32% dextran): anaphylaxis, fld. overload, pulmonary edema, renal failure
• Glycine 1.5%: fld. overload, hyponatremia, hypo-osmolality, hyperammonaemia, hyperglycinaemia

Question 50

what are the effects of glycine?

Answer 50

• glycine is metabolized into ammonia by the liver

* ammonia toxicity: seizures, mental changes, lethargy

Question 51

what are early signs of TURP Syndrome?

Answer 51

• restlessness leading to confusion
• blurring of vision
• H/A
• N/V

Question 52

how can TURP Syndrome be diagnosed?

Answer 52

CV signs
-unexplained HTN followed by decreased BP
-refractory bradycardia
-nodal/junctional rhythm (loss of P waves), ST changes, U waves, widening QRS
Fluid absorption: avg. rate is 20 ml/min (more than 1 L/hr)
*limit the volume given

Question 53

describe the circulatory overload w/ TURP Syndrome

Answer 53

• absorption
• blood volume increases
• systolic and diastolic pressures increase
• affects contractility and potentiates failure
• dilutes proteins and decreases osmotic pressure
• fluid moves into interstitial causing pulmonary and cerebral edema

Question 54

how can TURP Syndrome be prevented?

Answer 54

• regional anesthesia
• use saline vs. glycine (surgeon’s decision)
• minimize surgical resection time ( more than 1 hr. associated w/ increased risk; has occurred within 15 min.)
• use different surgical technique, i.e. laser vaporization (helps close off opening vessels)
• communication- increased risk w/ capsular perforation

Question 55

if TURP Syndrome is suspected, what should be done?

Answer 55

• complete procedure quickly
• draw labs (CBC, electrolytes, Na+, osmolality)
• administer normal saline and furosemide
• glycine deficits of 500 ml lead to decreases in Na+ of 2.5 mEq/L
• if under GA, mental status changes are not assessable
• regional recommended

Question 56

describe endoscopy

Answer 56

• NPO (ensure adequate NPO time)
• bowel prep (colonoscopy; fld. deficit)
• sedation (propofol alone is best option; just need to sedate enough to pass scope; may see w/ versed)
• airway management and pt. safety
• pt. satisfaction
• positioning (most cases flat maybe w/ HOB raised a little; colonoscopy usu. turned)
• PONV and recovery
• no pain post-op, so fentanyl just delays recovery