Enhanced Recovery for Colorectal Surgery



Fig. 6.1
Original ERAS Elements described for colorectal surgery. From Fearon KCH et al. Clinical Nutrition 2005



Whilst some the aspects can be challenged or, updated, figure one which is now 10 years old, was remarkably prescient and still largely relevant as the basis of modern ER in colorectal surgery. It has recently been updated by the UK’s Department of Health (Fig. 6.2)

A327076_1_En_6_Fig2_HTML.gif


Fig. 6.2
Updated ER pathway for Colorectal Surgery. SDM shared decision making

From a practical perspective, the setting up of an ERAS programme in a unit not currently practising it is not always straightforward. A number of hurdles have to be overcome, with buy in from managers, the appointment of a local champion (often an experienced nurse) who will then coordinate regular multidisciplinary meetings with surgeons, anaesthetists, physiotherapists, and others e.g. dieticians and occupational health. In addition, full participation and understanding from the primary care providers is fundamental too. It is very important that at these regular meetings problems are addressed and progress reported on for the next meeting. The cornerstone of this process is the collection of good quality audit data, permitting analysis of success and failures for clinicians as well as also allowing the managers to see the effects on bed usage and cost (Table 6.1).


Table 6.1
Stress response to surgery


































Neuroendocrine activation

Metabolic consequences

Inflammatory reponses

Other responses

Sympathetic nervous system

↑Catecholamines

Salt and water retention

Potassium loss

Cytokine release e.g.

Interleukins (especially IL-1, IL-6)

Tumour Necrosis Factor alpha

Interferons

VEGF

Malaise

Pituitary activation

↑GH, ADH, ACTH, Prolactin, Beta-endorphin

Fat metabolism

Lipolysis

SIRS response

Fever

Other endocrine glands (e.g. adrenal, pancreatic)

↑Renin, Aldosterone, Cortisol

Carbohydrate metabolism

Insulin resistance, hyperglycaemia, glycogenolysis, gluconeogenesis

Immunosuppression
 
 
Protein metabolism

Muscle breakdown, nitrogen loss
   


GH growth hormone, ADH antidiuretic hormone, ACTH corticotrophin, VEGF vascular endothelial growth factor, SIRS systemic inflammatory response syndrome


6.1 Preoperative Preparation


The preoperative preparation is a fundamental part of the ERAS pathway. Various issues need to be addressed.


6.1.1 Assessment of the Functional Physiological Status and Reserve


The assessment of the patient’s ability to withstand and respond to surgery is a key determinant in risk stratification for predicting outcome, providing informed consent planning appropriate surgery and the level of anticipated postoperative care. Major elective colorectal surgery carries significant risk (particularly in the elderly or those with comorbidities) and imposes significant perioperative demands on the patients, in particular causing a catabolic response and an increase in oxygen consumption. Patients who are unable to meet this increase in oxygen consumption with a concomitant rise in oxygen delivery are at risk of oxygen debt, anaerobic metabolism and the build up of lactic acid. Moreover, in patients undergoing colorectal surgery the situation is compounded by the fact that haemodynamic upset (e.g. from hypovolaemia) will divert splanchnic blood other organs, which may put anastomotic healing at particular risk.

For many years, intensivists have focussed on the improved outcomes of patients who are able to increase oxygen delivery (DO2) in the intraoperative and postoperative period to supranormal levels e.g. a DO2 of >600 ml·min−1·m−2 [8]. In addition a number of risk scores have also been described to aid in the preoperative assessment. Goldman’s original risk score [9] has been superseded by a number others, the most well known is Lee’s Revised Cardiac Risk Index [10]. There others that are widely used including Physiological and Operative Severity Score for the enUmeration of Mortality and Morbidity (POSSUM) scores and data from large surgical databases such as the American College of Surgeons National Surgical Quality Improvement Program (NSQIP).

More recently, there has been a paradigm shift to dynamic assessment of patients. This may includes relatively simple assessment such as estimating metabolic equivalents (MET) which is the resting oxygen uptake (approx. 3 ml/kg/min), with, for example walk up a flight of steps or a brisk walk on level ground representing 4 METs and strenuous sports representing >10 METs. The gold standard is increasingly being viewed as cardiopulmonary exercise testing (CPET), in which a number of measurements are made including maximal oxygen consumption (VO2 peak) or more usefully the estimation of anaerobic threshold (AT), which is effort independent. Although the evidence is still growing a commonly used threshold is Older’s study in elderly patients undergoing abdominal surgery, with a mortality in a patients with an AT of >11 ml/kg/min was 1 %, increasing to 18 % with an AT of 8–11 ml/kg and over 50 % with an AT of <8 ml/kg/min [11]. More recently, studies for colorectal surgery patients have broadly agreed with this, such as West’s group who demonstrated the risk threshold to be an AT of <10.1 ml/kg/min and VO2 peak < 16.7 ml/kg/min [12].

What is the value of this assessment of physiological status? There is compelling evidence that patients with poor reserve have a poorer outcome, both in terms or mortality but also morbidity. The latter, in the form of complications has the potential to cause chronic ill health, and given the volume of colorectal surgery undertaken worldwide annually clearly represents not only huge personal burdens, but also widespread social and economic burdens too. Above all, good preoperative assessment permits risk stratification, guiding consent, appropriate surgery and the postoperative care. For example some patients may not be able to withstand the cardiovascular and respiratory sequelae of prolonged pneumoperitoneum for a laparoscopic resection and may be best served by an open procedure. Other patients may be deemed at such high risk that stenting may be the safest alternative, or require a planned admission to intensive are for targeted organ support.


6.1.2 Optimization of Patients’ Health


There is little controversy for patients with an ERAS programme should have their health optimized preoperatively. Much of this involves coordination with primary care physicians and includes optimization of haemoglobin levels (e.g. with iron therapy), and of comorbidities such as diabetes, angina hypertension, atrial fibrillation asthma etc. For some patients, preoperative assessment may unmask other serious comorbidities and these may need surgical intervention prior to surgery, such as coronary stenting.

An exciting area of perioperative medicine emerging is the concept of prehabilitation. Given that there seems to be an improved outcome in with increasing physiological reserve, it is logical to take steps to improve this reserve preoperatively. Indeed, the parallel between some of the physiological changes of major surgery and a major sporting endeavour has been made [13] and there exists a wealth of data in exercise physiology as to how training may improve exercise performance as measured by an increase in VO2 max or lactate threshold [14]. Therefore if exercise can improve the results of CPET for athletes, it is very tempting to suppose that this might have the same effect in patients and thus be translated into an improved outcome. This is an emerging field with no unified agreement as to an exercise regime. However there seems to be a dose–response effect with increased benefits occurring following increased exercise. Prehabilitation is a wider, multimodal discipline, encompassing not only exercise regimes, but nutritional supplementation (see below) and psychological preparation too. Although in some circumstances effective prehabilitation may be impractical, either because of the relative urgency of surgery or because of other comorbidities, this area is key within ERAS programme, as patients with poor preoperative functional capacity and grip strength have a slower recovery, with increased complications, sleep disturbance and fatigue persisting weeks or even months. Moreover the least fit patients appear to have the most to gain [15].


6.1.3 Other Areas of Preparation for Surgery


Nutritional supplementation and advice and has been mentioned above, and is one of the most exciting areas in the preoperative care and indeed we have coined the phrase “nutritional perioperative medicine” [13]. The use of nutritional support and supplements for those with a high degree of nutritional risk may need to escalated so to formal enteral (and in some cases parenteral) for 7–10 days prior to surgery, even if surgery may have to be delayed. More recently the effects of immunonutrients and perhaps even other nutrients that improve oxygen efficiency (such as beetroot and other nitrates) are awaited with interest [13, 15].

In addition, simple advice (but often hard for the patients to implement) such as weight loss and cessation of smoking and management of excessive alcohol intake must nevertheless be enthusiastically given to patients, extolling their virtues. In particular smoking cessation has a greater effect the longer the patient is able to stop, and there is a reduction in postoperative complications after just 3 weeks of abstinence. Furthermore, multidisciplinary support, counselling and nicotine replacement patches may aid in this process.

The patient, their family and their carers need to be given advice and prepared for postoperative management and what is expected of the patient on a daily basis in terms of nutrition and activity, as well as and psychological support where necessary. There are several ways of imparting this information such as literature, or DVD or a website. In addition, the routine use of bowel preparation has largely been abandoned (although there is a degree of personal choice from surgeons and some advocate for certain circumstances, such when intraoperative colonoscopy is contemplated) as it has often resulted in patients arriving for surgery in a state of dehydration and electrolyte imbalance. Finally the admission of patients the day before surgery (or even earlier) has largely been abandoned as patients should continue to have a normal level of activity until just prior to surgery.


6.2 Oral Carbohydrate Loading


A key area within ERAS pathways is the prevention of prolonged fasting, with dehydration (compounded if a bowel preparation is used). If the analogy of major surgery and sport is accepted, then clearly one would not expect an athlete to perform at their best dehydrated and with little or no attention paid to nutrition (Table 6.2).


Table 6.2
Benefits of oral carbohydrate preload

















Improves patient comfort and wellbeing

Patient in metabolically conditioned or fed state prior to surgery

Attenuates insulin resistance

Attenuates protein loss and catabolism, preserves muscle strength

Reduces complications

No effect on gastric emptying/reflux

Anaesthetists have traditionally required fasting of 6 h for solids and 2 h for clear liquids to minimize the risks of pulmonary aspiration of gastric contents, but in practice this has often resulted in patients being fasted for much longer. However whilst dehydration may be prevented or rapidly reversed intraoperatively, major interest has focussed on the immediate nutritional optimization of patients, in a similar fashion to athletes.

For nearly 50 years, carbohydrate loading in athletes has improved performance during endurance exercise (75–85 % VO2 max). This is attributed to an increase in muscle glycogen stores. For elective surgical patients, carbohydrate drinks not only prevents dehydration, but also reduces insulin resistance, catabolism and preserves muscle function [13].

The mixture consists of maltodextrins, which are complex carbohydrates and empty readily and predictably from the stomach, in contrast to glucose or milk. Generally two doses are given, 100 g of carbohydrate in a volume of 800 ml approximately 12 h before surgery and half this (50 g carbohydrates in 400 ml) 2–3 h before surgery.

Oral carbohydrate preload has been a key elements of the ERAS protocol for colorectal surgery for over 10 years, and is the first and probably the most simple element to reduce surgical stress and metabolically condition a patient to aid early return to oral diet, mobility and recovery. In a recent review of all ERAS elements, preload was one of two ERAS elements that independently had a significant effect on reducing complications and improving wellbeing [7].

Safety is clearly paramount and the first concern some will have is that the risk of pulmonary aspiration may be more likely. Whilst not appearing to increase this risk, given the relative rarity of this condition (1 in 7000 anaesthetics and a mortality of 1;1000000) a very large study would be needed to provide further information. Indirect information from other studies which have estimated gastric emptying from ultrasound and/or co-administering with paracetemol (them measuring the change in serum paracetemol concentrations) also suggests that stomach emptying should have occurred within 2 h of the second preload. Another area of concern is its use in diabetics, who are at risk of both hyperglycaemia and (in the presence of autonomic neuropathy) gastric stasis. There is a little evidence to support its use in type 2 diabetics, when a carbohydrate preload with paracetemol (the latter to determine gastric emptying) did not delay gastric emptying nor risk hyperglycaemia or pulmonary aspiration. The current recommendations are to give diabetic patients a preload along with their usual diabetic medication [16]. Further, larger studies, and its use on Type I diabetics, are required. Finally, in the emergency patient (see below) where there is like to be poor gastric motility, oral preload should be avoided.


6.3 Intraoperative Anaesthesia


The anaesthetist has a pivotal role in the patient’s ERAS pathways. There are many aspects to this (see Figs. 6.1 and 6.2), but the two major areas are fluid management and analgesia, which have a large evidence base and are dealt with in detail below. Indeed, so important are these areas that we have introduced the trimodal approach – fluids, analgesia and “all the rest” [17]. The last term refers to many of the fundamental elements which are often protocolised and in which there either exists little controversy in their use, or there is little compelling evidence for an alternative.

Most ERAS anaesthetists would support the idea of no sedative premedication and the use of short acting anaesthetics. The ideal agents for induction and maintenance of anaesthesia may not be proven, but most anaesthetists would avoid nitrous oxide as it may cause bowel distension and increase the risk of postoperative nausea and vomiting (PONV). Short acting inhaled agents such as desflurane or sevoflurane are commonly used although a total intravenous regime with propofol is preferable where there is high risk of PONV. An area that will undoubtedly receive more attention in the future is cerebral monitoring e.g. bispectral index (BIS) and anaesthetic depth, particularly in the elderly, as excessive anaesthetic depth is associated with delirium and postoperative cerebral dysfunction [18]. Most recently and rather more speculatively, an editorial examines some of the evidence for the potential role in which volatile anaesthetic agents may play in cancer call growth [19].

The use of neuromuscular blocking drugs is currently of interest as there is some data that shows that deep neuromuscular blockade (DNB) as defined as a Post tetanic twitch count of 1–2, may aid laparoscopic access (e.g. for rectal surgery) and allow a marked reduction in insufflation pressures [20], perhaps also reducing postoperative pain and mitigating some of the cardiorespiratory effects of laparoscopy. DNB is most easily achieved by the use of rocuronuium which is easily and reliably reversed by suggammadex. Whatever type of neuromuscular blocking drug is used, confirmation of restoration of neuromuscular function at the end of surgery is paramount. In spite of postoperative residual curarization (PORC) having been described over 35 years ago [21], and is commonplace even with modern neuromuscular blocking drugs [22]. PORC is associated not only with patient distress, but delayed post anaesthetic care unit discharge, and early and late postoperative pulmonary complications [23].

Tracheal intubation is almost universal for these patients and care is required to prevent of microaspiration by careful tracheal toilet at the end of the procedure. A newer area is that of lung protection strategies – well recognised by our intensivist colleagues – and the recent the focus of studies for (mainly) open abdominal surgery in which low tidal volumes (7–8 ml/kg) and PEEP (6–10 cmH2O) reduced hospital stay and postoperative pulmonary complications compared to higher tidal volumes (9–12 ml/kg) and no PEEP [24, 25], although most recently, the PROVHILO trial, found no benefit in PEEP and recruitment manoeuvres, which merely resulted in more hypotension requiring vasoactive support [26].


6.4 Fluid Management


There is probably no area in perioperative medicine that generates more controversy than fluid management, particularly in patients undergoing major colorectal surgery, where the potential for fluid losses and shifts is enormous. Both the protocol for administration (fixed, liberal, zero-balance, restrictive, individualized, goal directed etc.) and the type of fluid – crystalloid and colloid (and the various different types) – and have all been the subject of numerous studies and reviews.


6.4.1 Volume of Fluid Administered


The fundamentals fluid management are best appreciated by understanding two fundamental concepts. Firstly the importance of adequate cellular oxygen delivery and secondly the consequences of poor fluid management.

Adequate tissue oxygenation is a basic physiological principle and over 40 years ago the link between higher levels of oxygen delivery (DO2) and consumption (VO2) with increased survival in septic patients [27]. Many, but not all, later trials have supported confirmed these findings in both high risk and septic patients [28, 29] and the concept of ensuring adequate or indeed “supranormal” DO2 to patients undergoing major surgery to reduce complications and death is now fundamental modern perioperative practice. DO2 is usually indexed (i.e. expressed per m2) and expressed as DO2I using the well known equation:



$$ \mathrm{DO}2\mathrm{I} = \frac{\mathrm{SV} \times \mathrm{H}\mathrm{R} \times \mathrm{S}\mathrm{a}\mathrm{O}2 \times \left[\mathrm{H}\mathrm{b}\right] \times 1.34}{\mathrm{BSA}} $$
Where SV = stroke volume, HR = heart rate, SaO2 = oxygen saturation (expressed as fraction), [Hb] = haemoglobin concentration and BSA = body surface area.

Commonly used targets are cardiac index (CI) of >4.5 l min–1 and a DO2I of >600 ml·min–1·m–2 [30]. This forms the basis of modern fluid management as there is a move away from pressure guided fluid therapy (such as blood pressure or central venous pressure – CVP) to flow guided fluid therapy. Given that HR, SaO2 and [Hb] are often not markedly deranged, the major focus is directed at stroke volume optimisation (SVO) according to Frank-Starling curve.

Secondly, an appreciation is required of the consequences of poor fluid management, either with inadequate fluid or excess fluid. The former will ultimately result in a reduced SV, CO and DO2, and morbidity and mortality will be increased, secondary to inadequate tissue perfusion and organ dysfunction. The latter – excess fluid administration – will result in salt and water overload and thus oedema, which will not only effect major organs such as the lung, but critically in colorectal surgery, gut tissues and in particular any anastomosis as well as potentially increasing myocardial workload. Both these extremes of fluid management will therefore ultimately impair tissue oxygenation, leading to anaerobic metabolism, an oxygen debt, lactic acidosis and ultimately organ dysfunction and anastomotic failure. In particular excess fluids increases complications: for every litre of excess increased complications by 32 % [7] and prolonged hospital stay by 1 day [31].

Thus if we accept that excess or inadequate fluid for the patient is harmful and leads to increased morbidity and mortality, the key question is how to find the “sweet spot” of just the right amount of fluid, i.e. achieve SVO. It is just over a 100 years since Starling was credited with the concept that the more a heart muscle is stretched the greater the power of contractility (although the concept was first described 50 years prior to that) [32]. The process of SVO involves measurement and then the administration of an IV fluid bolus of 200–250 ml. The SV is measured again 10–15 min later. If there has been >10 % rise in SV, further boluses are given until SV no longer rises (i.e. optimisation has occurred). Further boluses of fluid are potentially detrimental as SV can reduce with excess of fluid. SVO is sometimes used synonymously with (Individualized) Goal Directed Fluid Therapy (GDFT), but the latter is not restricted to fluids but other methods too (e.g. inotropes) to achieve various targets or goals.

Historically, formulaic methods based on weight, standard 25 years ago (e.g. 5–10 ml/kg/h intraoperatively followed by 3 l in the first 24 h) are generally seen as inferior as they take no account of the patients starting fluid status or cardiac function. Moreover the widely held belief of third space loss and the concomitant requirement to replace these losses is probably flawed [33]. A significant improvement occurred with the adoption of routine CVP monitoring and the use of intermittent estimation of lactate, base excess and central venous oxygen saturation (as a surrogate marker for mixed venous oxygen saturation and hence oxygen extraction) to guide fluid therapy provide a more individualized approach. However, CVP measurement assumes pressure (right atrial pressure) and volume (left ventricular end diastolic volume) measurements are directly correlated which is clearly not always the case e.g. with a poorly compliant myocardium. Arterial and central venous biomarkers are of use but may show a delay of several hours. Thus flow-derived variables such as SVO, whilst not having universal acceptance, are nevertheless regarded as probably the superior method of fluid management.

Nevertheless, how can we make sense of the large amount of studies, some conflicting, in this all-important area? Firstly an appreciation is required in the changes in perioperative care that have occurred which rapidly outdates studies even only a few years old. The ERAS philosophy represents one of the most major changes in modern perioperative care and many of the physiological stresses such as prolonged starvation, the use of bowel preparation have produced a huge change improvement in the fluid status of patients arriving for surgery. Secondly the advent of laparoscopic surgery (vide infra) has dramatically reduced the physiological upset and fluid shifts associated with open surgery. Thirdly, there are various different available methods of measurement of cardiac output (with the majority of good quality data using the oesophageal Doppler monitor (ODM) though some more recent use other method such as arterial waveform analysis e.g. LiDCO rapid). This area has been recently reviewed [34]. Finally, many studies are on various abdominal surgeries and not specific to colorectal.

The key, current area seem are exemplified in the OPTIMISE trial, looking at 734 high-risk patients aged 50 years or older undergoing a variety of major gastrointestinal surgeries [35]. SVO and inotropic support was compared to a control group (CVP guided therapy) during surgery and for 6 h postoperatively. Although complications and 30-day mortality was different to the control group, when included in an updated meta-analysis their intervention group was associated with a reduction in complication rates. Thus we can postulate that SVO probably does no harm, probably reduces complications and probably has no effect on mortality. Two other major reviews would broadly support these findings. The former, most definitive review, studied the effects of increasing perioperative blood flow using fluids (with or without inotropes/vasoactive drugs) and found that mortality was not reduced but three complications – renal failure, respiratory failure, and wound infections – were reduced, with 13 out of every hundred patients treated expected to avoid having complications. The length of stay was also reduced by just over 1 day [36]. The latter systematic review, whilst specifically looing at colorectal surgery had only 691 patients and found no difference in outcome (morbidity and mortality), particularly if GDFT was conducted within modern ‘optimized perioperative care’ [37].

It would seem that the benefits of modern, flow-targeted therapies, using fluids and where necessary inotropes had benefits that have been rather easier to demonstrate in older studies, prior to the adoption of ERAS pathways, and any benefits, are now much harder to prove. Indeed, a recent editorial – Stroke volume Optimization is the fairy tale over? – makes this very point [38]. SVO probably does no harm, and in aerobically fit patients many be unnecessary, but some patients will benefit more than others, especially the very frail and those in whom there is significant blood loss (7 ml/kg), or other large fluid shifts. Overall with the reduction of variability of patient care that comes with protocolised ERAS pathways, preoperative optimization and the reduction of physiological upset have all probably served to negate the earlier benefits of SVO.

This author’s approach to fluid management takes a pragmatic approach of the available evidence. The key areas are [39]



  • Patients should arrive euvolaemic for surgery, aided by avoiding prolonged fasting, mechanical bowel preparation and ingestion of carbohydrate drinks


  • Intraoperative fluid therapy to maintain volume status, usually guided by SVO particularly in high risk patients and/or high risk surgery, with the use of vasopressors (and not fluids) to treat hypotension from anaesthetic vasodilation (e.g. regional blockade) to maintain arterial pressure as they preserve gastrointestinal blood flow) [40, 41]. For low risk patients undergoing low risk surgery a zero-balance approach can be adopted (i.e. merely replacing maintenance fluids of 1–3 mL/kg/h)


  • Maintenance postoperative IV maintenance fluids, avoiding both fluid and saline excess, (e.g. <2.5 L with <100 mmol sodium per 24 h) aiming to transfer to oral fluids as soon as possible. Moreover, “permissive oliguria” [39] should be tolerated, and not chased with IV fluids, unless other signs of hypovolaemia co-exist.

The approach to laparoscopic surgery is dealt with later.


6.4.2 Type of Fluid


The type of fluid administered is also important and has generated a large number of trials, reviews and debates spanning four decades. A recent area of interest as centred on the endothelial gylcocalyx, where excessive volumes of fluid may disrupt this barrier promoting vascular leakage in to the interstitial space [39].

There are a variety of crystalloids available, but there is little doubt that physiologically balanced crystalloids (e.g. Hartmann’s solution and latterly Plasma-Lyte) are superior to 0.9 % saline, which has consistently been reported to cause hyperchloraemic acidosis, itself predisposing to reduced kidney perfusion, reduced gastric blood flow and motility and reduced myocardial contractility [42]. If 0.9 % saline has a place, it is for the treatment of hypocholoraemic alkalosis, such as prolonged vomiting or large volumes of nasogastric aspirate.

Colloids have been preferred by some as the intravascular half-life is improved, providing that the endothelial glycocalyx is intact. Theoretically, a ratio of crystalloid: colloid might be expected to be about 3:1 to meet the same targets, given the early distribution of the two fluids, but a recent meta analysis demonstrated that in practice although there was much variation amongst the studies, the overall ratio was about 1.5:1 [43]. Of the major synthetic colloids – gelatins and starches – the latter have recently fallen into disuse because of the risk of death and renal failure in critically ill patients, although whether or not this can be extrapolated to elective patients is debatable. Many still use gelatin derivatives, although potential disadvantages include cost, allergy and coagulopathy. Albumin, whole blood and blood products are used to replace pre-existing and/or losses deficiencies.

Thus for critically ill patients who may be septic and/or have renal injury, in whom the endothelial glycocalyx may not be intact, many would avoid colloids to exacerbate any renal dysfunction. For other patients, many still use colloids for SVO to limit excess crystalloid (and saline) load, which is a major predictor for adverse outcomes for ERAS patients [7].


6.5 Analgesia


Analgesic requirements for patients undergoing colorectal surgery will clearly depend on the type of surgery – laparoscopic or open. Although they differ, there are nevertheless some principles common to providing analgesia for both types of surgery. Good analgesia is of course a fundamental humanitarian objective for all doctors, but, correctly undertaken, there are other potential benefits too. These include earlier mobilization, reduced organ dysfunction, reduced stress response, an earlier return to a diet and ultimately an earlier discharge from hospital, all of which are key ERAS principles. Moreover, if the analgesic modality reduces early complications, this will also impact on outcome both in the short term and long term (see above). On the horizon, is the prospect of how analgesic technique may impact on survival following major cancer surgery – see below. Thus modern pain medicine has the potential not only to improve patient’s well being in the short term but may also have an effect on long-term survival as well.

The core philosophy is the provision of effective, opioid sparing analgesia. Whilst no drug is free from side effects, opioids, whilst effective analgesics, are widely regarded as undesirable with ERAS pathways, being particularity associated with PONV and slower return of gastrointestinal function, as well as other undesirable effect such as sedation, dysphoria and cough suppression. The provision of opioid sparing analgesia is best undertaken with multimodal analgesia, a concept that is over 20 years old and popularised by Kehlet [44]. In essence it is achieved by combining separate analgesics that act by different mechanisms, resulting in additive or synergistic analgesia with lowered adverse effects compared to sole administration of analgesics individually. Thus a combination of non-opioid analgesic drugs can still result in effective analgesia and a reduction in opioid consumption.

There are a large and growing number of analgesics described for use multimodal use. They can be conveniently classified into local anaesthetic (LA) techniques and systemic analgesics. The former involves blocking the pain pathway between the operation site and onward transmission within the spinal cord, and includes central neuraxial block, (spinal and epidural), nerve plexus blockade, TAP blocks and lastly local anaesthetic into the wound itself. The latter classification includes some very familiar drugs such non steroidal anti inflammatory drugs (NSAIDs), paracetemol, tramadol and perhaps some less familiar agents such as iv lidocaine, steroids, ketamine and magnesium.


6.5.1 Central Neuraxial Block for Open Surgery


Open colorectal surgery usually necessitates a large incision and requires intensive pain relief, usually with either regional blockade (usually an epidural) or parenteral opioids. For many years a thoracic epidural anaesthesia (TEA) was viewed as the gold standard for these patients rather than opioids as it provided a number of well-documented advantages including not only excellent pain relief, but in addition a swifter return of GI function, both as a result of a reduced in opioid requirements but also due to the sympathectomy and a relative increase in parasympathetic action on the gut. Other advantages from other forms of abdominal and pelvic surgery included a reduced VTE rate, reduced blood loss, and a reduction in some aspects of the stress response (pituitary, adrenocortical and sympathetic responses).

However in recent years enthusiasm for epidurals has declined. There are several reasons for this including a significant failure rate with quoted ranges between 13 and 47 %, with a large study describing an incidence of 32 % for thoracic epidurals and 27 % for lumbar epidural [45]. Although in many cases re-siting or adding adjuvants (such as epidural diamorphine) may rectify the situation, a failed epidural not only leaves the patient in pain, but it may also restrict other alternatives (such as systemic opioids) as these drugs cannot be co-administered if the patient is receiving epidural opioids. In addition, although epidurals are widely perceived as safe, the permanent neurological damage can occur, either due to vertebral canal haematoma, abscess and direct trauma. The NAP3 project highlighted the risks associated with postoperative epidurals having the highest incidence of permanent neurological harm, estimated between 1:5 700 – 1:12 200 [46]. Finally patients with epidurals often receive a greater volume of fluids to combat hypotension, which predisposes to fluid overload and can increase hospital stay [31]. These patients should receive vasoactive drugs rather than fluids to combat the sympathectomy [40, 41], but if so the patient will require nursing in an ICU/HDU environment as these agents cannot safely be administered on a ward and without intrarterial monitoring. Whilst epidurals will nevertheless continue to have a place for open surgery, other techniques have been used successfully used such as bilateral Transversus Abdominis Plane (TAP) catheters [47], rectus sheath catheters, and wound catheters which infuse local anaesthetic into the wound edges.


6.5.2 Central Neuraxial Block for Laparoscopic Surgery


Whilst the optimum analgesic technique for open colorectal is well studied and has a good evidence base to support the use of epidurals (even if latterly other modalities nerve blocks are gaining popularity), there is a paucity of data for laparoscopic surgery. Generally these patients’ analgesic requirements are much more modest in both intensity and in duration and although epidurals have been used, they are at best probably not necessary and at worst detrimental. A logical alternative to more the modest analgesic requirements is spinal anaesthesia with local anaesthetic and opioid. This has been used with a degree of success by a number of centres, and was used for patients in the first 23-h stay colorectal resections paper [48]. It offers good intraoperative analgesia extending several hours postoperatively with postoperative opioid sparing, following which a regime of regular simple oral analgesics suffices. Compared to epidurals, spinals permit greater mobilization and with no on-going sympathectomy, results in patients receiving less iv fluids, with their attendant complications [31], although others have found its benefits purely limited to opioid sparing [49]. Whilst spinals are approximately 2½ safer than epidurals [46], they are nevertheless not risk free for neurological damage. In addition, the onset of the sympathectomy is much more rapid than an epidural and caution is required, particularly in the elderly. Also the spinal must have “fixed” before adopting any head down position, so it is advisable to leave 10–15 min before adopting this position. Other forms of one-shot local anaesthetics have also been used, such as TAP blocks and wound infiltration, also with success. As with epidurals for open surgery, after initial success with spinals for laparoscopic surgery, many clinicians are opting for a simpler alternative, such as TAP blocks. Spinals are of little use for very prolonged surgery or if conversion to open surgery occurs.


6.5.3 Peripherally Placed Blocks



6.5.3.1 TAP Blocks


Transversus abdominus plane (TAP) blocks have been used with good effect in both laparoscopic and open surgery for nearly 10 years. A large volume (20 ml) of local anaesthetic is instilled between internal oblique and transversus abdominus muscles, in the lumbar triangle of Petit, whose borders are the external oblique muscle anteriorly, the latissimus dorsi muscle posteriorly and the iliac crest inferiorly. Originally a blind technique using anatomical landmarks was used with a “double pop” as a blunted needle passes through first the external and then the internal oblique muscles (posterior approach). The procedure is probably more safely undertaken using ultrasound and can be undertaken midaxillary line (lateral approach), with latterly a laparoscopic technique having been described. A TAP block provides analgesia from approximately T10-L1 dermatomes covering the incision for the specimen and port sites for laparoscopic bowel surgery, but they may also be used for open surgery too. Bilateral catheters may be used to extend the block duration. A number of studies have shown reductions in morphine use, time to tolerating diet, PONV and length of hospital stay have been described [50, 51]. The posterior approach appears to give more reliable effects [52]. Moreover, preoperative blocks provide better overall outcomes, with a dose response effect of larger dose of LA producing a greater effect on pain scores and reduced opioid consumption [53]. They are generally safe although liver trauma has been described [54].


6.5.3.2 Rectus Sheath Catheters


Rectus sheath catheters (RSC) have been used to provide effective analgesia for major open surgery. They can be inserted by a loss of resistance or ultrasound, but a logical way is for the surgeon to insert them under direct vision too. The catheter is left in situ and LA can be administered either by bolus dosing or via infusion. It has been used successfully particularly in urological surgery, and early work suggests they may provide comparable analgesia to TEA, without the associated problems of hypotension and limited mobility. The results of an ongoing study are awaited comparing TEA versus RSC (TERSC study) for open midline incisions in major abdominal surgery within an enhanced recovery programme [55].


6.5.3.3 Wound Catheters or Surgical Site Analgesia (SSA)


For many years, surgeons have infiltrated long acting local anaesthetic into the wound edges at the end of surgery and it is therefore logical to extend this by the placement of a multi-holed catheter to provide continuous infusion into the postoperative period.

They have been used in many types of surgery, including major orthopaedic surgery, abdominal and pelvic surgery. For open abdominal surgery, these catheters need to be the correct length of the incision and placed in the pre-peritoneal space by the surgeon and so are not suitable for mass closure techniques. Recently there has been renewed interest with good postoperative analgesia described for colorectal surgery [56], and a meta-analysis also demonstrated that they provided broadly similar results to epidural analgesia, with less urinary retention [57]. Two recent studies for open colorectal surgery have provided conflicting results. In one study SSA produced good pain control, faster recovery of postoperative ileus and bowel function with a lower incidence of PONV, and improved night sleep [58]. Another study however, performed within an ERAS protocol, did not replicate these results, with the epidural group having better pain control on the first day, better sleep quality, reduced time to both normal gut function and to hospital discharge [59]. SSAs are a promising, especially as they are relatively simple to manage postoperatively. There were concerns about an increased in wound infection, bit this appears to be unsubstantiated.


6.5.3.4 Intraperitoneal Local Anaesthetic


This technique, which has been used intermittently for over 60 years, has been studied more enthusiastically with the marked increase in laparoscopic operations such as gastric surgery, cholecystectomy, colonic resection and gynecological procedures. It is a promising technique, using for example 20 ml of 0.5 % bupivacaine, resulting in modest reductions in pain scores, opioid consumption and even a reduced stress response activation described. Part of the mechanism may be due to the systemic effect of the local anaesthetic.

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Sep 22, 2016 | Posted by in ANESTHESIA | Comments Off on Enhanced Recovery for Colorectal Surgery

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