Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-05T06:21:38.582Z Has data issue: false hasContentIssue false
  • English
  • Français

Strategies to improve ingestive behaviour with reference to critical illness

Published online by Cambridge University Press:  16 July 2007

Isobel Davidson  and
Sara Smith
Isobel Davidson*
Affiliation:
Dietetics, Nutrition & Biological Sciences, Queen Margaret University, Edinburgh EH12 8TS, UK
Sara Smith
Affiliation:
Dietetics, Nutrition & Biological Sciences, Queen Margaret University, Edinburgh EH12 8TS, UK
*
*Corresponding author: Dr Isobel Davidson, fax +44 131 317 3528, email [email protected]
Rights & Permissions [Opens in a new window]

Abstract

The complex interplay between neural and endocrine responses following food intake regulates ingestive behaviour and ultimately determines subsequent energy intake. These processes include cognitive, gastrointestinal-derived and metabolic mechanisms. Such physiological responses to the ingestion of food initiate short- to medium-term inhibition of intake (satiety). However, in clinical states in which systemic inflammation is evident there is a more profound satiety response and a clear absence of motivation to eat that is evident as loss of appetite. These negative influences on energy intake can contribute to poor nutritional status, and consequently poor physical function, and impact on rehabilitation and recovery. Cytokine mediators of the inflammatory response directly influence feeding behaviour at the hypothalamic nuclei and may explain the lack of motivation and desire for food. However, additional detrimental effects on appetite are brought about because of alterations in intermediary metabolism present in inflammation-induced catabolism. This process forms part of the host response to inflammation and may explain symptoms, such as early satiety, frequently reported in many patient groups. In clinical states, and cancer in particular, pharmacological strategies have been employed to ameliorate the inflammatory response in an attempt to improve energy intake. Some success of this approach has been reported following administration of substrates such as EPA. Novel strategies to improve intake through administration of anti-cytokine drugs such as thalidomide may also be of benefit. However, drugs that oppose the actions of neurotransmitter pathways involved in central induction of satiety, such as 5-hydroxytryptamine, have failed to improve intake but appear to enhance enjoyment of food. Such findings indicate that therapeutic nutritional targets can only be achieved where novel pharmacological therapies can be supported by more innovative and integrated dietary management strategies. Many of these strategies remain to be elucidated.

Keywords

Ingestion behaviourCritical illnessIntervention strategiesGhrelin
Type
Research Article
Information
Proceedings of the Nutrition Society , Volume 66 , Issue 3 , August 2007 , pp. 346 - 350
Copyright
Copyright © The Authors 2007

The regulation of food intake in healthy individuals has an inordinate extent of complexity that requires an understanding of the integration of appetite variables, specific food preferences, food behaviour and psychology as well as the physiological and metabolic responses to nutrient (energy) intake. The biopsychological model put forward by Blundell & Tremblay (Reference Blundell and Tremblay1995) reduces this complex interplay to three key levels (Fig. 1): first, the psychological level that includes appetite sensations and pleasurable or hedonic responses to food as well as food behaviour; second, the physiological and metabolic events occurring in the periphery; third, the level of neurotransmitter, metabolic and possibly nutrient interactions in the brain. Subsequent research has expanded the complexity of the controlling neurotransmitter and peptide pathways (Kirschgessner, Reference Kirschgessner2002; Morton et al. Reference Morton, Cummings, Baskin, Barsh and Schwartz2006), and more peripheral mediators have been identified as important regulators of energy homeostasis (e.g. leptin). Currently, the literature abounds with research investigating the neural and endocrine pathways (Baynes et al. Reference Baynes, Dhillo and Bloom2006) that determine ingestive behaviour, and has primarily been driven by the global epidemic of obesity. However, the model retains its appropriateness for the study of ingestive behaviour in both over- and undernutrition.

Fig. 1. Biological and psychological elements regulating food (energy) intake. NPY, neuropeptide Y; AgRP, Agouti-related protein; POMC, pro-opiomelanocortin; CART, cocaine- and amphetamine-regulated transcript; GLP-1, glucagon-like peptide 1. (Adapted from Blundell & Tremblay, Reference Blundell and Tremblay1995.)

The elucidation of the mechanisms that dictate and influence feeding behaviour are essential to the improvement of nutritional intervention strategies in patients who are underweight or at high risk of developing disease-related malnutrition. This patient group includes those who are critically ill, for whom appropriate and targeted nutritional support can improve functional rehabilitation and outcome (Eneroth et al. Reference Eneroth, Ollson and Thorngrem2006). The general metabolic response to the trauma present in critical illness brings about profound effects on the physiological regulation of ingestive behaviour. These effects are most notable when the development of a systemic inflammation occurs, effecting the orchestration of neuroendocrine responses through pro-inflammatory cytokines that act both locally in a paracrine fashion and distally as endocrine mediators. Thus, both peripherally- and centrally-produced cytokine inflammatory mediators can influence a change in the cognitive and autonomic processing that governs the initiation and cessation of ingestion. The consequences of such a response are to provide anorexigenic signalling to inhibit motivation and desire to eat, reduce energy intake, reduce body weight and alter body composition.

The fact that nutritional demands alter in disease states generally is not in question (Richardson & Davidson, Reference Richardson and Davidson2002). However, homeostatic control is lost during pathophysiological processes involved in the host response to trauma and critical illness, promoting a prevalence of undernutrition in patients requiring critical care. It is unclear how and where the disease process(es) per se and the metabolic response to injury affect the key levels of regulation of appetite variables in relation to ingestive behaviour. However, the extent of wasting and both its psychological and physical consequences are key determinants of recovery and rehabilitation. The body of literature examining the central and peripheral processing that impacts on energy intake shows considerable promise in improving ingestive behaviour in patients in whom loss of appetite and poor intake is evident. However, identification of appropriate targets for intervention in critical illness (and other wasting disorders) poses an important challenge to clinicians because of the heterogeneous nature of such a population and the paucity of research in this area.

Alterations in appetite variables in disease

The development of undernutrition and risk of malnutrition in critical illness (Hill, Reference Hill1996) results in rapid weight loss and overt changes in body composition. Hence, a large proportion of patients with critical illness require to be artificially fed, which can lead to both under- and over-feeding (Reid, Reference Reid2005), primarily as procedures for estimating requirements are not definitive. Whilst the immediate goal is to provide adequate nutrition by whatever means (enteral nutrition, parenteral nutrition or a combination of both), ultimately most patients need to be weaned to resume oral intake. The barriers to resumption are often self reported (and include taste changes, early satiety, poor motivation to eat, no pleasure in eating and too tired to eat) or self-evident, with patients having poor mobility and low functional status. Furthermore, there is no definitive information on whether artificial nutritional support itself is a barrier to resumption and maintenance of oral intake. Research findings on the effects of parenteral feeding on appetite have revealed equivocal results (for review, see Stratton & Elia, Reference Stratton and Elia1999). Most recently, Murray et al. (Reference Murray, Roux, Goueia, Bassett, Ghatei, Bloom, Emmanuel and Gabe2006) have reported little change in appetite variables following infusion of three isoenergetic types of feed to patients with intestinal failure predominantly associated with Crohn's disease. In contrast, patients fed entirely by total parenteral nutrition have been reported as having appetite (hunger) sensations that are distressing (33%) and most (83%) continue to have a strong desire to eat (Stratton et al. Reference Stratton, Stubbs and Elia1998). It is tempting to speculate that maintenance of appetitive sensations when the gut is completely by-passed represents the restoration of the normal drive to eat in the absence of inflammatory mediators. However, evidence from Bannerman et al. (Reference Bannerman, Davidson, Aldhous and Ghosh2001), who addressed the influence of Crohn's disease severity on appetite variables, indicates that baseline appetite sensations are altered. Both desire to eat and hunger ratings are depressed in patients compared with healthy controls, and the greatest suppression of appetite is evident in patients with active disease, as indicated by the Harvey-Bradshaw index (Harvey & Bradshaw, Reference Harvey and Bradshaw1980). This finding may suggest that in this population at least it is the initiation of feeding that contributes to the associated anorexia.

In other disorders in which poor nutritional status is evident and wasting occurs (most extensively reported in cancer patients) early satiety is frequently reported along with anorexia. This outcome has been observed in appetite-rating studies conducted pretransplant in patients with chronic liver disease (McCollum, Reference McCollum2000), for whom levels of hunger and desire to eat were found to be similar to those of healthy controls. However, post-meal satiety ratings were found to be higher and longer lasting in subjects with chronic liver disease, indicating an enhanced satiety response rather than a failure to initiate ingestion. These appetite studies suggest that motivation (meal initiation), satiation (relating to meal length) and satiety (inhibition of eating) may be altered in disease. Since motivation is a behaviour generated centrally and satiety is a peripherally-generated response to the delivery of food to the stomach (distention) and small intestine (incretin-mediated satiety), effective pharmacological intervention to improve ingestive behaviour may need to be targeted both centrally and peripherally. This approach may in turn lead to more effective strategies for weaning patients from enteral tube feeding to resumption of adequate oral intake and may positively impact on rehabilitation and recovery.

Pharmacological strategies to improve ingestive behaviour

The use of appetite stimulants such as megestrol acetate for anorexia associated with cancer has long been considered beneficial (Berenstein & Ortiz, Reference Berenstein and Ortiz2006), with improvements being reported in well-being as well as increased appetite. However, studies in which a positive correlation between appetite and increased energy intake is evident are sparse. The use of cannabinoid receptor agonists is currently being considered because of their application to clinical states other than cancer (Jonsson et al. Reference Jonsson, Holt and Fowler2006). More novel intervention strategies with EPA that had initially shown good promise of reversing the weight loss (Barber et al. Reference Barber, Ross and Fearon1998) and appetite loss in cancer cachexia (Congalves et al. Reference Congalves, Ramos, Romanova, Suzuki, Chen and Meguid2006) associated with pancreatic cancer in particular, now appear questionable (Fearon et al. Reference Fearon, Barber, Moses, Ahmedzai, Taylor, Tisdale and Murray2006). In addition, evidence to support the concomitant repletion of functional tissue that is critical to recovery is less impressive (Bruera et al. Reference Bruera, Strasser, Palmer, Willey, Calder, Amyotte and Baracos2003).

Targeting key neurotransmitter pathways in the hypothalamic nuclei has been proposed as a possible strategy to ameliorate anorexia. However, drugs that oppose the actions of neurotransmitter pathways involved in central induction of satiety, such as 5-hydroxytryptamine, have failed to improve intake (Edelman et al. Reference Edelman, Gandara and Myers1999). On the other hand, they may show some benefit in enhancing enjoyment of food, which in itself is useful, particularly where treatment is palliative in nature. Novel strategies to improve intake through administration of anti-cytokine drugs such as thalidomide (Mantovani et al. Reference Mantovani, Maccio, Massa and Maddedu2001) may also be of benefit.

As a result of the extensive research into obesity that has uncovered peptide pathways both in the brain (hypothalamic nuclei) and mediating communication via the gut–brain axis, novel pharmaceuticals such as incretin mimetics are beginning to emerge as candidates for improving energy intakes in many clinical states (Adrian, Reference Adrian2005; Mayer et al. Reference Mayer, Tillisch and Bradesi2006). In particular, the growth hormone receptor analogue and ‘hunger hormone’ ghrelin has provided encouraging results in conditions in which anorexia is resistant to other interventions.

The case for ghrelin

Of the numerous peptides implicated in feeding behaviour that have been identified recently, one of the most promising that may actually make the leap to clinical usage is ghrelin. The peptide was first discovered as a growth hormone-releasing peptide from the stomach (Kojima et al. Reference Kojima, Hosoda, Date, Nakazato, Matsuo and Kangawa1999). Subsequently, it has shown properties that may be of major benefit to nutritional support in the critically ill, including a dose-dependent increase in gastric motility and promotion of energy storage through adipogenesis (Akamizu & Kengawa, Reference Akamizu and Kengawa2007). The putative anabolic effects of this peptide and the evidence that these effects may involve the inhibition of cytokine release and the action of leptin has generated the suggestion that the presence and extent of inflammation may be associated with plasma ghrelin levels. Very recently, an association between ghrelin levels and inflammatory markers has been confirmed (Akamizu & Kengawa, Reference Akamizu and Kengawa2007). Boyes et al. (Reference Boyes, Stratton, Jackson, Shearman and Elia2006) have demonstrated that elective surgery depresses circulating levels of ghrelin. In addition, in the early post-operative phase (up to 5 d following the surgical insult) ghrelin levels (assessed by area under the curve) are negatively correlated with C-reactive protein. This finding has warranted early trials of the effects of ghrelin administration in patients to address whether nutritional, metabolic and functional outcomes can be improved.

Results of early intervention studies include those of a randomised placebo-controlled trial in malnourished patients (Wynne et al. Reference Wynne, Giannitsopoulou, Small, Patterson, Frost, Ghatei, Brown, Bloom and Choi2005) receiving peritoneal dialysis. Ghrelin was administered before a test meal to patients with mild- to moderate malnutrition, as defined by their global subjective assessment score. A significant increase in energy intake at the meal was reported, with a mean increase of 1047 kJ (P<0·01) compared with the control day. However, no significant differences in daily energy intakes in the 3 d following administration were found, although on each of the days the mean intakes were higher for the treated group. This finding suggests that at best there is a short-term increase in dietary intake following ghrelin administration.

In an attempt to address whether ghrelin could be used to improve functional status in the cachexia associated with chronic obstructive pulmonary disease, Nagaya et al. (Reference Nagaya, Itoh, Murakami, Oya, Uematsu, Miyatake and Kangawa2005) administered ghrelin intravenously over 3 weeks and assessed nutritional and functional status of patients. Significant improvements in functional status determined by hand grip (P<0·05), inspiratory and expiratory pressure (P<0·05) and 6 min timed walk were found. Small but significant increases (P<0·05) in body weight and lean body mass were noted, as well as improved dietary intake assessed by a semi-quantitative method.

Previously, improvements in appetite and energy intake were reported in cancer patients given ghrelin by intravenous infusion (Neary et al. Reference Neary, Small, Wren, Lee, Druce, Palmieri, Frost, Ghatei, Coombes and Bloom2004). In this study energy intake from a buffet lunch was found to increase by 31% in the treatment group compared with placebo group. In addition, patients reported an increased pleasantness of food on ingestion. Adverse effects of food ingestion in patients with cancer often include dialogue on how unpleasant food tastes or ‘that it just doesn't taste the same’ and are a problem in motivating cancer patients to eat. This effect of ghrelin alone should be investigated further to address a key issue in the anorexia of patients with cancer.

Other potential strategies

The extent of metabolic abnormality that accompanies disease determines the utilisation of nutrients, even when adequate energy is provided. This abnormality most commonly includes insulin insensitivity, and in critical illness glycaemic control dramatically influences mortality and morbidity (van den Berghe et al. Reference van den Berghe, Wouters, Bouillon, Weekers, Verwaest, Schetz, Viasselaers, Ferdinande and Lauwers2003). Derangements are common in other disorders in which inflammation is apparent (usually defined as a raised C-reactive protein). This situation promotes a state of catabolism and enhances loss of lean body mass as the preferential fuel supply to the muscle becomes limited. Insulin insensitivity, undernutrition and the presence of inflammation can predict survival in certain conditions such as chronic kidney disease (Stenvinkel, Reference Stenvinkel2006). Attempts to break this catabolic cycle to promote accretion of lean body mass and redress the metabolic picture to one of anabolism have proved successful when exercise intervention strategies have been employed (Milani et al. Reference Milani, Lavie and Mehra2004), and such strategies show concomitant reductions in inflammatory markers (Febbraio & Pedersen, Reference Febbraio and Pedersen2002). Consequent nutritional benefits will undoubtedly accompany this outcome by promotion of an anti-inflammatory state, and in the undernourished patient are likely to include improvement of appetite and ingestive behaviour. Definitive protocols in relation to exercise that are disease specific have been proposed (Pedersen & Saltin, Reference Pedersen and Saltin2006) but have not been universally adopted, and both resistance training and low-intensity exercise appear to be beneficial (Smith et al. Reference Smith, Greig, Jenkins and Davidson2006). In particular, in a population such as the critically ill, for whom suggested protocols may be impractical and unachievable, current physical therapy interventions should be aligned with nutritional support strategies to provide integrated care, so that there is the potential to improve not only ingestive behaviour and functional status but also to impact on disease pathogenesis and progression.

References

Adrian, TE (2005) Importance of gut peptides in gastrointestinal, metabolic and malignant disease. Current Opinion in Endocrinology and Diabetes 12, 8088.Google Scholar
Akamizu, A & Kengawa, K (2007) Emerging results of anticatabolic therapy with ghrelin. Current Opinion in Clinical Nutrition and Metabolic Care 10, 278283.CrossRefGoogle ScholarPubMed
Bannerman, E, Davidson, HIM, Aldhous, M & Ghosh, S (2001) Altered subjective appetite parameters in Crohns disease patients. Clinical Nutrition 20, 399405.Google Scholar
Barber, MD, Ross, JA & Fearon, KCH (1998) An eicosapentaenoic acid-enriched nutritional supplement reverses cachexia in patients with advanced pancreatic cancer. British Journal of Surgery 85, Suppl. 1, 46.Google Scholar
Baynes, KCR, Dhillo, WS & Bloom, SR (2006) Regulation of food intake by gastrointestinal hormones. Current Opinion in Gastroenterology 22, 626631.Google Scholar
Berenstein, EG & Ortiz, Z (2006) Megestrol acetate for the treatment of anorexia-cachexia syndrome. Cochrane Pain, Palliative and Supportive Care Group. The Cochrane Database of Systematic Reviews, issue 4. Chichester, West Sussex: John Wiley and Sons Ltd.Google Scholar
Blundell, J & Tremblay, A (1995) Appetite control and energy (fuel) balance. Nutrition Research Reviews 8, 225242.Google Scholar
Boyes, SA, Stratton, RJ, Jackson, JM, Shearman, CP & Elia, M (2006) Postoperative ghrelin concentrations and the acute phase response after major elective vascular surgery. British Journal of Surgery 93, Suppl. 1, 96.Google Scholar
Bruera, E, Strasser, F, Palmer, LJ, Willey, J, Calder, K, Amyotte, G & Baracos, V (2003) Effect of fish oil on appetite and other parameters in patients with advanced cancer and anorexia/cancer: a double blind placebo controlled study. Journal of Clinical Oncology 21, 129134.Google Scholar
Congalves, CG, Ramos, EC, Romanova, IC, Suzuki, S, Chen, C & Meguid, MM (2006) Omega-3 fatty acids improve appetite in cancer but tumor resecting restores it. Surgery 139, 202208.Google Scholar
Edelman, MJ, Gandara, DR & Myers, FJ (1999) Serotonergic blockade in the treatment of cancer-cachexia anorexia. Cancer 86, 684688.Google Scholar
Eneroth, M, Ollson, U-B & Thorngrem, K-G (2006) Nutritional supplementation decreases hip fracture related complications. Clinical Orthopaedics and Related Research 451, 212217.CrossRefGoogle ScholarPubMed
Fearon, K, Barber, M, Moses, A, Ahmedzai, S, Taylor, G, Tisdale, M & Murray, G (2006) Double-blind, placebo-controlled, randomized study of eicosapentaenoic acid diester in patients with cancer cachexia. Journal of Clinical Oncology 24, 34013407.CrossRefGoogle ScholarPubMed
Febbraio, MA & Pedersen, BK (2002) Muscle derived IL-6: mechanisms for activation and possible biological roles. FASEB Journal 16, 13351347.CrossRefGoogle ScholarPubMed
Harvey, RF & Bradshaw, JM (1980) A simple index of Crohn's-disease activity. Lancet i, 514.CrossRefGoogle Scholar
Hill, GL (1996) Implications of critical illness, injury and sepsis on lean body mass and nutritional needs. Nutrition 16, 197218.Google Scholar
Jonsson, K-O, Holt, S & Fowler, CJ (2006) The endocannabinoid system: current pharmacological research and therapeutic possibilities. Basic Clinical Pharmacology and Toxicology 28, 124134.Google Scholar
Kojima, M, Hosoda, H, Date, Y, Nakazato, M, Matsuo, H & Kangawa, K (1999) Ghrelin is a growth-hormone-releasing acylated peptide from stomach. Nature 402, 656660.Google Scholar
Kirschgessner, AL (2002) Orexins in the brain-gut axis. Endocrine Reviews 23, 115.CrossRefGoogle Scholar
McCollum, K (2000) Appetite and nutritional intake in patients with chronic liver disease. Journal of Human Nutrition and Dietetics 13, 363371.Google Scholar
Mantovani, G, Maccio, A, Massa, E & Maddedu, C (2001) Managing cancer related anorexia/cachexia. Drugs 61, 499514.CrossRefGoogle ScholarPubMed
Mayer, EA, Tillisch, K & Bradesi, S (2006) Review article: modulation of the brain-gut axis as a therapeutic approach in gastrointestinal disease. Alimentary Pharmacology and Therapeutics 24, 919933.CrossRefGoogle ScholarPubMed
Milani, RV, Lavie, CJ & Mehra, MR (2004) Reduction in C-reactive protein through cardiac rehabilitation and exercise training. Journal of the American College of Cardiology 43, 10561061.CrossRefGoogle ScholarPubMed
Morton, GJ, Cummings, DE, Baskin, DG, Barsh, GS & Schwartz, MW (2006) Central nervous system control of food intake and body weight. Nature 443, 289295.CrossRefGoogle ScholarPubMed
Murray, CD, Roux, CW, Goueia, C, Bassett, P, Ghatei, MA, Bloom, SR, Emmanuel, AV & Gabe, SM (2006) The effect of different macronutrient infusions on appetite, ghrelin and peptide YY in parenterally fed patients. Clinical Nutrition 25, 626633.CrossRefGoogle ScholarPubMed
Nagaya, N, Itoh, T, Murakami, S, Oya, H, Uematsu, M, Miyatake, K & Kangawa, K (2005) Treatment of cachexia with ghrelin in patients with COPD. Chest 128, 11871193.Google Scholar
Neary, NM, Small, CJ, Wren, AM, Lee, JL, Druce, MR, Palmieri, C, Frost, GS, Ghatei, MA, Coombes, RC & Bloom, SR (2004) Ghrelin increases energy intake in cancer patients with impaired appetite: acute randomized placebo controlled trial. Journal of Clinical Endocrinology and Metabolism 89, 28322836.Google Scholar
Pedersen, BK & Saltin, B (2006) Evidence for prescribing exercise as therapy in chronic disease. Scandinavian Journal of Medicine and Science in Sports 16, Suppl. 1, 363.CrossRefGoogle ScholarPubMed
Reid, C (2005) Frequency of under and over feeding in mechanically ventilated ICU patients: possible causes and consequences. Journal of Human Nutrition and Dietetics 19, 1322.CrossRefGoogle Scholar
Richardson, RA & Davidson, HIM (2002) Nutritional demands in acute and chronic illness. Proceedings of the Nutrition Society 62, 777781.Google Scholar
Smith, S, Greig, CA, Jenkins, DAS & Davidson, I (2006) Improvements in functional and clinical parameters following a simple 12 month exercise programme in long term haemodialysis patients. Nephrology Dialysis Transplantation 21, Suppl. 4, 472473.Google Scholar
Stenvinkel, P (2006) Inflammation in end stage renal disease: the hidden enemy. Nephrology 11, 3641.CrossRefGoogle ScholarPubMed
Stratton, R & Elia, M (1999) The effects of enteral tube feeding and parenteral nutrition on appetite sensations and food intake in health and disease. Clinical Nutrition 18, 6370.Google Scholar
Stratton, R, Stubbs, J & Elia, M (1998) Appetite and food intake during enteral nutrition. Proceedings of the Nutrition Society 57, 96A.Google Scholar
van den Berghe, G, Wouters, P, Bouillon, R, Weekers, F, Verwaest, C, Schetz, C, Viasselaers, D, Ferdinande, P & Lauwers, P (2003) Outcome benefit of intensive insulin therapy in the critically ill: Insulin dose versus glycaemic control. Critical Care Medicine 31, 359366.Google Scholar
Wynne, K, Giannitsopoulou, K, Small, CJ, Patterson, M, Frost, G, Ghatei, MA, Brown, EA, Bloom, SR & Choi, P (2005) Subcutaneous ghrelin enhances acute food intake in malnourished patients who receive peritoneal dialysis: a randomized placebo controlled trial. Journal of the American Society of Nephrology 16, 21112118.Google Scholar
Figure 0

Fig. 1. Biological and psychological elements regulating food (energy) intake. NPY, neuropeptide Y; AgRP, Agouti-related protein; POMC, pro-opiomelanocortin; CART, cocaine- and amphetamine-regulated transcript; GLP-1, glucagon-like peptide 1. (Adapted from Blundell & Tremblay, 1995.)