The rate of gastric emptying is reduced.

Understanding Gastric Secretions for Surgical Procedures

A basic understanding of gastric secretions is crucial for surgeons, especially when dealing with patients who have undergone acid-lowering procedures or are prescribed anti-secretory drugs. Gastric acid, produced by the parietal cells in the stomach, has a pH of around 2 and is maintained by the H+/K+ ATPase pump. Sodium and chloride ions are actively secreted from the parietal cell into the canaliculus, creating a negative potential across the membrane. Carbonic anhydrase forms carbonic acid, which dissociates, and the hydrogen ions formed by dissociation leave the cell via the H+/K+ antiporter pump. This leaves hydrogen and chloride ions in the canaliculus, which mix and are secreted into the lumen of the oxyntic gland.

There are three phases of gastric secretion: the cephalic phase, gastric phase, and intestinal phase. The cephalic phase is stimulated by the smell or taste of food and causes 30% of acid production. The gastric phase, which is caused by stomach distension, low H+, or peptides, causes 60% of acid production. The intestinal phase, which is caused by high acidity, distension, or hypertonic solutions in the duodenum, inhibits gastric acid secretion via enterogastrones and neural reflexes.

The regulation of gastric acid production involves various factors that increase or decrease production. Factors that increase production include vagal nerve stimulation, gastrin release, and histamine release. Factors that decrease production include somatostatin, cholecystokinin, and secretin. Understanding these factors and their associated pharmacology is essential for surgeons.

In summary, a working knowledge of gastric secretions is crucial for surgical procedures, especially when dealing with patients who have undergone acid-lowering procedures or are prescribed anti-secretory drugs. Understanding the phases of gastric secretion and the regulation of gastric acid production is essential for successful surgical outcomes.

If the tail of the pancreas is damaged during splenectomy, the pancreatic duct may end up draining into the splenic bed. This can result in an increase in amylase levels, but there will be no secretion of glucagon into the pancreatic duct.

Understanding the Anatomy of the Spleen

The spleen is a vital organ in the human body, serving as the largest lymphoid organ. It is located below the 9th-12th ribs and has a clenched fist shape. The spleen is an intraperitoneal organ, and its peritoneal attachments condense at the hilum, where the vessels enter the spleen. The blood supply of the spleen is from the splenic artery, which is derived from the coeliac axis, and the splenic vein, which is joined by the IMV and unites with the SMV.

The spleen is derived from mesenchymal tissue during embryology. It weighs between 75-150g and has several relations with other organs. The diaphragm is superior to the spleen, while the gastric impression is anterior, the kidney is posterior, and the colon is inferior. The hilum of the spleen is formed by the tail of the pancreas and splenic vessels. The spleen also forms the apex of the lesser sac, which contains short gastric vessels.

In conclusion, understanding the anatomy of the spleen is crucial in comprehending its functions and the role it plays in the human body. The spleen’s location, weight, and relations with other organs are essential in diagnosing and treating spleen-related conditions.

The most frequent scenario is for the cystic artery to originate from the right hepatic artery, although there are known variations in the anatomy of the gallbladder’s blood supply.

The gallbladder is a sac made of fibromuscular tissue that can hold up to 50 ml of fluid. Its lining is made up of columnar epithelium. The gallbladder is located in close proximity to various organs, including the liver, transverse colon, and the first part of the duodenum. It is covered by peritoneum and is situated between the right lobe and quadrate lobe of the liver. The gallbladder receives its arterial supply from the cystic artery, which is a branch of the right hepatic artery. Its venous drainage is directly to the liver, and its lymphatic drainage is through Lund’s node. The gallbladder is innervated by both sympathetic and parasympathetic nerves. The common bile duct originates from the confluence of the cystic and common hepatic ducts and is located in the hepatobiliary triangle, which is bordered by the common hepatic duct, cystic duct, and the inferior edge of the liver. The cystic artery is also found within this triangle.

The secretion of gastrin hormone from G cells in the antrum of the stomach is responsible for increasing the secretion of H+ by gastric parietal cells. Additionally, chief cells secrete pepsin, which is a proteolytic enzyme, while D cells in the pancreas and stomach secrete somatostatin hormone. Gastrin hormone is released in response to distension of the stomach and vagal stimulation.

Overview of Gastrointestinal Hormones

Gastrointestinal hormones play a crucial role in the digestion and absorption of food. These hormones are secreted by various cells in the stomach and small intestine in response to different stimuli such as the presence of food, pH changes, and neural signals.

One of the major hormones involved in food digestion is gastrin, which is secreted by G cells in the antrum of the stomach. Gastrin increases acid secretion by gastric parietal cells, stimulates the secretion of pepsinogen and intrinsic factor, and increases gastric motility. Another hormone, cholecystokinin (CCK), is secreted by I cells in the upper small intestine in response to partially digested proteins and triglycerides. CCK increases the secretion of enzyme-rich fluid from the pancreas, contraction of the gallbladder, and relaxation of the sphincter of Oddi. It also decreases gastric emptying and induces satiety.

Secretin is another hormone secreted by S cells in the upper small intestine in response to acidic chyme and fatty acids. Secretin increases the secretion of bicarbonate-rich fluid from the pancreas and hepatic duct cells, decreases gastric acid secretion, and has a trophic effect on pancreatic acinar cells. Vasoactive intestinal peptide (VIP) is a neural hormone that stimulates secretion by the pancreas and intestines and inhibits acid secretion.

Finally, somatostatin is secreted by D cells in the pancreas and stomach in response to fat, bile salts, and glucose in the intestinal lumen. Somatostatin decreases acid and pepsin secretion, decreases gastrin secretion, decreases pancreatic enzyme secretion, and decreases insulin and glucagon secretion. It also inhibits the trophic effects of gastrin and stimulates gastric mucous production.

In summary, gastrointestinal hormones play a crucial role in regulating the digestive process and maintaining homeostasis in the gastrointestinal tract.

Barrett’s oesophagus is characterized by the transformation of the lower oesophageal epithelial cells from stratified squamous to simple columnar epithelium. This change from the normal stratified squamous epithelium increases the risk of oesophageal cancer by 30 times and is often associated with gastro-oesophageal reflux disease.

Metaplasia is a reversible process where differentiated cells transform into another cell type. This change may occur as an adaptive response to stress, where cells sensitive to adverse conditions are replaced by more resilient cell types. Metaplasia can be a normal physiological response, such as the transformation of cartilage into bone. The most common type of epithelial metaplasia involves the conversion of columnar cells to squamous cells, which can be caused by smoking or Schistosomiasis. In contrast, metaplasia from squamous to columnar cells occurs in Barrett’s esophagus. If the metaplastic stimulus is removed, the cells will revert to their original differentiation pattern. However, if the stimulus persists, dysplasia may develop. Although metaplasia is not directly carcinogenic, factors that predispose to metaplasia may induce malignant transformation. The pathogenesis of metaplasia involves the reprogramming of stem cells or undifferentiated mesenchymal cells present in connective tissue, which differentiate along a new pathway.

The renal artery provides branches that supply the proximal ureter, while other feeding vessels are described in the following.

Anatomy of the Ureter

The ureter is a muscular tube that measures 25-35 cm in length and is lined by transitional epithelium. It is surrounded by a thick muscular coat that becomes three muscular layers as it crosses the bony pelvis. This retroperitoneal structure overlies the transverse processes L2-L5 and lies anterior to the bifurcation of iliac vessels. The blood supply to the ureter is segmental and includes the renal artery, aortic branches, gonadal branches, common iliac, and internal iliac. It is important to note that the ureter lies beneath the uterine artery.

In summary, the ureter is a vital structure in the urinary system that plays a crucial role in transporting urine from the kidneys to the bladder. Its unique anatomy and blood supply make it a complex structure that requires careful consideration in any surgical or medical intervention.

The level at which the oesophagus passes through the diaphragm is T10, which is also where the oesophageal hiatus is located. When the stomach protrudes through this opening, it is referred to as a hiatus hernia.

Understanding Diaphragm Apertures

The diaphragm is a muscle that separates the chest cavity from the abdominal cavity and plays a crucial role in respiration. Diaphragm apertures are openings within this muscle that allow specific structures to pass from the thoracic cavity to the abdominal cavity. The three main apertures are the aortic hiatus at T12, the oesophageal hiatus at T10, and the vena cava foramen at T8. To remember the vertebral levels of these apertures, a useful mnemonic involves counting the total number of letters in the spellings of vena cava (8), oesophagus (10), and aortic hiatus (12).

In addition to these main apertures, smaller openings in the diaphragm exist in the form of lesser diaphragmatic apertures. These allow much smaller structures to pass through the thoracic cavity into the abdomen across the diaphragm. Examples of lesser diaphragmatic apertures include the left phrenic nerve, small veins, superior epigastric artery, intercostal nerves and vessels, subcostal nerves and vessels, splanchnic nerves, and the sympathetic trunk. Understanding the diaphragm and its apertures is important in the diagnosis and treatment of various medical conditions.

Ascites is a medical condition characterized by the accumulation of abnormal amounts of fluid in the abdominal cavity. The causes of ascites can be classified into two groups based on the serum-ascites albumin gradient (SAAG) level. If the SAAG level is greater than 11g/L, it indicates portal hypertension, which is commonly caused by liver disorders such as cirrhosis, alcoholic liver disease, and liver metastases. Other causes of portal hypertension include cardiac conditions like right heart failure and constrictive pericarditis, as well as infections like tuberculous peritonitis. On the other hand, if the SAAG level is less than 11g/L, ascites may be caused by hypoalbuminaemia, malignancy, pancreatitis, bowel obstruction, and other conditions.

The management of ascites involves reducing dietary sodium and sometimes fluid restriction if the sodium level is less than 125 mmol/L. Aldosterone antagonists like spironolactone are often prescribed, and loop diuretics may be added if necessary. Therapeutic abdominal paracentesis may be performed for tense ascites, and large-volume paracentesis requires albumin cover to reduce the risk of complications. Prophylactic antibiotics may also be given to prevent spontaneous bacterial peritonitis. In some cases, a transjugular intrahepatic portosystemic shunt (TIPS) may be considered.

This patient has been diagnosed with Crohn’s disease, which is characterized by a long history of abdominal pain, weight loss, and diarrhea. Unlike ulcerative colitis, which only affects the colon, Crohn’s disease can affect any part of the gastrointestinal tract. In this case, oral mucosal ulceration is also present. The classic cobblestone appearance on endoscopy is due to deep ulceration in the gut mucosa with skip lesions in between.

On the other hand, loss of haustra is a finding seen in chronic ulcerative colitis on fluoroscopy. The chronic inflammatory process in the mucosal and submucosal layers of the colon can cause luminal narrowing, resulting in a drainpipe colon that is shortened and narrowed. In UC, shallow ulceration occurs in the mucosa, with spared mucosa giving rise to the appearance of polyps, also known as pseudopolyps. These can cause bloody diarrhea.

Inflammatory bowel disease (IBD) is a condition that includes two main types: Crohn’s disease and ulcerative colitis. Although they share many similarities in terms of symptoms, diagnosis, and treatment, there are some key differences between the two. Crohn’s disease is characterized by non-bloody diarrhea, weight loss, upper gastrointestinal symptoms, mouth ulcers, perianal disease, and a palpable abdominal mass in the right iliac fossa. On the other hand, ulcerative colitis is characterized by bloody diarrhea, abdominal pain in the left lower quadrant, tenesmus, gallstones, and primary sclerosing cholangitis. Complications of Crohn’s disease include obstruction, fistula, and colorectal cancer, while ulcerative colitis has a higher risk of colorectal cancer than Crohn’s disease. Pathologically, Crohn’s disease lesions can be seen anywhere from the mouth to anus, while ulcerative colitis inflammation always starts at the rectum and never spreads beyond the ileocaecal valve. Endoscopy and radiology can help diagnose and differentiate between the two types of IBD.

Using CEA as a screening tool for colonic cancer is not justifiable. While it is true that CEA levels are elevated in colonic cancer, this is also the case in non-malignant conditions such as cirrhosis and colitis. Additionally, the highest levels of CEA are typically seen in cases of metastatic disease. Therefore, CEA should not be used to monitor colitis patients for the development of colonic cancer. This information is supported by a study published in the BMJ in 2009.

Diagnosis and Staging of Colorectal Cancer

Diagnosis of colorectal cancer is typically done through a colonoscopy, which is considered the gold standard as long as it is complete and provides good mucosal visualization. Other options for diagnosis include double-contrast barium enema and CT colonography. Once a malignant diagnosis is made, patients will undergo staging using chest, abdomen, and pelvic CT scans. Patients with rectal cancer will also undergo evaluation of the mesorectum with pelvic MRI scanning. For examination purposes, the Dukes and TNM systems are preferred.

Tumour Markers in Colorectal Cancer

Carcinoembryonic antigen (CEA) is the main tumour marker in colorectal cancer. While not all tumours secrete CEA, it is still used as a marker for disease burden and is once again being used routinely in follow-up. However, it is important to note that CEA levels may also be raised in conditions such as IBD.