Generally speaking, if a child shows clinical signs of dehydration but does not exhibit shock, it can be assumed that they are 5% dehydrated. On the other hand, if shock is also present, it can be assumed that the child is 10% dehydrated or more. To put it in simpler terms, 5% dehydration means that the body has lost 5 grams of fluid per 100 grams of body weight, which is equivalent to 50 milliliters per kilogram of fluid. Similarly, 10% dehydration implies a loss of 100 milliliters per kilogram of fluid.

The clinical features of dehydration are summarized below:

Dehydration (5%):
– The child appears unwell
– The heart rate may be normal or increased (tachycardia)
– The respiratory rate may be normal or increased (tachypnea)
– Peripheral pulses are normal
– Capillary refill time (CRT) is normal or slightly prolonged
– Blood pressure is normal
– Extremities feel warm
– Decreased urine output
– Reduced skin turgor
– Sunken eyes
– Depressed fontanelle
– Dry mucous membranes

Clinical shock (10%):
– The child appears pale, lethargic, and mottled
– Tachycardia (increased heart rate)
– Tachypnea (increased respiratory rate)
– Weak peripheral pulses
– Prolonged CRT
– Hypotension (low blood pressure)
– Extremities feel cold
– Decreased urine output
– Decreased level of consciousness

Klumpke’s palsy, also known as Dejerine-Klumpke palsy, is a condition where the arm becomes paralyzed due to an injury to the lower roots of the brachial plexus. The most commonly affected root is C8, but T1 can also be involved. The main cause of Klumpke’s palsy is when the arm is pulled forcefully in an outward position during a difficult childbirth. It can also occur in adults with apical lung carcinoma (Pancoast’s syndrome).

Clinically, Klumpke’s palsy is characterized by a deformity known as ‘claw hand’, which is caused by the paralysis of the intrinsic hand muscles. There is also a loss of sensation along the ulnar side of the forearm and hand. In some cases where T1 is affected, a condition called Horner’s syndrome may also be present.

Klumpke’s palsy can be distinguished from Erb’s palsy, which affects the upper roots of the brachial plexus (C5 and sometimes C6). In Erb’s palsy, the arm hangs by the side with the elbow extended and the forearm turned inward (known as the ‘waiter’s tip sign’). Additionally, there is a loss of shoulder abduction, external rotation, and elbow flexion.

The recommended target SpO2, which measures the percentage of oxygen saturation in the blood, following a cardiac arrest is 94-98%. This range ensures that the patient receives adequate oxygenation without the risk of hyperoxia, which is an excess of oxygen in the body.

Further Reading:

Cardiopulmonary arrest is a serious event with low survival rates. In non-traumatic cardiac arrest, only about 20% of patients who arrest as an in-patient survive to hospital discharge, while the survival rate for out-of-hospital cardiac arrest is approximately 8%. The Resus Council BLS/AED Algorithm for 2015 recommends chest compressions at a rate of 100-120 per minute with a compression depth of 5-6 cm. The ratio of chest compressions to rescue breaths is 30:2.

After a cardiac arrest, the goal of patient care is to minimize the impact of post cardiac arrest syndrome, which includes brain injury, myocardial dysfunction, the ischaemic/reperfusion response, and the underlying pathology that caused the arrest. The ABCDE approach is used for clinical assessment and general management. Intubation may be necessary if the airway cannot be maintained by simple measures or if it is immediately threatened. Controlled ventilation is aimed at maintaining oxygen saturation levels between 94-98% and normocarbia. Fluid status may be difficult to judge, but a target mean arterial pressure (MAP) between 65 and 100 mmHg is recommended. Inotropes may be administered to maintain blood pressure. Sedation should be adequate to gain control of ventilation, and short-acting sedating agents like propofol are preferred. Blood glucose levels should be maintained below 8 mmol/l. Pyrexia should be avoided, and there is some evidence for controlled mild hypothermia but no consensus on this.

Post ROSC investigations may include a chest X-ray, ECG monitoring, serial potassium and lactate measurements, and other imaging modalities like ultrasonography, echocardiography, CTPA, and CT head, depending on availability and skills in the local department. Treatment should be directed towards the underlying cause, and PCI or thrombolysis may be considered for acute coronary syndrome or suspected pulmonary embolism, respectively.

Patients who are comatose after ROSC without significant pre-arrest comorbidities should be transferred to the ICU for supportive care. Neurological outcome at 72 hours is the best prognostic indicator of outcome.

This patient is exhibiting the psoas sign, which is a medical indication of irritation in the iliopsoas group of hip flexors located in the abdomen. In this particular case, it is highly likely that the patient has acute appendicitis.

The psoas sign can be observed by extending the patient’s thigh while they are lying on their side with their knees extended, or by asking the patient to actively flex their thigh at the hip. If these movements result in abdominal pain or if the patient resists due to pain, then the psoas sign is considered positive.

The pain occurs because the psoas muscle is adjacent to the peritoneal cavity. When the muscles are stretched or contracted, they rub against the inflamed tissues nearby, causing discomfort. This strongly suggests that the appendix is positioned retrocaecal.

Pyloric stenosis is a condition that primarily affects infants and is often seen in those with a positive family history. It is more commonly observed in first-born children and those who were bottle-fed or delivered by c-section. Additionally, it is more prevalent in white and hispanic children compared to other races and ethnicities. Smoking during pregnancy and premature birth are also associated with an increased risk of developing pyloric stenosis.

Further Reading:

Pyloric stenosis is a condition that primarily affects infants, characterized by the thickening of the muscles in the pylorus, leading to obstruction of the gastric outlet. It typically presents between the 3rd and 12th weeks of life, with recurrent projectile vomiting being the main symptom. The condition is more common in males, with a positive family history and being first-born being additional risk factors. Bottle-fed children and those delivered by c-section are also more likely to develop pyloric stenosis.

Clinical features of pyloric stenosis include projectile vomiting, usually occurring about 30 minutes after a feed, as well as constipation and dehydration. A palpable mass in the upper abdomen, often described as like an olive, may also be present. The persistent vomiting can lead to electrolyte disturbances, such as hypochloremia, alkalosis, and mild hypokalemia.

Ultrasound is the preferred diagnostic tool for confirming pyloric stenosis. It can reveal specific criteria, including a pyloric muscle thickness greater than 3 mm, a pylorus longitudinal length greater than 15-17 mm, a pyloric volume greater than 1.5 cm3, and a pyloric transverse diameter greater than 13 mm.

The definitive treatment for pyloric stenosis is pyloromyotomy, a surgical procedure that involves making an incision in the thickened pyloric muscle to relieve the obstruction. Before surgery, it is important to correct any hypovolemia and electrolyte disturbances with intravenous fluids. Overall, pyloric stenosis is a relatively common condition in infants, but with prompt diagnosis and appropriate management, it can be effectively treated.

Placental abruption, also known as abruptio placentae, occurs when the placental lining separates from the wall of the uterus before delivery and after 20 weeks of gestation.

In the early stages, there may be no symptoms, but typically abdominal pain and vaginal bleeding develop. Approximately 20% of patients experience a concealed placental abruption, where the haemorrhage is confined within the uterine cavity and the amount of blood loss can be significantly underestimated.

The clinical features of placental abruption include sudden onset abdominal pain (which can be severe), variable vaginal bleeding, severe or continuous contractions, abdominal tenderness, and an enlarged, tense uterus. The foetus often shows signs of distress, such as reduced movements, increased or decreased fetal heart rate, decreased variability of fetal heart rate, and late decelerations.

In contrast, placenta praevia is painless and the foetal heart is generally normal. The degree of obstetric shock is usually proportional to the amount of vaginal blood loss. Another clue that the cause of bleeding is placenta praevia rather than placental abruption is that the foetus may have an abnormal presentation or lie.

The primary approach to managing nerve gas exposure through medication involves the repeated administration of antidotes. The two antidotes utilized for this purpose are atropine and pralidoxime.

Atropine is the standard anticholinergic medication employed to address the symptoms associated with nerve agent poisoning. It functions as an antagonist for muscarinic acetylcholine receptors, effectively blocking the effects caused by excessive acetylcholine. Initially, a 1.2 mg intravenous bolus of atropine is administered. This dosage is then repeated and doubled every 2-3 minutes until excessive bronchial secretion ceases and miosis (excessive constriction of the pupil) resolves. In some cases, as much as 100 mg of atropine may be necessary.

Pralidoxime (2-PAMCl) is the standard oxime used in the treatment of nerve agent poisoning. Its mechanism of action involves reactivating acetylcholinesterase by scavenging the phosphoryl group attached to the functional hydroxyl group of the enzyme, thereby counteracting the effects of the nerve agent itself. For patients who are moderately or severely poisoned, pralidoxime should be administered intravenously at a dosage of 30 mg/kg of body weight (or 2 g in the case of an adult) over a period of four minutes.

Ketamine sedation in children should only be performed by a trained and competent clinician who is capable of managing complications, especially those related to the airway. The clinician should have completed the necessary training and have the appropriate skills for procedural sedation. It is important for the clinician to consider the length of the procedure before deciding to use ketamine sedation, as lengthy procedures may be more suitable for general anesthesia.

Examples of procedures where ketamine may be used in children include suturing, fracture reduction/manipulation, joint reduction, burn management, incision and drainage of abscess, tube thoracostomy placement, foreign body removal, and wound exploration/irrigation.

During the ketamine sedation procedure, a minimum of three staff members should be present: a doctor to manage the sedation and airway, a clinician to perform the procedure, and an experienced nurse to monitor and support the patient, family, and clinical staff. The child should be sedated and managed in a high dependency or resuscitation area with immediate access to resuscitation facilities. Monitoring should include sedation level, pain, ECG, blood pressure, respiration, pulse oximetry, and capnography, with observations taken and recorded every 5 minutes.

Prior to the procedure, consent should be obtained from the parent or guardian after discussing the proposed procedure and use of ketamine sedation. The risks and potential complications should be explained, including mild or moderate/severe agitation, rash, vomiting, transient clonic movements, and airway problems. The parent should also be informed that certain common side effects, such as nystagmus, random purposeless movements, muscle twitching, rash, and vocalizations, are of no clinical significance.

Topical anesthesia may be considered to reduce the pain of intravenous cannulation, but this step may not be advisable if the procedure is urgent. The clinician should also ensure that key resuscitation drugs are readily available and doses are calculated for the patient in case they are needed.

Before administering ketamine, the child should be prepared by encouraging the parents or guardians to talk to them about happy thoughts and topics to minimize unpleasant emergence phenomena. The dose of ketamine is typically 1.0 mg/kg by slow intravenous injection over at least one minute, with additional doses of 0.5 mg/kg administered as required after 5-10 minutes to achieve the desired dissociative state.

Common causes for different acid-base disorders.

Respiratory alkalosis can be caused by hyperventilation, such as during periods of anxiety. It can also be a result of conditions like pulmonary embolism, CNS disorders (such as stroke or encephalitis), altitude, pregnancy, or the early stages of aspirin overdose.

Respiratory acidosis is often associated with chronic obstructive pulmonary disease (COPD) or life-threatening asthma. It can also occur due to pulmonary edema, sedative drug overdose (such as opiates or benzodiazepines), neuromuscular disease, obesity, or other respiratory conditions.

Metabolic alkalosis can be caused by vomiting, potassium depletion (often due to diuretic usage), Cushing’s syndrome, or Conn’s syndrome.

Metabolic acidosis with a raised anion gap can occur due to lactic acidosis (such as in cases of hypoxemia, shock, sepsis, or infarction) or ketoacidosis (such as in diabetes, starvation, or alcohol excess). It can also be a result of renal failure or poisoning (such as in late stages of aspirin overdose, methanol or ethylene glycol ingestion).

Metabolic acidosis with a normal anion gap can be caused by conditions like renal tubular acidosis, diarrhea, ammonium chloride ingestion, or adrenal insufficiency.

The standard facial X-ray series consists of two occipitomental x-rays: the Occipitomental (or Occipitomental 15º) and the Occipitomental 30º. The Occipitomental view captures the upper and middle thirds of the face, showing important structures such as the orbital margins, frontal sinuses, zygomatic arches, and maxillary antra. On the other hand, the Occipitomental 30º view uses a 30º caudal angulation, resulting in a less clear visualization of the orbits but a clearer view of the zygomatic arches and the walls of the maxillary antra.

Further Reading:

Zygomatic injuries, also known as zygomatic complex fractures, involve fractures of the zygoma bone and often affect surrounding bones such as the maxilla and temporal bones. These fractures can be classified into four positions: the lateral and inferior orbital rim, the zygomaticomaxillary buttress, and the zygomatic arch. The full extent of these injuries may not be visible on plain X-rays and may require a CT scan for accurate diagnosis.

Zygomatic fractures can pose risks to various structures in the face. The temporalis muscle and coronoid process of the mandible may become trapped in depressed fractures of the zygomatic arch. The infraorbital nerve, which passes through the infraorbital foramen, can be injured in zygomaticomaxillary complex fractures. In orbital floor fractures, the inferior rectus muscle may herniate into the maxillary sinus.

Clinical assessment of zygomatic injuries involves observing facial asymmetry, depressed facial bones, contusion, and signs of eye injury. Visual acuity must be assessed, and any persistent bleeding from the nose or mouth should be noted. Nasal injuries, including septal hematoma, and intra-oral abnormalities should also be evaluated. Tenderness of facial bones and the temporomandibular joint should be assessed, along with any step deformities or crepitus. Eye and jaw movements must also be evaluated.

Imaging for zygomatic injuries typically includes facial X-rays, such as occipitomental views, and CT scans for a more detailed assessment. It is important to consider the possibility of intracranial hemorrhage and cervical spine injury in patients with facial fractures.

Management of most zygomatic fractures can be done on an outpatient basis with maxillofacial follow-up, assuming the patient is stable and there is no evidence of eye injury. However, orbital floor fractures should be referred immediately to ophthalmologists or maxillofacial surgeons. Zygomatic arch injuries that restrict mouth opening or closing due to entrapment of the temporalis muscle or mandibular condyle also require urgent referral. Nasal fractures, often seen in conjunction with other facial fractures, can be managed by outpatient ENT follow-up but should be referred urgently if there is uncontrolled epistaxis, CSF rhinorrhea, or septal hematoma.