The blood electrolytes—sodium, potassium, chloride, and bicarbonate—help regulate nerve and muscle function and maintain acid-base balance and water balance. ... Thus, having electrolytes in the right concentrations (called electrolyte balance) is important in maintaining fluid balance among the compartments
The blood electrolytes—sodium, potassium, chloride, and bicarbonate—help regulate nerve and muscle function and maintain acid-base balance and water balance. ... Thus, having electrolytes in the right concentrations (called electrolyte balance) is important in maintaining fluid balance among the compartments
This presentation covers the basics of molecular hydrogen and frequently asked questions answered by Tyler LeBaron, biochemist and founder of the Molecular Hydrogen Foundation
Tom Selleck Health: A Comprehensive Look at the Iconic Actor’s Wellness Journeygreendigital
Tom Selleck, an enduring figure in Hollywood. has captivated audiences for decades with his rugged charm, iconic moustache. and memorable roles in television and film. From his breakout role as Thomas Magnum in Magnum P.I. to his current portrayal of Frank Reagan in Blue Bloods. Selleck's career has spanned over 50 years. But beyond his professional achievements. fans have often been curious about Tom Selleck Health. especially as he has aged in the public eye.
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Introduction
Many have been interested in Tom Selleck health. not only because of his enduring presence on screen but also because of the challenges. and lifestyle choices he has faced and made over the years. This article delves into the various aspects of Tom Selleck health. exploring his fitness regimen, diet, mental health. and the challenges he has encountered as he ages. We'll look at how he maintains his well-being. the health issues he has faced, and his approach to ageing .
Early Life and Career
Childhood and Athletic Beginnings
Tom Selleck was born on January 29, 1945, in Detroit, Michigan, and grew up in Sherman Oaks, California. From an early age, he was involved in sports, particularly basketball. which played a significant role in his physical development. His athletic pursuits continued into college. where he attended the University of Southern California (USC) on a basketball scholarship. This early involvement in sports laid a strong foundation for his physical health and disciplined lifestyle.
Transition to Acting
Selleck's transition from an athlete to an actor came with its physical demands. His first significant role in "Magnum P.I." required him to perform various stunts and maintain a fit appearance. This role, which he played from 1980 to 1988. necessitated a rigorous fitness routine to meet the show's demands. setting the stage for his long-term commitment to health and wellness.
Fitness Regimen
Workout Routine
Tom Selleck health and fitness regimen has evolved. adapting to his changing roles and age. During his "Magnum, P.I." days. Selleck's workouts were intense and focused on building and maintaining muscle mass. His routine included weightlifting, cardiovascular exercises. and specific training for the stunts he performed on the show.
Selleck adjusted his fitness routine as he aged to suit his body's needs. Today, his workouts focus on maintaining flexibility, strength, and cardiovascular health. He incorporates low-impact exercises such as swimming, walking, and light weightlifting. This balanced approach helps him stay fit without putting undue strain on his joints and muscles.
Importance of Flexibility and Mobility
In recent years, Selleck has emphasized the importance of flexibility and mobility in his fitness regimen. Understanding the natural decline in muscle mass and joint flexibility with age. he includes stretching and yoga in his routine. These practices help prevent injuries, improve posture, and maintain mobilit
micro teaching on communication m.sc nursing.pdfAnurag Sharma
Microteaching is a unique model of practice teaching. It is a viable instrument for the. desired change in the teaching behavior or the behavior potential which, in specified types of real. classroom situations, tends to facilitate the achievement of specified types of objectives.
Lung Cancer: Artificial Intelligence, Synergetics, Complex System Analysis, S...Oleg Kshivets
RESULTS: Overall life span (LS) was 2252.1±1742.5 days and cumulative 5-year survival (5YS) reached 73.2%, 10 years – 64.8%, 20 years – 42.5%. 513 LCP lived more than 5 years (LS=3124.6±1525.6 days), 148 LCP – more than 10 years (LS=5054.4±1504.1 days).199 LCP died because of LC (LS=562.7±374.5 days). 5YS of LCP after bi/lobectomies was significantly superior in comparison with LCP after pneumonectomies (78.1% vs.63.7%, P=0.00001 by log-rank test). AT significantly improved 5YS (66.3% vs. 34.8%) (P=0.00000 by log-rank test) only for LCP with N1-2. Cox modeling displayed that 5YS of LCP significantly depended on: phase transition (PT) early-invasive LC in terms of synergetics, PT N0—N12, cell ratio factors (ratio between cancer cells- CC and blood cells subpopulations), G1-3, histology, glucose, AT, blood cell circuit, prothrombin index, heparin tolerance, recalcification time (P=0.000-0.038). Neural networks, genetic algorithm selection and bootstrap simulation revealed relationships between 5YS and PT early-invasive LC (rank=1), PT N0—N12 (rank=2), thrombocytes/CC (3), erythrocytes/CC (4), eosinophils/CC (5), healthy cells/CC (6), lymphocytes/CC (7), segmented neutrophils/CC (8), stick neutrophils/CC (9), monocytes/CC (10); leucocytes/CC (11). Correct prediction of 5YS was 100% by neural networks computing (area under ROC curve=1.0; error=0.0).
CONCLUSIONS: 5YS of LCP after radical procedures significantly depended on: 1) PT early-invasive cancer; 2) PT N0--N12; 3) cell ratio factors; 4) blood cell circuit; 5) biochemical factors; 6) hemostasis system; 7) AT; 8) LC characteristics; 9) LC cell dynamics; 10) surgery type: lobectomy/pneumonectomy; 11) anthropometric data. Optimal diagnosis and treatment strategies for LC are: 1) screening and early detection of LC; 2) availability of experienced thoracic surgeons because of complexity of radical procedures; 3) aggressive en block surgery and adequate lymph node dissection for completeness; 4) precise prediction; 5) adjuvant chemoimmunoradiotherapy for LCP with unfavorable prognosis.
MANAGEMENT OF ATRIOVENTRICULAR CONDUCTION BLOCK.pdfJim Jacob Roy
Cardiac conduction defects can occur due to various causes.
Atrioventricular conduction blocks ( AV blocks ) are classified into 3 types.
This document describes the acute management of AV block.
Ozempic: Preoperative Management of Patients on GLP-1 Receptor Agonists Saeid Safari
Preoperative Management of Patients on GLP-1 Receptor Agonists like Ozempic and Semiglutide
ASA GUIDELINE
NYSORA Guideline
2 Case Reports of Gastric Ultrasound
Title: Sense of Smell
Presenter: Dr. Faiza, Assistant Professor of Physiology
Qualifications:
MBBS (Best Graduate, AIMC Lahore)
FCPS Physiology
ICMT, CHPE, DHPE (STMU)
MPH (GC University, Faisalabad)
MBA (Virtual University of Pakistan)
Learning Objectives:
Describe the primary categories of smells and the concept of odor blindness.
Explain the structure and location of the olfactory membrane and mucosa, including the types and roles of cells involved in olfaction.
Describe the pathway and mechanisms of olfactory signal transmission from the olfactory receptors to the brain.
Illustrate the biochemical cascade triggered by odorant binding to olfactory receptors, including the role of G-proteins and second messengers in generating an action potential.
Identify different types of olfactory disorders such as anosmia, hyposmia, hyperosmia, and dysosmia, including their potential causes.
Key Topics:
Olfactory Genes:
3% of the human genome accounts for olfactory genes.
400 genes for odorant receptors.
Olfactory Membrane:
Located in the superior part of the nasal cavity.
Medially: Folds downward along the superior septum.
Laterally: Folds over the superior turbinate and upper surface of the middle turbinate.
Total surface area: 5-10 square centimeters.
Olfactory Mucosa:
Olfactory Cells: Bipolar nerve cells derived from the CNS (100 million), with 4-25 olfactory cilia per cell.
Sustentacular Cells: Produce mucus and maintain ionic and molecular environment.
Basal Cells: Replace worn-out olfactory cells with an average lifespan of 1-2 months.
Bowman’s Gland: Secretes mucus.
Stimulation of Olfactory Cells:
Odorant dissolves in mucus and attaches to receptors on olfactory cilia.
Involves a cascade effect through G-proteins and second messengers, leading to depolarization and action potential generation in the olfactory nerve.
Quality of a Good Odorant:
Small (3-20 Carbon atoms), volatile, water-soluble, and lipid-soluble.
Facilitated by odorant-binding proteins in mucus.
Membrane Potential and Action Potential:
Resting membrane potential: -55mV.
Action potential frequency in the olfactory nerve increases with odorant strength.
Adaptation Towards the Sense of Smell:
Rapid adaptation within the first second, with further slow adaptation.
Psychological adaptation greater than receptor adaptation, involving feedback inhibition from the central nervous system.
Primary Sensations of Smell:
Camphoraceous, Musky, Floral, Pepperminty, Ethereal, Pungent, Putrid.
Odor Detection Threshold:
Examples: Hydrogen sulfide (0.0005 ppm), Methyl-mercaptan (0.002 ppm).
Some toxic substances are odorless at lethal concentrations.
Characteristics of Smell:
Odor blindness for single substances due to lack of appropriate receptor protein.
Behavioral and emotional influences of smell.
Transmission of Olfactory Signals:
From olfactory cells to glomeruli in the olfactory bulb, involving lateral inhibition.
Primitive, less old, and new olfactory systems with different path
These simplified slides by Dr. Sidra Arshad present an overview of the non-respiratory functions of the respiratory tract.
Learning objectives:
1. Enlist the non-respiratory functions of the respiratory tract
2. Briefly explain how these functions are carried out
3. Discuss the significance of dead space
4. Differentiate between minute ventilation and alveolar ventilation
5. Describe the cough and sneeze reflexes
Study Resources:
1. Chapter 39, Guyton and Hall Textbook of Medical Physiology, 14th edition
2. Chapter 34, Ganong’s Review of Medical Physiology, 26th edition
3. Chapter 17, Human Physiology by Lauralee Sherwood, 9th edition
4. Non-respiratory functions of the lungs https://academic.oup.com/bjaed/article/13/3/98/278874
Recomendações da OMS sobre cuidados maternos e neonatais para uma experiência pós-natal positiva.
Em consonância com os ODS – Objetivos do Desenvolvimento Sustentável e a Estratégia Global para a Saúde das Mulheres, Crianças e Adolescentes, e aplicando uma abordagem baseada nos direitos humanos, os esforços de cuidados pós-natais devem expandir-se para além da cobertura e da simples sobrevivência, de modo a incluir cuidados de qualidade.
Estas diretrizes visam melhorar a qualidade dos cuidados pós-natais essenciais e de rotina prestados às mulheres e aos recém-nascidos, com o objetivo final de melhorar a saúde e o bem-estar materno e neonatal.
Uma “experiência pós-natal positiva” é um resultado importante para todas as mulheres que dão à luz e para os seus recém-nascidos, estabelecendo as bases para a melhoria da saúde e do bem-estar a curto e longo prazo. Uma experiência pós-natal positiva é definida como aquela em que as mulheres, pessoas que gestam, os recém-nascidos, os casais, os pais, os cuidadores e as famílias recebem informação consistente, garantia e apoio de profissionais de saúde motivados; e onde um sistema de saúde flexível e com recursos reconheça as necessidades das mulheres e dos bebês e respeite o seu contexto cultural.
Estas diretrizes consolidadas apresentam algumas recomendações novas e já bem fundamentadas sobre cuidados pós-natais de rotina para mulheres e neonatos que recebem cuidados no pós-parto em unidades de saúde ou na comunidade, independentemente dos recursos disponíveis.
É fornecido um conjunto abrangente de recomendações para cuidados durante o período puerperal, com ênfase nos cuidados essenciais que todas as mulheres e recém-nascidos devem receber, e com a devida atenção à qualidade dos cuidados; isto é, a entrega e a experiência do cuidado recebido. Estas diretrizes atualizam e ampliam as recomendações da OMS de 2014 sobre cuidados pós-natais da mãe e do recém-nascido e complementam as atuais diretrizes da OMS sobre a gestão de complicações pós-natais.
O estabelecimento da amamentação e o manejo das principais intercorrências é contemplada.
Recomendamos muito.
Vamos discutir essas recomendações no nosso curso de pós-graduação em Aleitamento no Instituto Ciclos.
Esta publicação só está disponível em inglês até o momento.
Prof. Marcus Renato de Carvalho
www.agostodourado.com
Report Back from SGO 2024: What’s the Latest in Cervical Cancer?bkling
Are you curious about what’s new in cervical cancer research or unsure what the findings mean? Join Dr. Emily Ko, a gynecologic oncologist at Penn Medicine, to learn about the latest updates from the Society of Gynecologic Oncology (SGO) 2024 Annual Meeting on Women’s Cancer. Dr. Ko will discuss what the research presented at the conference means for you and answer your questions about the new developments.
Explore natural remedies for syphilis treatment in Singapore. Discover alternative therapies, herbal remedies, and lifestyle changes that may complement conventional treatments. Learn about holistic approaches to managing syphilis symptoms and supporting overall health.
New Directions in Targeted Therapeutic Approaches for Older Adults With Mantl...i3 Health
i3 Health is pleased to make the speaker slides from this activity available for use as a non-accredited self-study or teaching resource.
This slide deck presented by Dr. Kami Maddocks, Professor-Clinical in the Division of Hematology and
Associate Division Director for Ambulatory Operations
The Ohio State University Comprehensive Cancer Center, will provide insight into new directions in targeted therapeutic approaches for older adults with mantle cell lymphoma.
STATEMENT OF NEED
Mantle cell lymphoma (MCL) is a rare, aggressive B-cell non-Hodgkin lymphoma (NHL) accounting for 5% to 7% of all lymphomas. Its prognosis ranges from indolent disease that does not require treatment for years to very aggressive disease, which is associated with poor survival (Silkenstedt et al, 2021). Typically, MCL is diagnosed at advanced stage and in older patients who cannot tolerate intensive therapy (NCCN, 2022). Although recent advances have slightly increased remission rates, recurrence and relapse remain very common, leading to a median overall survival between 3 and 6 years (LLS, 2021). Though there are several effective options, progress is still needed towards establishing an accepted frontline approach for MCL (Castellino et al, 2022). Treatment selection and management of MCL are complicated by the heterogeneity of prognosis, advanced age and comorbidities of patients, and lack of an established standard approach for treatment, making it vital that clinicians be familiar with the latest research and advances in this area. In this activity chaired by Michael Wang, MD, Professor in the Department of Lymphoma & Myeloma at MD Anderson Cancer Center, expert faculty will discuss prognostic factors informing treatment, the promising results of recent trials in new therapeutic approaches, and the implications of treatment resistance in therapeutic selection for MCL.
Target Audience
Hematology/oncology fellows, attending faculty, and other health care professionals involved in the treatment of patients with mantle cell lymphoma (MCL).
Learning Objectives
1.) Identify clinical and biological prognostic factors that can guide treatment decision making for older adults with MCL
2.) Evaluate emerging data on targeted therapeutic approaches for treatment-naive and relapsed/refractory MCL and their applicability to older adults
3.) Assess mechanisms of resistance to targeted therapies for MCL and their implications for treatment selection
Most of the body’s water (about 65%) resides inside cells; this is called intracellular fluid (ICF).
The remaining 35%, called extracellular fluid (ECF), resides outside cells; this includes the fluid between the cells inside tissue (interstitial fluid), as well as the fluid within vessels as blood plasma and lymph.
Other extracellular fluids (cerebrospinal fluid, synovial fluid in the joints, vitreous and aqueous humors of the eye, and digestive secretions) are called transcellular fluid.
Intracellular and extracellular fluid continually mingle as fluid passes through the permeable membrane surrounding each compartment. The concentration of solutes (particularly electrolytes) within each compartment determines the amount and direction of flow.
If the concentration of electrolytes (and therefore the osmolarity) of tissue fluid increases, water moves out of the cells and into the tissues (shown in figure on left).
If the osmolarity of tissue fluid declines, water moves out of the tissues and into the cells (shown in figure on right).
The passage of fluid happens within seconds to maintain equilibrium.
Normally, the amount of water gained and lost by the body each day is equal. (An adult gains and loses about 2,500 mL fluid each day.)
Most fluid intake occurs through eating and drinking; the cells produce a fair amount of water as a by-product of metabolic reactions. (This is called metabolic water.)
Fluid is lost through the kidneys (as urine), the intestines (as feces), the skin (by sweat as well as diffusion), and the lungs (through expired air).
Water loss varies with environmental temperature and physical activity.
When total body water declines (such as by excess sweating), blood pressure drops, sodium concentration rises, and osmolarity increases. This triggers mechanisms to increase intake, as well as mechanisms to decrease output.
Mechanisms to increase intake are shown here.
The same physical changes of a decrease in blood pressure and an increase in osmolarity also trigger these changes.
In dehydration, besides a loss of fluid, the concentration of sodium (and the osmolarity) of the extracellular fluid increases. The increase in osmolarity prompts the shifting of fluid from one compartment to another in an effort to balance the concentration of sodium.
Dehydration results from consuming an inadequate amount of water to cover the amount of water lost. Other causes include diabetes mellitus and the use of diuretics. When severe, fluid deficiency can lead to circulatory collapse.
Because kidneys usually compensate, fluid excess is rarer than fluid deficit.
One cause is renal failure, in which both sodium and water are retained and the extracellular fluid (ECF) remains isotonic.
Another type is water intoxication, which can occur if someone consumes an excessive amount of water or if someone replaces heavy losses of water and sodium (such as from profuse sweating) with just water. This causes the amount of sodium in the ECF to drop; water moves into the cells, causing them to swell.
Complications of either type of fluid excess include pulmonary or cerebral edema.
Although fluid can accumulate in any organ or tissue, it typically affects the lungs, brain, and dependent areas (such as the legs).
A disturbance in any of the factors regulating the movement of fluid between blood plasma and the interstitial compartment—such as electrolyte imbalances, increased capillary pressure, and decreased concentration of plasma proteins—can trigger edema.
Electrolytes drive chemical reactions, affect distribution of the body’s water content, and determine a cell’s electrical potential.
The major cations of the body are sodium (Na+), potassium (K+), calcium (Ca+), and hydrogen (H+). The major anions are chloride (Cl−), bicarbonate (HCO3−), and phosphates (Pi).
Sodium accounts for 90% of the osmolarity of extracellular fluid.
Because it plays a key role in depolarization, it is crucial for proper nerve and muscle function.
Sodium levels are regulated by aldosterone and ADH: aldosterone adjusts the excretion of sodium, and ADH adjusts the excretion of water.
Increased renal absorption of water combined with increased water intake because of thirst cause sodium levels to decline.
Potassium is the chief cation of intracellular fluid; it works with sodium for nerve and muscle function.
Aldosterone regulates serum levels of potassium (just as it does sodium). Increasing potassium levels stimulate the adrenal cortex to secrete aldosterone, which causes the kidneys to excrete potassium as they reabsorb sodium.
Potassium imbalances are the most dangerous of any electrolyte imbalance.
Hyperkalemia may develop suddenly after a crush injury or severe burn; it may occur gradually from the use of potassium-sparing diuretics or renal insufficiency; it may cause fatal cardiac arrhythmias.
Hypokalemia often results from prolonged use of potassium-wasting diuretics. It causes muscle weakness, depressed reflexes, and cardiac arrhythmias.
Hypercalcemia leads to muscle weakness, depressed reflexes, and cardiac arrhythmia.
Hypocalcemia leads to muscle spasms and tetany.
The pH of a solution is determined by its concentration of hydrogen ions.
The body uses chemical and physiological buffers to keep acids and bases in balance.
Bicarbonate buffer system is the main buffering system; it uses bicarbonate and carbonic acid as shown in this equation: CO2 + H2O→ H2CO3→ H+ + HCO3-. The equation moves to the right when the body needs to lower pH and to the left when it needs to raise pH.
Normally, the lungs expel CO2 at the same rate metabolic processes produce it, keeping pH in balance. If CO2 begins to accumulate in the bloodstream, the respiratory physiological buffer system begins to act.
The kidneys are the only buffer system that actually expels H+ ions from the body.
Not all buffer systems act simultaneously: Chemical buffers respond first and can often restore pH within a fraction of a second. The respiratory system responds within 1 to 2 minutes. The renal system takes as long as 24 hours to be initiated.
In acidosis, plasma contains an excess concentration of H+. As the body tries to achieve acid-base balance, H+ moves out of plasma and into cells. The gain of cations inside the cell changes the polarity of the cell. To restore polarity, K+ moves out of the cell as H+ moves in. So: acidosis causes hyperkalemia.
In alkalosis, plasma contains a low concentration of H+; H+ moves out of the cells and into the plasma while K+ moves out of the plasma and into the cells. As a result: alkalosis leads to hypokalemia.
If pH is too low (metabolic acidosis), the respiratory center increases the rate of respirations. The increased respiratory rate “blows off” CO2, which raises pH. In metabolic alkalosis, the pH is too high: breathing slows, allowing CO2 to accumulate, and pH drops.
Although respiratory compensation is powerful, it does not eliminate fixed acids, such as lactic acid or ketone bodies. Renal compensation is also necessary to restore balance in those situations.
The kidneys are the most effective regulators of pH, but they take several hours to days to respond. In response to acidosis, the kidneys eliminate H+ and reabsorb more bicarbonate. In response to alkalosis, the kidneys conserve H+ and excrete more bicarbonate.