MCAT Basics (from MedSchoolCoach)

In this episode, we'll break down the intricate processes of nutrient digestion and absorption, from the mechanical and chemical digestion in the stomach to the vital role of the small and large intestines. We'll also discuss the regulatory mechanisms involving hormones and nervous innervation and the essential structures like the liver, gallbladder, and pancreas. And don't forget, this episode is packed with tips on everything you need to know about this high-yield topic for the MCAT. So grab your notes, get comfortable, and let's embark on this fascinating journey through the digestive system. Stay tuned for a deep dive into how our bodies turn food into the vital nutrients we need to thrive. Visit MedSchoolCoach.com for more help with the MCAT. Jump into the conversation: [00:00] Introduction to the MCAT Basics [05:11] Digestive system involves mechanical and chemical processes. [06:55] Food travels through digestive system over time. [10:48] Small intestines: duodenum, jejunum, ileum, enterocytes crucial. [14:38] Sphincters in digestive system control food movement. [16:26] Podcast discusses physiology of digestive system structures. [20:57] Salivary enzyme breaks down starch into glucose. [23:46] Muscle contractions propel food through digestive system. [27:40] Lipase enzyme breaks down fats in stomach. [29:11] Stomach doesn't absorb nutrients, protects itself. [32:55] Enzymes linked to cells for carbohydrate breakdown. [38:05] Bile emulsifies fat, chylomicrons enter lymphatic system. [41:35] Gut bacteria metabolize cellulose, form fatty acids. [45:02] Living without large intestine; regulation of digestion. [46:50] CCK stimulates pancreatic juice release, important digestion. [49:57] Prepare for MCAT and excel with us!  

In this episode of MCAT Basics, we’ll cover Electrochemistry. We start with the role of salt bridges in electrochemical cells and cover the intricacies of cell notation. We’ll also discuss how ions maintain charge balance, the importance of reduction and oxidation potentials, and how these elements come together in galvanic and electrolytic cells. We’ll also take a closer look at concentration cells and the critical Nernst equation, which helps us understand cell potentials under non-standard conditions. Visit MedSchoolCoach.com for more help with the MCAT. Jump into the Conversation: [00:00] Introduction to MCAT Basics [01:09} Introduction to Electrochemistry [03:20] Concentration cell: same metal, different ion concentrations [13:05] Visualizing galvanic cells using royal analogy [22:19] Reduction potential, oxidation potential, cell potential explained [30:47] Electrochemical cells, Gibbs free energy, and Nernst equation [41:16] Electroplating and electric current to coat metals [45:40] Electrochemistry in Nanobiology: measuring oxidation of molecules  

This MCAT Basics podcast covers biological membranes. First, the podcast introduces a few topics regarding membranes: what they are, how they are formed, their presence in the cell, and cell-to-cell junctions. Second, it addresses transport through the membrane, including simple diffusion, active vs. passive transport, and transport membrane proteins. Next, the discussion moves to membrane proteins, including receptors, transporters, and the differences between integral, peripheral, and lipid-anchored proteins. Finally, the podcast covers membrane dynamics, such as endocytosis and the transmembrane system, and discusses membrane potential.   Visit MedSchoolCoach.com for more help with the MCAT.   Jump into the Conversation: [00:00] Intro into MCAT Basics [01:08] Introducing Biological Membranes [01:53] What is a membrane and what is its structure [15:33] Cell to cell junctions and the involvement of plasma membranes [17:16] Transport through a membrane [26:49] Membrane proteins [31:05] Membrane dynamics and potential  

In this episode, we’ll talk about  ATP or adenosine triphosphate. We will begin with a detailed examination of ATP's structure and composition as a nucleotide, followed by an explanation of the metabolic pathways involved in its production—both aerobic and anaerobic. We will also cover the pivotal process of ATP hydrolysis, emphasizing its energy release and crucial role in various cellular processes, including the sodium-potassium pump and protein phosphorylation. Additionally, we will address the limitations of ATP supplementation and the broader implications of ATP in biological transport and biosynthesis processes. This episode promises to provide a clear and thorough understanding of ATP's essential functions, ensuring you are well-prepared for your MCAT studies. Visit MedSchoolCoach.com for more help with the MCAT.   Jump Into the Conversation: [00:00] Intro into Adenosine Triphosphate, otherwise known as ATP [2:09] The structure of ATP  [06:48] Where and how ATP is produced [24:04] Thermodynamics of ATP [35:16] The functions of ATP [35:31] Sodium-potassium pump or the sodium-potassium ATPase [39:45] Protein kinases and protein phosphorylation [42:48] ATP binding cassette transporter protein or ABC transporter proteins  

In this episode, we explore the topic of intelligence, which is primarily featured in the psychology and sociology section of the MCAT. We cover several key theories, including entity vs. incremental theory, general intelligence theory, two-factor theory, multiple intelligences theory, Triarchic theory, CHC theory, and biological theories. Additionally, we examine the nature vs. nurture debate on hereditary intelligence factors and discuss how intelligence is measured. Visit MedSchoolCoach.com for more help with the MCAT.   Jump Into the Conversation: [00:00] Intro to Intelligence [02:47] Entity vs. Incremental Theory [06:36] G Factor Theory [10:26] Multiple Intelligences Theory [12:18] Triarchic Theory [14:39] CHC Theory [18:58] Theories of Intelligence [21:01] Hereditary factors of intelligence  [28:33] How intelligence is measured [32:06] Why intelligence tests can be problematic  

Redox reactions or reduction and oxidation are reactions in which electrons are simultaneously transferred from one chemical species to another. This episode begins with exploring this concept, including an in-depth look at oxidizing and reducing agents and the factors determining a compound's effectiveness as an oxidizing agent.  It also covers the oxidation states of molecules and functional groups, common redox reagents in organic chemistry, and the role of redox in biological systems. The episode also addresses numerical concepts from general chemistry related to redox, such as determining oxidation numbers and understanding electrochemical cells. Visit MedSchoolCoach.com for more help with the MCAT.   [00:00] Introduction [01:09] What is the conceptual definition of redox [06:22] What is an oxidizing agent, and what is a reducing agent? [08:50] What makes a molecule better than another at being an oxidizing agent or a reducing agent? [13:58] Which oxidation reduction reagents should you know and what do they [21:44] Redox in biological systems [35:01] How to determine the oxidation state [41:16] The application of oxidation-reduction in electrochemical cells  

In this episode, we focus on the physiology of sound and hearing. We begin by exploring sound-related concepts, including sound waves, pitch, ultrasound, and the decibel system. Next, we delve into the anatomy and physiology of the ear, providing a clear understanding of how we perceive sound. This material will appear in two of the four MCAT sections: the Bio/Biochem and Physics/Chemistry sections. Visit MedSchoolCoach.com for more help with the MCAT.   [00:00] Introduction [01:50] Physics of sound waves [06:07] Wavelength and frequency equation [08:08] Equation for the speed of sound [11:01] Overall takeaway for the MCAT [11:15] Ultrasound imaging [14:23] The decibel system [18:05] Anatomy and physiology of the ear

Discover the fascinating world of the eye, from its intricate anatomy to the roles of rods and cones. Explore the phototransduction pathway and how visual information is processed. Learn about the nuances of perception, including visual field processing and the differences between binocular and monocular cues. Delve into feature detection with insights on Magno and Parvo pathways, revealing how our brains interpret motion and detail. This engaging discussion enhances your understanding of vision while providing essential MCAT prep insights.

Dive into the fascinating world of the adaptive immune system! Learn the essential vocabulary that sets the stage for understanding immune responses. Discover the dynamic roles of B cells in humoral immunity and T cells in cell-mediated immunity. Explore how these cells remember past infections to better protect the body. Unravel the intricacies of antigen presentation and the activation of T cells, revealing the complexity and efficiency of our immune defense mechanisms.

Dive into the fascinating world of the innate immune system! Discover its essential role as the body's first line of defense against pathogens. Learn about the various immune cells involved and the importance of anatomical barriers. The podcast also delves into the inflammatory response's four critical steps, showcasing how the body reacts to harmful stimuli. Plus, get valuable tips for MCAT preparation, emphasizing the need for thorough study and confidence building before the big exam!