कॉन्डम (बाहरी)

कॉन्डम (बाहरी)

कॉन्डम (बाहरी)

बाहरी (पुरुष) और आंतरिक (महिला) कॉन्डम गर्भनिरोधक में बाधा तरीके हैं। ये शुक्राणु को अंडे से मिलने नहीं देते  हैं।

बाहरी कॉन्डम एक उत्तेजित लिंग पर सही बैठता है और बहुत पतले लेटेक्स (रबड़), पॉलीयूरेथेन (प्लास्टिक) या पॉलीसोप्रीन से बना होता है।

कुछ  बाहरी नवीनता कॉन्डम भी उपलब्ध हैं। ये कॉन्डम आपको गर्भावस्था से नहीं बचा सकते हैं और यौन संचारित संक्रमणों से आपकी रक्षा नहीं कर सकते हैं, इसलिए नीचे दी गई जानकारी उन पर लागू नहीं होती है।

एक नज़र में

प्रभावशीलता: बाहरी कॉन्डम सबसे प्रभावी तब  होते हैं, जब पूरी तरह से इनका उपयोग किया जाता है। वे सही उपयोग के साथ गर्भावस्था को रोकने में 98 प्रतिशत प्रभावी हैं और सामान्य उपयोग के साथ 82 प्रतिशत प्रभावी हैं। 

यौन संबंध से पहले याद रखें: हर बार जब भी आप यौन संबंध बनाएँ,तो एक नए कॉन्डम का प्रयोग करें। 

मासिक धर्म: कॉन्डम आपके मासिक धर्म को नहीं बदलेगा।

एसटीआई सुरक्षा: हाँ, बाहरी कॉन्डम और आंतरिक कॉन्डम गर्भनिरोधक के एकमात्र तरीके हैं, जो आपको एसटीआई से बचाने में मदद करते हैं। 

हार्मोन: कोई हार्मोन नहीं।

प्रभावशीलता

कोई गर्भनिरोधक कितना प्रभावी है, यह इस बात पर निर्भर करता है कि आप कितने साल के हैं, आप कितनी बार यौन संबंध स्थापित  करते हैं और क्या आप निर्देशों का पालन करते हैं।

यदि 100 यौन सक्रिय महिलाएँ  किसी गर्भनिरोधक का उपयोग नहीं करती हैं, तो एक वर्ष में 80 से 90 महिलाएँ  गर्भवती हो जाएँगी। 

सही उपयोग: यदि बाहरी कॉन्डम हमेशा निर्देशों के अनुसार उपयोग किए जाते हैं, तो वे 98 प्रतिशत प्रभावी होते हैं। इसका मतलब है कि 100 में से दो महिलाएँ साल में एक बार  गर्भवती होंगी। 

विशिष्ट उपयोग: यदि बाहरी कॉन्डम हमेशा निर्देशों के अनुसार उपयोग नहीं किए जाते हैं, तो 100 में से लगभग 18 महिलाएँ साल में एक बार गर्भवती हो जाएँगी। 

यौन संबंध बनाने के दौरान शुक्राणु योनी में जा सकते हैं, भले ही आप कॉन्डम का इस्तेमाल करें। ऐसा हो सकता है अगर: 

·        कॉन्डम लगाने से पहले लिंग योनी के आसपास के क्षेत्र को छूता है (वीर्यपात पूर्व द्रव, जो वीर्यपात से पहले लिंग से बाहर निकलता है, उसमें शुक्राणु हो सकते हैं)

·        कॉन्डम फट जाता है

·        आप गलत प्रकार या गलत आकार के कॉन्डम का उपयोग करते हैं

·        आप कॉन्डम का सही इस्तेमाल नहीं करते हैं

·        कॉन्डम फिसल जाता है

·        कॉन्डम क्षतिग्रस्त हो जाता है, उदाहरण के लिए नुकीले नाखूनों या गहनों से

·        आप बहुत अधिक या बहुत कम स्नेहक (चिकनाई) का उपयोग करते हैं

·        आप लेटेक्स या पॉलीसोप्रीन कॉन्डम के साथ तेल आधारित उत्पादों (जैसे बॉडी लोशन) का उपयोग करते हैं। ये कॉन्डम को नुकसान पहुँचाते हैं। 

यदि इनमें से कोई भी कारण होता है या यदि आपने गर्भनिरोधक का उपयोग किए बिना यौन संबंध बनाएँ हैं, तो आप आपातकालीन गर्भनिरोधक( emergency contraception) के बारे में सलाह ले सकते हैं।

कॉन्डम का उपयोग कौन कर सकता है?

बाहरी कॉन्डम ज़्यादातर लोगों के लिए उपयुक्त होते हैं।

 कुछ लोग बाहरी कॉन्डम में मौजूद लेटेक्स के प्रति संवेदनशील होते हैं।

यदि यह एक समस्या है तो आप बाहरी पॉलीयूरेथेन कॉन्डम या आंतरिक कॉन्डम का उपयोग कर सकते हैं। 

यदि आपका लिंग यौन संबंध के दौरान उत्तेजित नहीं रहता है, तो आपको बाहरी कॉन्डम का उपयोग करना मुश्किल हो सकता है। 

लाभ

·        आपको इनका उपयोग केवल तभी करना चाहिए, जब आप यौन संबंध स्थापित  करते हैं।

·        दोनों भागीदारों को एचआईवी सहित कुछ यौन संचारित संक्रमणों से बचाने में मदद करते हैं।

·        कॉन्डम के प्रयोग  से कोई गंभीर दुष्प्रभाव नहीं होते हैं।·        कॉन्डम कई प्रकार के आकृतियों और आकार में आते हैं।

·        वे आसानी से उपलब्ध होते हैं।

नुकसान

·        कॉन्डम कभी-कभी फिसल सकता है या फट भी सकता है।

·        कुछ लोग लेटेक्स कॉन्डम के प्रति संवेदनशील होते हैं, हालांकि यह दुर्लभ है।

·        वीर्यपात के बाद, लिंग के नरम होने से पहले, कॉन्डम को लिंग के आधार पर मज़बूती से पकड़कर बाहर निकालना महत्वपूर्ण है। 

गर्भावस्था के बाद कॉन्डम का प्रयोग 

मेरा अभी-अभी बच्चा हुआ है, क्या मैं कॉन्डम का इस्तेमाल कर सकती हूँ? 

आप बच्चा पैदा करने के तुरंत बाद कॉन्डम का उपयोग कर सकती हैं

– अतिरिक्त स्नेहक (चिकनाई) का उपयोग करने से यौन संबंध को और अधिक आरामदायक बनाने में मदद मिल सकती है। 

क्या मैं गर्भपात या गर्भपात के बाद कॉन्डम का उपयोग कर सकती हूँ? 

गर्भपात होने के तुरंत बाद आप कॉन्डम का उपयोग कर सकते हैं। 

मुझे कॉन्डम कहाँ  मिल सकता है? 

बाहरी कॉन्डम गर्भनिरोधक, यौन स्वास्थ्य क्लीनिक, युवा लोगों की सेवाओं और कुछ सामान्य प्रथाओं और जननांग चिकित्सा (जीयूएम) क्लीनिक से कॉन्डम  मुफ़्त मिल सकते हैं। 

वे स्थानीय योजनाओं के हिस्से के रूप में कुछ फार्मेसियों और अन्य स्थानों पर मुफ़्त में भी उपलब्ध हो सकते हैं। 

आप उन्हें किसी फार्मेसी से, मेल के द्वारा  या ऑनलाइन के साथ-साथ वेंडिंग मशीन, सुपरमार्केट, गैरेज और अन्य दुकानों से खरीद सकते हैं। 

एनएचएस चॉइस पर खोजें कि मुफ़्त में कॉन्डम कहाँ से प्राप्त करें।

Search where to get free condoms at NHS Choices.

कॉन्डम का उपयोग कैसे करें ?

Follow our guide to using external and internal condoms >>

विभिन्न प्रकार के कॉन्डम

आप कई अलग-अलग प्रकार के बाहरी कॉन्डम चुन सकते हैं, जिनमें नियमित, बड़ा, ट्रिम, उत्तेजक और मज़ेदार शामिल हैं। 

नियमित कॉन्डम

ये लेटेक्स या पॉलीयुरेथेन से बने होते हैं। वे अधिकांश लिंगों के अनुरूप औसत लंबाई और चौड़ाई के होते हैं और एक गोल या नुकीले सिरे के साथ सीधे किनारे होते हैं। वयस्क लिंग का आकार भिन्न होता है, लेकिन बहुत अधिक नहीं। हालांकि, आप बड़े या छोटे कॉन्डम के साथ अधिक सहज महसूस कर सकते हैं। 

बड़ा कॉन्डम

ये कॉन्डम बड़े लिंग में फिट होने के लिए डिज़ाइन किए गए हैं। वे आकार में भिन्न होते हैं और कुछ आराम में सुधार करने और उन्हें पहनने में आसान होते हैं। 

छोटे कॉन्डम

अक्सर ट्रिम कॉन्डम के रूप में जाना जाता है, छोटे कॉन्डम पतले या छोटे लिंग के लिए बनाए जाते  हैं।

मेड-टू-माप कॉन्डम

कस्टम-निर्मित कॉन्डम उन लोगों के लिए उपलब्ध हैं, जिन्हें सही आकार या आरामदायक कॉन्डम नहीं मिल रहा है। 

वीर्यपात में देरी

अधिकांश वीर्यपात में देरी वाले कॉन्डम में बेंज़ोकेन होता है। बेंज़ोकेन एक कम ताकत वाला स्थानीय संवेदनाहारी है, जो गले के लोज़ेंग में इस्तेमाल होने के समान है। यह कॉन्डम स्नेहक(चिकनाई) में डाला जाता है और अस्थायी रूप से लिंग के तंत्रिका अंत को सुन्न करके काम करता है। 

अधिक उत्तेजना वाला कॉन्डम

कुछ कॉन्डम में एक विशेष स्नेहक(चिकनाई) होता है, जो दोनों भागीदारों के लिए गर्म या झुनझुनी पैदा करता है। दूसरों में सनसनी बढ़ाने के लिए अतिरिक्त स्नेहक होता है। सभी ब्रांडों में कॉन्डम की कम से कम एक शैली होती है, जो बनावट वाली होती है – रिब्ड, डॉटेड  या स्टडेड – जिसका उद्देश्य सेक्स के दौरान सनसनी को बढ़ाना है।

मज़ा कॉन्डम

रंगीन, फ्लेवर, ग्लो-इन-द-डार्क और नवीनता वाले कॉन्डम सभी का उद्देश्य सेक्स को अधिक मज़ेदार बनाना है। यह सुनिश्चित करने के लिए पैकेजिंग की जाँच करें कि उनका उपयोग गर्भावस्था और यौन संचारित संक्रमणों से बचाने के लिए किया जा सकता है।

 मज़बूत कॉन्डम

ये कॉन्डम थोड़े मोटे होते हैं और कभी-कभी इनमें अतिरिक्त स्नेहक भी होता है। ये आमतौर पर लेटेक्स से बने होते हैं। मज़बूत कॉन्डम के टूटने की संभावना कम नहीं होती है। 

पतला कॉन्डम

ये कॉन्डम नियमित कॉन्डम की तुलना में पतले होते हैं, जो दोनों भागीदारों के लिए अधिक संवेदनशीलता प्रदान करते हैं। 

शाकाहारी कॉन्डम

कई लेटेक्स कॉन्डम में कैसिइन नामक दूध प्रोटीन होता है। शाकाहारी कॉन्डम सभी पशु उत्पादों से मुक्त होते हैं।

जानने योग्य अन्य बातें

मुझे कॉन्डम के साथ स्नेहक का उपयोग कब करना चाहिए? 

अधिकांश बाहरी कॉन्डम उपयोग में आसान बनाने के लिए चिकनाहट से  तैयार होते हैं। कुछ लोग अतिरिक्त चिकनाहट का उपयोग करना भी पसंद करते हैं।

पॉलीयूरेथेन कॉन्डम के साथ किसी भी चिकनाहट का उपयोग किया जा सकता है। 

हालांकि, यदि आप लेटेक्स या पॉलीसोप्रीन कॉन्डम का उपयोग कर रहे हैं, तो आपको कभी भी तेल आधारित उत्पादों का उपयोग नहीं करना चाहिए – जैसे शरीर के तेल, क्रीम, लोशन या पेट्रोलियम जेली – स्नेहक(चिकनाहट) के रूप में। ऐसा इसलिए है क्योंकि वे नुकसान पहुँचा  सकते हैं और कॉन्डम के फटने की संभावना को बढ़ा सकते हैं।

कुछ मलहम लेटेक्स या पॉलीसोप्रीन को भी नुकसान पहुँचा सकते हैं। यदि आप जननांग क्षेत्र में दवा का उपयोग कर रहे हैं – उदाहरण के लिए, क्रीम, पेसरी, या सपोसिटरी – अपने डॉक्टर, नर्स या फार्मासिस्ट से पूछें कि क्या यह लेटेक्स या पॉलीसोप्रीन कॉन्डम को प्रभावित करेगा। कॉन्डम लेटेक्स, पॉलीयुरेथेन या पॉलीसोप्रीन से बना है या नहीं, यह पता लगाने के लिए आप कॉन्डम की पैकेजिंग की जाँच कर सकते हैं।

कुछ कॉन्डम में कोई स्नेहक नहीं होता है ताकि आप स्नेहक का उपयोग न करने या अपनी पसंद के स्नेहक का उपयोग करने का विकल्प चुन सकें। 

क्या मुझे शुक्राणुनाशक का उपयोग करने की आवश्यकता है? 

नहीं, यदि सही तरीके से उपयोग किया जाता है, तो कॉन्डम गर्भनिरोधक का एक प्रभावी तरीका है और आपको अतिरिक्त शुक्राणुनाशक की आवश्यकता नहीं है – एक रसायन जो शुक्राणु को मारता है। 

कुछ प्रकार के बाहरी कॉन्डम शुक्राणुनाशकों से चिकनाई युक्त होते हैं। इस प्रकार के कॉन्डम को चरणबद्ध तरीके से समाप्त किया जा रहा है। शोध से पता चलता है कि शुक्राणुनाशक जिसमें नॉनऑक्सिनॉल 9 होता है, संक्रमण के जोख़िम को बढ़ा सकता है। यदि आप कर सकते हैं, तो शुक्राणुनाशक चिकनाई वाले कॉन्डम का उपयोग करने से बचें और स्नेहक के रूप में अतिरिक्त शुक्राणुनाशक का उपयोग न करें।

ओरल सेक्स के लिए कौन से कॉन्डम सबसे अच्छे हैं? 

ओरल सेक्स के लिए किसी भी कॉन्डम का इस्तेमाल किया जा सकता है। हालांकि, फ्लेवर्ड कॉन्डम एक अच्छा विकल्प है क्योंकि वे लुब्रिकेटेड नहीं होते हैं और अधिकांश लोगों के स्वाद के अनुरूप कई प्रकार के फ्लेवर में आते हैं।

गुदा मैथुन के लिए कौन से कॉन्डम सबसे अच्छे हैं?

मानक कॉन्डम गुदा मैथुन के लिए उपयुक्त होते हैं – इस बात का कोई प्रमाण नहीं है कि मज़बूत या मोटे कॉन्डम बेहतर या सुरक्षित हैं। यह बहुत महत्वपूर्ण है कि आप कॉन्डम के टूटने के जोख़िम को कम करने के लिए गुदा मैथुन के लिए अतिरिक्त चिकनाई का उपयोग करें। 

क्या कॉन्डम के छिद्रों से शुक्राणु यात्रा कर सकते हैं? 

नहीं, न तो लेटेक्स और न ही पॉलीयूरेथेन कॉन्डम में छिद्र होते हैं। 

यह सुनिश्चित करने के लिए कॉन्डम का परीक्षण कैसे किया जाता है कि वे काम करेंगे? 

कॉन्डम को जाँचने के लिए कई अलग-अलग परीक्षणों से गुजरना पड़ता है:

 ·        वे छेद से मुक्त हैं

·        लेटेक्स की ताकत और खिंचाव

·        एक को फोड़ने के लिए आवश्यक वायु दाब

·        पैकेजिंग की सुरक्षा 

छुट्टी पर जा रहे हैं? 

कॉन्डम साथ रखना  हमेशा एक अच्छा विचार है – भले ही वह ‘जस्ट केस’ ही क्यों न हो। अगर आप विदेश जा रहे हैं, तो यूके से अपना पसंदीदा ब्रांड लें। इस तरह आपको किसी स्थानीय ब्रांड पर निर्भर नहीं रहना पड़ेगा, जिसे किसी विदेशी भाषा में पैक किया जा सकता है या जो समान मानकों पर निर्मित नहीं हो सकता है। 

मुझे कॉन्डम कहाँ रखना चाहिए? 

कॉन्डम और अलग-अलग कॉन्डम के पैकेट हमेशा ऐसे रखें जहाँ तेज़ गर्मी, नुकीली चीज़ें, रोशनी या नमी से उन्हें नुकसान न पहुँचे ।         

 

 

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Non-Invasive Treatment of Breast Cancer Using Histotripsy

Breast cancer is a global health challenge, with its impact felt across all corners of the world. According to the World Health Organization (WHO), breast cancer is the most frequent cancer among women, impacting 2.1 million women each year. It causes the greatest number of cancer-related deaths among women. In 2020, it is estimated that 685,000 women died from breast cancer worldwide. As the incidence of breast cancer rises, particularly in developing countries where the majority of cases are diagnosed in late stages, the need for accessible and non-invasive treatments is more pressing than ever. Histotripsy promises to be a gamechanger for the non-invasive treatment of breast cancer worldwide. In India, breast cancer has overtaken cervical cancer as the most common cancer among women. The Indian Council of Medical Research (ICMR) has reported a significant rise in cases, with breast cancer accounting for 14% of cancers in Indian women. 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Non-Invasive Treatment of Liver Tumors: The Revolutionary Role of Histotripsy

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Tumor-Associated Macrophages (TAMs): TAMs are a subset of macrophages that are recruited to the tumor site and are educated by the tumor microenvironment to adopt a pro-tumor phenotype. These cells can promote tumor growth, angiogenesis, and metastasis while suppressing anti-tumor immune responses. Histotripsy’s ability to target and modulate TAMs is of significant interest. By disrupting the tumor microenvironment, histotripsy can potentially reprogram TAMs from a pro-tumor M2 phenotype to an anti-tumor M1 phenotype, thereby reversing their tumor-promoting effects. b. Myeloid-Derived Suppressor Cells (MDSCs): MDSCs are a heterogeneous group of immature myeloid cells that expand during cancer, inflammation, and infection. In the context of cancer, MDSCs play a crucial role in suppressing T cell responses and promoting tumor growth. Preliminary studies suggest that histotripsy may reduce the number and suppressive function of MDSCs in the tumor microenvironment, thereby enhancing anti-tumor immunity. c. Regulatory T cells (Tregs): Tregs are a subset of CD4+ T cells that play a critical role in maintaining immune homeostasis by suppressing excessive immune responses. However, in the tumor microenvironment, Tregs can inhibit anti-tumor immune responses, thereby facilitating tumor growth. The impact of histotripsy on Tregs is an area of active research. By disrupting the tumor microenvironment and releasing tumor antigens, histotripsy may modulate the function and recruitment of Tregs, potentially enhancing anti-tumor immunity. d. The Interplay with Other Immune Cells: Apart from the aforementioned pro-tumor immune cells, the tumor microenvironment also contains other immune cells like dendritic cells, natural killer cells, and B cells. 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When released, CRT moves to the cell surface, where it aids in antigen presentation. This action effectively marks the damaged cells for elimination, kickstarting an adaptive immune response tailored to address the specific threat.  High Mobility Group  is another pivotal DAMP. As a nuclear protein, its primary role within the cell is to stabilize DNA structures. However, once outside, HMGB1 becomes a potent pro-inflammatory agent. It binds to receptors on immune cells, amplifying the inflammatory response, which is crucial in situations where rapid immune action is needed. Adenosine Triphosphate (ATP), commonly recognized as the primary energy currency of the cell, also plays a role in this immune signaling process. When found outside the cell, ATP acts as a danger signal. Immune cells, recognizing the abnormal presence of extracellular ATP, are prompted to migrate to the site of injury, further intensifying the immune response. 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Histotripsy: A Revolution in Precise Tissue Ablation

Histotripsy has emerged as a beacon of innovation in the ever-evolving landscape of medical technology. It  promises a future where precise tissue ablation can be achieved without the invasiveness of traditional surgical methods. But what makes histotripsy stand out? The answer lies in its unique mechanism of action, which harnesses the power of ultrasound to mechanically disrupt tissue structures. This article delves deep into the mechanism of histotripsy and how it paves the way for precise tissue ablation, especially in the realm of cancer treatment. What is Histotripsy? Histotripsy, a groundbreaking medical technique, is rapidly gaining traction in the healthcare sector due to its potential to revolutionise tissue ablation procedures. The term “histotripsy” is derived from the Greek words “histo,” meaning tissue, and “tripsy,” meaning to break. Histotripsy is a non-invasive approach to tissue disruption, and its unique mechanism of action  sets it apart from any other innovations. . The concept of histotripsy was first introduced at the University of Michigan in 2004. Since its inception, the technique has undergone significant advancements, with researchers continually exploring its potential applications and refining its methodology. The term itself encapsulates the essence of the procedure: a method to break down soft tissue. How does Histotripsy work? The Fundamental Mechanism: Cavitation  Cavitation, a phenomenon central to histotripsy, refers to the formation, growth, and subsequent collapse of gas or vapour-filled bubbles within a liquid medium when subjected to rapid pressure changes. In the context of histotripsy, the human body’s tissue serves as this liquid medium, and high-intensity, short-duration ultrasound pulses induce the rapid pressure changes. When tissues are exposed to these potent ultrasound pulses, the alternating high and low pressures lead to the creation of minuscule bubbles or cavities. These bubbles might initially form around pre-existing gas pockets or microscopic impurities within the tissue. As the ultrasound pulses persist, these bubbles expand due to the negative pressure phases of the ultrasound wave. Bubble Dynamics: The Heart of Tissue Disruption  The true essence of histotripsy is realised during the bubble collapse phase. Following the negative phase, the positive pressure phase of the ultrasound wave causes the expanded bubbles to undergo a swift and violent implosion. This rapid collapse generates potent local shock waves and produces high-velocity liquid jets. These intense mechanical forces, stemming from both the shock waves and the jets, act upon the surrounding tissue. The outcome is a mechanical breakdown of the tissue at a cellular level, resulting in the tissue being fractionated into a liquefied form. This liquid consists of a homogenised blend of cell debris and the extracellular matrix. How does Histotripsy achieve precision in action? In the realm of medical interventions, precision is paramount. The ability to target specific tissues or cells without affecting the surrounding structures can be the difference between successful treatment and unintended complications. Histotripsy, with its groundbreaking approach to tissue ablation, exemplifies this principle of precision in action. Let’s delve deeper into how histotripsy achieves such unparalleled accuracy. Histotripsy employs high-intensity ultrasound pulses to induce cavitation within the targeted tissue. The beauty of this technique lies in the ability to focus these ultrasound beams to a specific point, known as the focal zone. Within this focal zone, the energy of the ultrasound waves is concentrated, ensuring that the cavitation-induced tissue disruption occurs primarily within this localised area. This means that only the tissue within the focal zone is affected, while the surrounding structures remain untouched. One of the standout features that bolster histotripsy’s precision is the integration of real-time imaging. As the ultrasound waves are administered, they not only induce cavitation but also provide a live visual feed of the treatment area. This dual capability allows clinicians to monitor the formation and collapse of bubbles in real-time. Such immediate feedback ensures that the treatment is progressing as intended and allows for on-the-fly adjustments. If, for instance, the bubbles are not forming in the desired location or pattern, the clinician can instantly modify the parameters to achieve the desired effect. The precision of histotripsy can be likened to the accuracy of a surgeon’s scalpel, but without the invasiveness of a blade. The controlled generation and collapse of microbubbles ensure that only the targeted cells or tissues are disrupted. This selectivity is especially crucial when treating tumours or lesions located close to vital organs or critical structures. For example, when targeting a tumour adjacent to a major blood vessel, the precision of histotripsy ensures that the vessel remains unharmed, reducing the risk of bleeding or other complications. In many medical treatments, especially those involving radiation or surgery, there’s always a concern about collateral damage to healthy tissues. Histotripsy’s precision minimises this risk. By confining the tissue disruption to the focal zone, histotripsy ensures that the surrounding healthy tissues are spared. This not only enhances the safety profile of the treatment but also promotes faster healing and recovery. What sets Histotripsy apart from other cancer treatments? Histotripsy’s distinctive non-thermal approach to tissue ablation offers a fresh perspective in the realm of medical interventions. While many therapeutic ultrasound techniques, such as High-Intensity Focused Ultrasound (HIFU), rely on generating heat to achieve therapeutic effects, histotripsy stands apart. Traditional methods work by raising the temperature of the targeted tissue to a point where cellular proteins denature, leading to cell death. Although effective, this thermal approach has inherent risks. Elevated temperatures can inadvertently damage surrounding healthy tissues, especially if the heat spreads beyond the targeted area. Moreover, tissues sensitive to heat, like neural tissues, can be at risk of unintended damage. In contrast, histotripsy operates on a fundamentally different principle. Instead of using heat, it employs mechanical forces to achieve tissue disruption. This is achieved through the controlled generation and violent collapse of microbubbles within the tissue, a process known as cavitation. The implosive collapse of these bubbles generates intense local shock waves and produces high-speed liquid jets. These forces act on the tissue, leading to mechanical breakdown at the cellular level without the need for heat. The non-thermal nature of histotripsy offers